Talk:Monty Hall problem/Archive 9

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When Monty opens a door, he doesn't tell us anything we didn't already need to know. He ALWAYS shows a goat. It makes no difference to this puzzle WHICH remaining door he shows. So it starts out as 1/3 for your door + 2/3 for the remaining doors = 100%. Then he shows a door, but we knew in advance that he was going to show a goat. The odds simply haven't changed following his action. They remain 1/3 for your door + 2/3 for the remaining doors (of which there is now just 1).

That's why on the show, Monty didn't HAVE to show a door (unlike this puzzle), and he could bribe you with cash. Otherwise, there's no show. You always switch.

I'm new to this. Is there a way to get this 'solution' onto the article page?

75.185.188.104 (talk) 17:09, 25 October 2008 (UTC)

Isn't this essentially the same as the explanation in the Combining doors section? -- Rick Block (talk) 17:48, 25 October 2008 (UTC)

It would seem that your solution is not much liked by many of the current editors of this page because it cannot be verified by reliable sources. Martin Hogbin (talk) 22:59, 25 October 2008 (UTC)

Martin - was that directed at me? If so, then I'm confused. I didn't say I didn't like it, but that it's already included in the article (with reliable sources). -- Rick Block (talk) 03:58, 26 October 2008 (UTC)

No. It was directed at all the current editors. If you remember, I first came to this article in response to an RFC which claimed that the current editors were being overly protective. Although I understand why that attitude has some justification, I think that there are possible improvements that could be made that are being resisted.

My central point is this: The Monty Hall problem is particularly notable because, even when people make the 'standard' assumptions, the great majority of them get the wrong answer and it is difficult to convince them of the right one. This article could, and in my opinion should, address that issue better.

The more complex issues of host action/ game rules etc are not part of the core problem. In particular the issue of conditional/unconditional probability only adds to the confusion for many people. It is a fact that, for the 'standard' version of the problem, there is no difference between the two, therefore I put it to you that we do not need to make a major point at the start of the article about something that could have been the case but in fact is not. I have proposed that I very simple, and hopefully convincing, explanation along the lines suggested above should be given a prime position at the start of the article, followed by a section on sources of confusion in the basic case. The more detailed analyses, as already presented, should then follow. I appreciate that this might require a more liberal interpretation of some WP policies but I suggest that it is worthwhile considering this option in order improve the article.

I have tried to be a good Wikipedian by not disrupting this featured article with experimental edits and have set up a draft page for people to attempt to improve the it; so far only one other editor has shown an interest. So, yes, my remark was aimed at getting some reaction but only so that the article might be improved in a way that is acceptable to all. Martin Hogbin (talk) 10:33, 26 October 2008 (UTC)

I agree that the presentation of this article leaves something to be desired. I would think that most users come to this page to settle an arguement, or to enlighten themselves on how they don't 'get' the solution. I know that's why I came here.

So, an elegant, simple solution would serve the readers. I'm a stats and probability geek, but I don't like having to 'prove' something by running simulations (since I don't know who created the simulation, I can't trust it). And, if there is an easier to understand explanation that doesn't require umpteen diagrams, the typical reader would prefer that, as s/he will probably try to explain what s/he read here to other people. 75.185.188.104 (talk) 12:27, 26 October 2008 (UTC)

Isn't the first bit in the Solution section about as simple and elegant as it gets, with a diagram for the more visually minded folks out there? Three clearly equally probable cases, switching wins in two and loses in one. The transitional paragraph about this solution (the one containing the reference to simulations) and the follow-on conditional analysis (with a different diagram that appeals to other sorts of folks) is there to address a significant mathematical criticism (i.e. this solution does not address the problem that's actually posed), raised first by Morgan et al. If we end the Solution section following the first diagram the solution is incomplete as it fails to address the Morgan et al. criticism. IMO, any "simple" solution will inevitably have this same issue. There's an argument that Morgan et al. are splitting hairs over trivial details that most people don't care about, but that's like ignoring negative or imaginary roots of a quadratic equation (x^2 = 4, what's x? most people would say 2, but -2 is also an answer). If the suggestion is to simplify the solution section by eliminating any mention of the conditional analysis I strongly disagree. -- Rick Block (talk) 15:03, 26 October 2008 (UTC)

You refer to "significant mathematical criticism (i.e. this solution does not address the problem that's actually posed),". If such a thing is valid, then you don't have a solution at all. The solution should be, and is, simple. 1/3 + 2/3 = 100%. And Monty's actions do not change this formula. I don't see a mathematical ambiguity.

Glkanter (talk) 16:07, 26 October 2008 (UTC)

This is the same topic discussed in more detail three sections down (about the subtly different question), and indeed Morgan et al. argue the "simple" solution is not a solution at all. -- Rick Block (talk) 16:28, 26 October 2008 (UTC)

Well, I thought we were going to discuss the solution to the Monty Hall Problem. And that the 'Solution' portion of the Wikipedia entry would provide just that. I can see now that there is some other agenda for Monty Hall Problem page. I provided a mathematical proof to a very simple problem. So far, not you, or anybody else has challanged that proof. I already pointed out an error in the VERY FIRST LINE OF THE EXISTING SOLUTION paragraph. Yet you bring up all sorts of 'subtly different questions', 'mathematical inconsisancies', and whatnot. It's your page. Do whatever you want.

Glkanter (talk) 16:42, 26 October 2008 (UTC)

We're off on the wrong foot here. It's not my page, it's openly editable by anyone. In its current form it's the result of the efforts of at least a dozen editors over the span of 7 years. I'm simply one of a number of editors who have contributed to this page for a long time (in my case, since at least June 2005). I'm perfectly happy to discuss changes, and very happy when discussions result in improvements to the article. Please delete the first sentence in the solution section (I'll wait a while and if you don't I will). Thank you for this suggestion. I think nearly anyone would agree it's an improvement (fewer words are generally better). What I mostly meant by the comment from 16:28 above is that the discussion is continuing in the other section (below), so rather than continue here we should continue there. -- Rick Block (talk) 20:48, 26 October 2008 (UTC)

Re: The 'Combining Doors' comment above. Yes, it's similar. imho, these should be a prominant part of the 'Solution', not relegated to 'Aids to Understanding'. Glkanter (talk) 15:12, 26 October 2008 (UTC)

I find the explanation in the combining doors section somewhat abstract. Here's the explanation I've been using with people who have a hard time understanding why switching is the best strategy -- I know this probably shouldn't go on the main page (I'm the only reference I know of) but I wanted to share it.

I'm going to write it in the form of a dialog because that is the shortest form of this explanation and also the form in which it has been used:

"What if I could show you a tricky way to pick two doors instead of just one. Would you agree that you have a 2/3 chance of winning if you could pick two doors?"

"Sure! If I can actually pick two doors I'll have a 2/3 chance of winning."

"OK, tell me (but don't tell Monty) which two doors you want to pick."

"OK, I want to pick doors two and three."

"Great -- now tell Monty you want to pick door number one."

"But I don't want door number one!"

"I know, that's the tricky part. By telling Monty you want door number one you'll get him to open one of the two doors you actually picked -- and the way the rules are setup he'll always pick a door that has a goat. After he opens one of the two doors you actually picked now tell him you're switching that way you'll get to pick both doors two and three."

Am I correct that this would be inappropriate for the main page? Stepheneb (talk) 17:08, 2 January 2009 (UTC)

I would say yes, you are correct that this would be inappropriate for the main page (unless you can find a reliable source for it). It is logically the same as the "Combining doors" explanation. -- Rick Block (talk) 18:53, 2 January 2009 (UTC)

I follow the reasoning all the way, yet the following twist to the scenario puzzles me. Can someone explain what I'm missing?

1. Contestant chooses door 1, Monty reveals a goat behind door 3 and invites the contestant to revise his choice.
2. Before the contestant makes his final decision known, another contestant is whisked on stage, straight from the dressing room, with no prior knowledge of the first contestant's original choice. This second contestant is presented with the open door 3 (and its goat) and asked to choose where the car is.
3. The two contestants then make their choices, independently of each other. The first contestant, having read this article, switches his choice to door 2. The second contestant tosses a coin on the basis of which he also chooses door 2.

As we know from the article, the first contestant has a 2/3 probability of finding the car. But for the second contestant it's a straight choice between 2 doors, so he has a 1/2 chance of finding the car. So it appears that at the moment the two contestants make their final choices, p(finding the car | choosing door 2) has two different values simultaneously depending on who does the choosing, whereas intuition (mine, anyway) says that the probability should have a unique value, and that it should depend only on the possible permutations of the original distribution of car and goats, and the shared knowledge that door 3 revealed a goat. Help! -- Timberframe (talk) 09:25, 26 October 2008 (UTC)

The probability depends on what the second contestant knows about the situation. If they are simple told,'here are two doors, one hides a car and the other a goat', then they might as well toss a coin. If, on the other hand, they have watched the show on a monitor, or are told, 'this is the door that the contestant first chose, then Monty opened this door to reveal a goat (as he always does)', they would know that the odds are better if they choose the door that the first contestant did not. Martin Hogbin (talk) 10:42, 26 October 2008 (UTC)

Mr. Hogbin is correct. Note that the 2nd player has less likelyhood of picking correctly. 50% vs 67%. This is because he has less knowledge of how the 2 doors came to be. He can only assume randomness, but the first player knows Monty did not act randomly when he opened the door revealing a goat. 75.185.188.104 (talk) 12:17, 26 October 2008 (UTC)

Another way to look at this is to compute the second player's conditional probability of winning the car. At the time the second player is choosing, Door 1 has a 1/3 chance of being the right door while Door 2 has a 2/3 chance. Someone picking randomly between these doors has a (1/2 * 1/3) + (1/2 * 2/3) chance of winning the car. Multiply this out and you get 1/2. In words what this means is that if the second player happens to pick Door 2 he also has a 2/3 chance of winning the car (but this only happens half the time, and the other half he has only a 1/3 chance). If your question is what is the second player's chance of winning if he happens to pick Door 2, the answer is 2/3 (same as the first player). Note that this is true whether or not he watched the show on a monitor. He may well think his chances are 1/2, and they are before he flips the coin, but after he flips the coin and picks a door his chances are either 1/3 or 2/3 (just like player 1) depending on which door he picks. -- Rick Block (talk) 15:24, 26 October 2008 (UTC)

To say that the second player would have a 2/3 chance of winning the car if he picks the door 2 is not, in my opinion, a good way of putting things. It depends on who is making the call. From the second contestant's point of view the chances are 1/2 (if he knows nothing of the history), from the audience's (who have seen what has happened so far) point of view they are 2/3, and from the producer's (who knows the car is actually behind door 1) point of view it is 0. Probability is a state of knowledge.Martin Hogbin (talk) 16:16, 26 October 2008 (UTC)

On the other hand, to say the first player and second player who have picked the same door have different chances of winning seems like an extremely odd way of putting things. The probability does depend on who makes the call, but I think the same perspective should be used in both cases - that being the perspective of a member of the audience. -- Rick Block (talk) 16:35, 26 October 2008 (UTC)

I would say that it is more normal to quote probabilities from the point of view of the person who is making the choice. This does lead to different probabilities for different people doing the same thing but understanding that is basic to understanding probability. For example what are the chances of a player initially picking the car - 1/3. Suppose that we have a different player who somehow knows that car is not behind door 2 - his probability of picking the car is 1/2. Same car, same goats, same doors, but a different answer. Martin Hogbin (talk) 16:47, 26 October 2008 (UTC)

You're right on target. As more knowledge is gained, probabilty increases from 1/2 (random, or no knowlegde), to 2/3 (watched Monty open a door), to 100% (you're Monty). Hopefully, Timberframe's original concern was resolved.

Glkanter (talk) 17:02, 26 October 2008 (UTC)

I'll be more precise. The perspective is generally that of someone who knows all the givens from the problem statement. So, if we're given the unambiguous Monty Hall statement (from the article) and that player 1 had picked Door 1 and the host has opened Door 3 and then player 2 has arrived on the scene and flipped a coin and has selected Door 2, player 2 has a 2/3 chance of winning (not 1/2). This matches the chances player 1 has if switching to Door 2. The probabilities are evaluated with knowledge of all the givens. Different givens result in different probabilities, which is why we'd say Martin's player who (we're given) knows that among the three doors the car is not behind Door 2 has a 1/2 probability of picking the car initially. Same car, same goats, same doors, but different givens so a different answer. -- Rick Block (talk) 17:49, 26 October 2008 (UTC)

I guess the moral of this discussion is to make always make clear what the givens are before stating a probability, which I think none of us actually did. Martin Hogbin (talk) 20:13, 26 October 2008 (UTC)

Thanks guys, got it now. The falacy in my proposition is in the assertion that because there are two closed doors and the car is behind one of them, the second contestant has a 50:50 chance of finding it. This is only true from the second contestant's limited perspective. The conditions of the scenario is posited have in reality already shifted the odds to 2:1. Thanks again -- Timberframe (talk) 19:29, 26 October 2008 (UTC)

The following is prominant in the article:

"Solution The overall probability of winning by switching is determined by the location of the car...

This result has been verified experimentally using computer and other simulation techniques (see Simulation below)."

This first sentance doesn't mean anything, and in fact is incorrect. The probability is NOT affected by the location of the car. One instance of playing the game is affected, but not the probability.

Further, a valid proof, which I believe my entry is, does not require being "verified experimentally using computer and other simulation techniques". A valid proof stands on it's own.

And lastly, this at the top of the Discussion Page is at a minimum, off-putting:

"Please note: The conclusions of this article have been confirmed by experiment

There is no need to argue the factual accuracy of the conclusions in this article. The fact that switching improves your probability of winning is mathematically sound and has been confirmed numerous times by experiment."

As I stated above, valid proofs do not rely on 'experiments'. Yet, there are two references to 'experiments'. Me thinks the lady doth protest too much. 75.185.188.104 (talk) 13:34, 26 October 2008 (UTC)

Are you suggesting deleting the first sentence in the Solution section? If so, that'd be fine with me. The "proof" in the Solution section does not depend on being verified experimentally - that sentence is there in an attempt to further convince the many doubters about the validity of the solution. If you can think of a way to make this more clear, please do so. The banner at the top of this page is there to discourage folks from arguing that the solution is incorrect (we still get a fair number of folks claiming the 2/3 answer is wrong). -- Rick Block (talk) 15:35, 26 October 2008 (UTC)

Yes, being incorrect, the first sentance should be deleted.

Why not move the 'experiment' stuff to 'Aids to Understanding'? A Solution should stand on it's merits. Making reference, in the solution, to another technique weakens it's apparent authority.

In fact, doesn't just having the 'Aids to Understanding' section imply that the proof is lacking clarity? The salient point that I believe is missing, is that the probabilities don't change because of Monty's action. That's why it's 1/3 - 2/3 when you start, and when you finish. Which is the only point of the whole Monty Hall Problem.

Glkanter (talk) 15:57, 26 October 2008 (UTC)

Can I mention again that I have set up this page:user:Martin Hogbin/Monty Hall problem (draft) for those, like myself, who do not find the current solution clear or convincing to develop a better basic solution. The concept is to develop a very clear solution that is verifiable and which can be eventually added to this article. There is also a talk page for discussion on how we might achieve this. Martin Hogbin (talk) 16:58, 26 October 2008 (UTC)

"A subtly different question is which strategy is best for an individual player after being shown a particular open door. Answering this question requires determining the conditional probability of winning by switching, given which door the host opens. This probability may differ from the overall probability of winning depending on the exact formulation of the problem (see Sources of confusion, below)."

I have no idea what this means, and fail to see how it part of a solution to the problem. People come to this page for an explanation. The above paragraph, plus whatever follows it, are not part of the solution to the Monty Hall Problem, and, imho should not be present there. Glkanter (talk) 14:59, 26 October 2008 (UTC)

There are two different questions.

1. If a player decides to switch before the host has opened a door, what is this player's chance of winning? Or, what is the overall probability of winning at the start of the game?
2. If a player decides to switch after the host has opened a door, what is this player's chance of winning? Or, what is the conditional probability of winning given which door the host opens?

The first part of the Solution section addresses the first question. The second question is subtly different, and requires examining only those cases where the host has opened a specific door. The second question can have a different answer than the first question even given the same game setup. This is exactly the same situation as the question raised two sections above about a second player who arrives on the scene after the host has opened a door (substituting before and after this player chooses a door for before and after the host opens a door). Before flipping a coin this second player has a 1/2 chance of winning. After flipping a coin this second player has a 1/3 or 2/3 chance of winning, depending on which door he chooses. Similarly, the first player has a 2/3 chance of winning by switching before the host opens a door, but may have a different chance of winning by switching after the host opens a door depending on exactly how the problem is formulated. In particular, unless the host is constrained to pick between two goat doors with equal probability (in the case the player has initially selected the car), the chance of winning by switching after the host opens a door may be anywhere between 1/2 and 1. An analysis that ignores this constraint and concludes the chance of winning by switching is 2/3 is incorrect, since the same analysis would apply to a different version of the problem (for example, where the host is constrained to always open the lowest numbered door hiding a goat). The typical wording of the problem is arguably asking the second question, not the first. -- Rick Block (talk) 16:07, 26 October 2008 (UTC)

There is no question of the probabilities at the start of the game. It's 1/3 car vs 2/3 goat. That's actually a premise, that everything is random. The only question asked in the problem, which assumes that Monty ALWAYS shows a goat (also a premise), is what are the odds when 2 doors are left? imho, everything else is clutter. I don't know what the word 'conditional' means in the context of this puzzle.

I came to the Wikipedia page because I needed to understand why it was favorable to switch. I've since distilled the reason to a single sentance, 'Monty's Action Doesn't Change the Odds.' As a user, I can assure you that all this other stuff gets in the way of understanding.

Glkanter (talk) 16:21, 26 October 2008 (UTC)

I agree. In the 'standard' version of the problem, it actually makes no difference when the player decides to switch. What is gained by answering a more complicated question that the one most people assume? The 'basic' question is plenty hard enough without trying to make it harder. Martin Hogbin (talk) 16:31, 26 October 2008 (UTC)

The question is why don't Monty's actions change the odds? Asserting this is true because we already know one of the unchosen doors hides a goat is not mathematically sound (and it's actually reasonably difficult to prove this assertion). The standard version of the problem puts the player's decision at the point the host has already opened a door. This makes it a conditional probability question. Any answer that ignores which door the host opens is fundamentally incomplete. -- Rick Block (talk) 17:06, 26 October 2008 (UTC)

Yes, but I am advocating getting the best of both worlds. Have a simple explanation that may not be rigorously complete but that people can understand and follow it with the current explanation that is more rigorous and complete. Martin Hogbin (talk) 17:22, 26 October 2008 (UTC)

This is the exact structure of the existing Solution section. Simple solution first (3 equally likely scenarios, switching wins in 2 of them), followed by a transition to a more rigorous solution. Are we fundamentally quibbling about what the simplest solution is? The one that is presented is meant to be obviously (intuitively) correct and mathematically sound (as far as it goes), but also function as a natural lead-in to the more rigorous solution. Are you arguing that the existing "3 equally likely scenarios" solution is hard to understand? -- Rick Block (talk) 18:14, 26 October 2008 (UTC)

Yes, I suppose I am arguing that simple solution shown is not simple enough. It also has some curious statements such as,'The overall probability of winning by switching is determined by the location of the car'. From whose point of view is that statement made? Martin Hogbin (talk) 19:43, 26 October 2008 (UTC)

Mr. Block, I disagree. There is no 'mathematically sound' problem. If there is, please share it with me. And your statement relating to conditional probability doesn't seem to apply here. The contestant's choice was random, and we don't care which door Monty reveals. You may repeat endlessly your asertion that it is important, but it is not valid. Like I said earlier, you seem to be interested in something other than the clear, concise answer to the Monty Hall Problem. Until you can focus on that, and perhaps show me the flaw with my solution, I'm wasting my time here. As for Monty's actions not affecting the odds, the proof is that the odds do not change once the contestant has chosen a door. His door remains 1/3. Maybe that is a tough concept for the random reader to grasp. That's why it's a paradox! But until you focus on that, and not all this other stuff, you won't be addressing the solution to the Monty Hall Problem at all.

Mr. Hogbin, I don't see how this solution is not 'rigorously complete'. Simple, yes. Incomplete, no.

I am, for the moment, simply accepting the opinion of others regarding rigorous completeness. Martin Hogbin (talk) 19:43, 26 October 2008 (UTC)

Glkanter (talk) 18:02, 26 October 2008 (UTC)

Consider a slightly different problem which is the same in all respects except that the host always opens the lowest numbered door possible. I believe your argument still holds (player's initial pick is 1/3, other two doors are 2/3, we know one is a goat, knowing which one can't affect the initial probability, etc.), leading to the conclusion that the player's chances of winning by switching are 2/3. This is even true if the question is asked before the host has opened a door. The usual version of the problem asks the question after the host opens the door. In this variant, if the player has picked Door 1 and the host has opened Door 3 the correct answer is the chances of winning by switching are 100%. In the unambiguous problem as stated in the article, the host must pick between two goat doors with an equal probability. This constraint, and only this constraint, is the difference between the variant I've suggested and the problem as posed in the article. If the solution does not use this constraint, there's a variant for which the solution produces the wrong result (i.e. the solution is mathematically unsound). -- Rick Block (talk) 18:14, 26 October 2008 (UTC)

Mr. Block, put yourself in the reader's seat. S/he wants to understand the Monty Hall Problem. Not 'a slightly different problem which is the same in all respects except that the host always opens the lowest numbered door possible.' Just the Monty Hall Problem. Now tell me, mathematically, or with symbolic logic, where my solution TO THAT PROBLEM is inaccurate, incomplete, or un-repeatable. That's all I ask. For now.

Glkanter (talk) 18:37, 26 October 2008 (UTC)

(outindent) The question is if it's advantageous to switch after we've picked a door and the host has opened one of the remaining doors. Your solution is the following:

When Monty opens a door, he doesn't tell us anything we didn't already need to know. He ALWAYS shows a goat. It makes no difference to this puzzle WHICH remaining door he shows. So it starts out as 1/3 for your door + 2/3 for the remaining doors = 100%. Then he shows a door, but we knew in advance that he was going to show a goat. The odds simply haven't changed following his action. They remain 1/3 for your door + 2/3 for the remaining doors (of which there is now just 1).

I've highlighted the problematic parts. These are assertions, not deductions based on what is given in the problem statement. They're true statements, but stating them without justification is equivalent to assuming the solution. We're not given that it makes no difference which door the host opens and we're not given that when the host opens one of the two remaining doors the initial 1/3 odds don't change - this is essentially what we're asked to show. It's like in a geometry proof using that an angle in the diagram is a 90 degree angle because it looks like one without showing why it must be one. If indeed it must be one because of what else is given it's certainly true, but using it without justification is at best incomplete. The simple solution currently in the article (3 equally likely scenarios, switching wins in 2 and loses in 1) doesn't have this problem. Do you find this solution hard to understand? -- Rick Block (talk) 19:21, 26 October 2008 (UTC)

Rick, I take issue with one of your statements: '...true statements, but stating them without justification is equivalent to assuming the solution' is too strong. Stating things without justification is assuming something, but not the solution. Even with the assumption of the statements mentioned, most people would still get the answer wrong, which is the notable feature of all this Martin Hogbin (talk) 19:56, 26 October 2008 (UTC).

Rick, also perhaps you would be kind enough to criticise the solution on my development page under Martin - Very short. Martin Hogbin (talk) 20:26, 26 October 2008 (UTC)

The very short solution (the player has a 2/3 chance of initially picking a goat, and in this case the host must reveal the other goat so this player now has a 2/3 of winning the car by switching) is essentially the "In other words" sentence just before the figure. I don't think it hurts to enumerate the cases, and the diagram definitely helps at least some people so I think this very short solution is fundamentally what's there already. The other advantage of the existing slightly longer version is that it provides a framework to discuss the more rigorous solution. Is the existing solution (up to and including the figure) any harder to understand than this very short solution? -- Rick Block (talk) 21:15, 26 October 2008 (UTC)

Thank you for your response to my question. Again, I respectfully disagree. My statement that it doesn't matter WHICH door Monty shows is true. It's not germain to the puzzle. The odds not changing? That's easy. Monty does not consider the door chosen by the contestant. Therefore, we gain no new knowledge about that selection, and it remains at 1/3. Since the probabilty must equal 100%, the remaining door now carries a 2/3 probability, (100% - 1/3). This is not really a debatable point. It is a bedrock principal of probabilty. The beauty of probability is that you only have to prove a solution one way. You can use my method, or Martin's method. They are BOTH VALID. As are some of the explanations with the diagrams, etc. And yes, the longer the explanation, the harder it is to understand, and explain to others. Why would you NOT want the most elegant solution to lead the paragraph? Any statement, diagram,etc. that is not necessary should be avoided. This is standard proof protocol. When Martin reduces it to 2 statements, that's a thing of beauty. Why interfere with it with extraneous statements?

Glkanter (talk) 21:33, 26 October 2008 (UTC)

Now, let's critique the existing Solution, much like you critiqued my proposed solution.

[Paragraph 1] The reasoning above applies to all players at the start of the game without regard to which door the host opens, specifically before the host opens a particular door and gives the player the option to switch doors (Morgan et al. 1991). This means if a large number of players randomly choose whether to stay or switch, then approximately 1/3 of those choosing to stay with the initial selection and 2/3 of those choosing to switch would win the car. This result has been verified experimentally using computer and other simulation techniques (see Simulation below).

[Paragraph 2] Tree showing the probability of every possible outcome if the player initially picks Door 1A subtly different question is which strategy is best for an individual player after being shown a particular open door. Answering this question requires determining the conditional probability of winning by switching, given which door the host opens. This probability may differ from the overall probability of winning depending on the exact formulation of the problem (see Sources of confusion, below).

[Paragraph 3] Referring to the figure above or to an equivalent decision tree as shown to the right (Chun 1991; Grinstead and Snell 2006:137-138) and considering only the cases where the host opens Door 2, switching loses in a 1/6 case where the player initially picked the car and otherwise wins in a 1/3 case. Similarly if the host opens Door 3 switching wins twice as often as staying, so the conditional probability of winning by switching given either door the host opens is 2/3 — the same as the overall probability. A formal proof of this fact using Bayes' theorem is presented below (see Bayesian analysis).

Paragraph 1 means nothing. It is gibberish.

Paragraph 2 does not respond to the Monty Hall Problem, and does not belong under the Solution heading.

Paragraph3 refers to a special case where Monty opens door 2 only. It too, is not germain to the Monty Hall Problem, which has ALREADY been proven by whatever method leads the discussion.

These three paragraphs of the existing Solution do not add anything to the reader's understanding of the solution, and should be removed. At best they are superfulous, at worst they are confusing, and maybe just wrong.

Glkanter (talk) 22:09, 26 October 2008 (UTC)

And, for the record, there are only 2 scenarios.

1 The contestant chooses a goat, which happens 2/3 of the time. In this case, as Martin so eloquently demonstrated, Monty eliminates the remaing goat leaving the car behind the closed door.

2 The contestant chose the car, in which case Monty eliminates one of the goats. This happens 1/3 of the time.

Therefore, any solution relying on diagrams, etc should have only these 2 scenarios. Anything beyond this convolutes the solution, which, of course should be avoided.

Glkanter (talk) 22:16, 26 October 2008 (UTC)

It doesn't matter which door Monty shows, but only because he's constrained to open one of the two goat doors with equal probability in the case the player initially selects the car. Again, you're asserting this without justifying why this is true. Regarding the odds not changing, are you saying Monty does not consider opening the door chosen by the contestant? This, by itself, is not sufficient to ensure that Monty's actions don't change the initial 1/3 probability. The total probability must be 100%, and before the host opens a door it's surely 1/3 player's door vs. 2/3 for the other two doors (so 2/3 of the players who decide to switch before the host opens a door will win) but the only thing that keeps it that way after the host opens a door is that pesky equal goat door constraint. The best way I know to show that it CAN change is to contrast the problem as stated with a different problem (i.e. the aforementioned "host opens lowest numbered door possible" variant).

With the equal door constraint, if the player picks Door 1 the probability the host opens Door 2 (or Door 3) is 1/2. This 1/2 is not random, but composed of a 1/3 chance that the car is behind the other door plus a (1/2 * 1/3) chance the car is behind Door 1. This fact makes the problem symmetric with regard to which door the host opens. We in effect have two identical subproblems, and it's this that makes it true that it doesn't matter which door the host opens (and prevents the host opening a door from changing the initial 1/3 chance).

In the lowest numbered door variant, the probability that the host opens Door 2 is not the same as the probability that the host opens Door 3. In this variant, the host opens Door 2 if the car is behind either Door 1 or Door 3 (i.e. 2/3 chance), and Door 3 only if the car is behind Door 2 (1/3 chance). The player has a 100% chance of winning if the host opens Door 3, but only a 50% chance of winning if the host opens Door 2. Multiplying out the composite probabilities we get (100% * 1/3) + (50% * 2/3), which totals 2/3 (meaning if you decide to switch before the host opens a door you have a 2/3 chance of winning) but in this variant the chances change to either 1/1 or 1/2 when the host opens a door (depending on which door the host opens).

The ONLY point in bringing up this variant is to demonstrate the flaw in the argument that the host's actions can't change the probability. They most certainly can. The host can't change the fact that 2/3 of players who decide to switch before a door is opened will win, but this doesn't necessarily mean that 2/3 of the players win when the host opens Door 3. This is an important aspect of the Monty Hall problem that, frankly, VERY few people understand (I didn't, until about a year ago - when an anonymous user brought it up on this talk page and provided the initial reference to the Morgan et al. paper and quite persistently argued about it). It is, in a sense, a second order issue (the first order issue being the "is it 1/2 or 2/3" confusion), but treating the problem rigorously, as a conditional probability problem, is not that difficult and leads to a much better understanding. This more rigorous solution is the topic of the paragraphs you've highlighted above. Could these be made more clear? Almost certainly. Should they be removed? I don't think so. -- Rick Block (talk) 00:24, 27 October 2008 (UTC)

Monty choosing the CONTESTANT'S door? Not in the puzzle. Therefore, the rest of your diatribe is meaningless. Equal goat door constraint? Never heard of it.

Look, the opening Wikipedia solution - once you remove the first sentance - proves that the odds are 1/3 vs 2/3. Once that mission is accomplished, the rest is either redundant, or incorrect. Is more than one proof valuable? Sure, but not the malarky that's there now.

Conditional probability? Hogwash!

I'm not familiar with a valid proof that is 'rigorously insufficient'. This isn't a beauty contest, or a political debate. It's math. It's a binary system, either it is, or it isn't a valid proof. The probabilities of those two events equals 100%. Like I said, that's a bedrock principal.

You have failed to demonstrate a weakness in the Wikipedia proof, Martin's proof or my proof. Yet you bring up all these other things. It's a simple puzzle, once you realize that Monty leaves a car on stage 2/3 of the time (thank you Martin). Again, 100% minus 2/3 leaves 1/3 for the contestant's choice.

Glkanter (talk) 01:42, 27 October 2008 (UTC)

Maybe we should take this one step at a time. Do you agree there may be a difference between the probability of winning by switching before the host opens a door and after the host opens a door? Or, at least, that these are different questions? -- Rick Block (talk) 02:09, 27 October 2008 (UTC)

I've read this entire discussion page from top to bottom. Other people have come before me, and pointed out essentially the same things I'm saying. No, thank you, I do NOT want to debate some other puzzle questions with you. It's a simple puzzle. In fact, the puzzle is almost like a Seinfeld episode. Nothing happens! The probabilities DON'T CHANGE! You seem to not understand Probability Theory. Otherwise, you would have acknowledged the validity of the proofs, and therefore the uselessness of those other issues as they relate to the Monty Hall Problem. Despite your valiant efforts at requiring 'a rigorous solution', you allowed a COMPLETELY ERRONEOUS STATEMENT to lead the solutions discussion. And have resisted multiple efforts to improve that section! That erroneous statement is at odds with everything that Probability Theory stands for. At times, you've argued with me over the premises of the Monty Hall Problem. Monty opening the CONTESTANT'S door? Give me a break.

Glkanter (talk) 02:28, 27 October 2008 (UTC)

I'm sorry you're finding this frustrating, but I assure you I understand probability theory. You perhaps missed my post in a section above agreeing that the first sentence in the solution section could (should) be deleted. The question about which door the host is opening was asking for a clarification of a comment you made (I'm well aware the host doesn't open the contestant's door). It is in fact not a simple puzzle, which is one reason why it remains so controversial. I'm very patient, and I'm willing to go through this step by step with you if you'd like. It's sounding like you might not like. That's OK, too. If you are willing, I think the first point is the one I ask above. Are there two possible questions? -- Rick Block (talk) 02:46, 27 October 2008 (UTC)

Well, we could debate your grasp of the science, but that would just get personal. I'd just like the interested reader to be able to see a couple or three simple proofs to help him/her understand the solution. That's really the only reason Wikipedia exists. There is a bunch of stuff under the Solutions heading that interferes with that. I, and people before me, have already demonstrated that. Is it possible to speak with your supervisor, or are you the final word?

Glkanter (talk) 03:13, 27 October 2008 (UTC)

Point by point form your response above...

"It doesn't matter which door Monty shows, but only because he's constrained to open one of the two goat doors with equal probability in the case the player initially selects the car. Again, you're asserting this without justifying why this is true."

False. I simply said "It doesn't matter which door Monty shows'. You added the rest. There's nothing to justify. How does Monty's or the contestant's behaviours change based on the door #s, or which goat he reveals? There's nothing in the puzzle about that.

"Regarding the odds not changing, are you saying Monty does not consider opening the door chosen by the contestant? This, by itself, is not sufficient to ensure that Monty's actions don't change the initial 1/3 probability."

Here's where you challanged the assumptions of the puzzle. Sad.

"The total probability must be 100%, and before the host opens a door it's surely 1/3 player's door vs. 2/3 for the other two doors (so 2/3 of the players who decide to switch before the host opens a door will win) but the only thing that keeps it that way after the host opens a door is that pesky equal goat door constraint."

False. The only thing 'keeping it that way' is that pesky law of probabilty that the outcomes must = 100%.

Glkanter (talk) 03:46, 27 October 2008 (UTC)

I am no more, and no less, an editor than you are - although I am an admin on the en.wikipedia site (admins are merely editors who are viewed by the community as trustworthy enough to have certain capabilities not available to most users, like deleting pages and blocking vandals - but admins distinctly do not work for the Wikipedia Foundation, so talking to my "supervisor" is a curious thought). The "final word" here is the consensus of the editors of this page. If you think there's a conflict you're welcome to follow the steps described at dispute resolution. If you'd like, you're also welcome to make whatever changes to the article you think are appropriate, although since you're apparently a new editor I'd suggest you review the 5 pillars. I'll also point out that this article is a featured article and has gone through two featured article reviews. The "stuff" you're objecting to in the Solution section was added in response to the most recent review, so it's not just me you're arguing with here but essentially the entire set of folks who have an interest in this article.

I'm quite willing to discuss this with you (if you'd like) in a less public forum such as your talk page, or mine, or email. -- Rick Block (talk) 04:30, 27 October 2008 (UTC)

Rick, thanks for your comments on my 'very short' solution. I have to say that Glkanter is not alone in being dissatisfied with the basic explanation in the current article. Myself and at least one other editor have also criticised it. It is also obvious from the reactions of editors just passing through (readers) that the article is not as convincing as it could be. Because of the FA status of this page, I am reluctant to just wade in and start editing it, which is why I set up my development page. The hope was that, on that page and it its associated talk page, we could all (old and new editors) work together to find ways to improve this article without compromising its current status. I would therefore suggest that all persons interested in the quality of this article discuss deficiencies of the current solution and proposals for new ones on that page. In particular, I will answer you questions to me above concerning what I do not like about the current article and I will look forward to your replies there.Martin Hogbin (talk) 09:24, 27 October 2008 (UTC)

My development page was set up to allow discussion rather than edit warring so I do not think that it would be right for old and existing editors to completely ignore my page but then start reverting changes to this page based on a consensus reached by those expressing their views on the development page. We need to move forwards but in the right way. Martin Hogbin (talk) 09:24, 27 October 2008 (UTC)

Several editors believe that, although the current article may meet the FA criteria, it still remains unconvincing and also concentrates far to much on variations of the basic problem that are irrelevant to the core problem.

It is therefore proposed that the current solution be replaced with a new version giving simple, intuitive, and verifiable solutions to the basic problem.

Preparation for this new section is taking place on a [[1]] . All interested editors are asked to make their comments on the suitability of this section for inclusion in the current article and to make improvements to the new section. Martin Hogbin (talk) 20:54, 6 November 2008 (UTC)

I couldn't find any discussion on the linked page, but I think the simplest explanation of the solution would be as follows (START):

Sorry, I have now corrected the link [[2]]. Martin Hogbin (talk) 09:26, 7 November 2008 (UTC)

The wording of the puzzle can be misleading because it seems to imply that after the goat is revealed, the player is now picking one of two doors. In reality, when offered a switch, the user is ALWAYS picking between their one door and BOTH of the other doors. Think about it this way. Instead of openening a door with a goat, once the player selects a door, Monty offers the player a choice, they can take whatever is behind their door, or take whatever is behind the two doors they didn't pick. Simple logic tells the player that AT LEAST ONE of those two doors MUST contain a goat, there's only one car. However, the player also knows that two doors are better than one. Since they picked one of three doors, the chance that their door contains the car is only 1/3. The chance that one of the other two doors contains the car is thus 2/3. Whether or not the user switches, we know one of the unpicked doors contains a goat. Revealing the presence of the goat before the switch offers no new information. Monty is not revealing a big secret, everyone knows one of two unpicked doors had to contain a goat. Monty just saved a little suspense and air-time by pre-revealing the goat we knew had to be behind one of the two unchosen doors. Therefore, the odds of winning the car by switching to both of the other doors (before or after the goat is revealed) are always 2/3. The key here is that the user IS switching to BOTH unchosen doors. The one we knew had a goat behind it just happens to already be open.

I think what you are suggesting is pretty much what is on the development page under 'combining doors'.Martin Hogbin (talk) 09:26, 7 November 2008 (UTC)

This solution assumes a couple things:

1. Monty will either randomly or always reveal a goat after the user picks a door. I.e. he knows where the car is.
2. Monty will either randomly or always offer the player the option to switch doors.

Monty randomly offering the trade is equal to always offering the trade, since in this particular instance, the trade was offered. The question becomes moot if Monty didn't offer a trade. If Monty has alterior motives, such as offering a trade only after you already picked the car, then the odds of you winning the car on a trade are 0, and it didn't matter which of the two doors (if either) was opened because once Monty offers the trade you know they both contain goats.

My main point is that not only are the 'assumptions' that you make above the natural ones that most people make, they are also what is clearly stated in the 'Parade' statement of the problem, which is where all the fuss started. It is my contention that the real problem is the one you state above and that this is what the article should concentrate on. Other, essentially academic, possibilities should then be discussed later in the article. Martin Hogbin (talk) 09:26, 7 November 2008 (UTC)

(END) Maybe this isn't any simpler to understand, but this is what I though of as I slowly convinced myself the answer really is 2/3. Hellpimp (talk) 06:41, 7 November 2008 (UTC)

Perhaps you might be able to improve the development article.Martin Hogbin (talk) 09:26, 7 November 2008 (UTC)

Are the doors distinguishable or not? They're numbered, so of course they are. This means there are two questions we can ask.

1) What is the overall chance of winning by switching, averaged across all players?

2) What is the specific chance of winning by switching for only those players selecting a given door (say Door 1) knowing the host has opened a specific door (say Door 3).

The general form of the problem statement asks the second question, not the first one. However, the argument above addresses the first question, not the second. In contrast, the Bayesian analysis section of the article answers the second question. I don't think this is merely an "academic" point. I know the online copy costs money, but I would strongly encourage anyone seriously interested in this problem to read the Morgan et al. paper in the references (it should be available at any university library). If we're attempting to answer the second question, Morgan et al. show the answer is 2/3 chance of winning by switching only if the host is also required to select between two goat doors (if given the chance) with equal probability. Any solution that does not use this constraint (the Bayesian analysis does), is either answering a different question (like the first question, above) or is incomplete (i.e., wrong).

The current structure of the article is to answer the first question first since its solution is easier to grasp, but then acknowledge that the second question is indeed a different question and proceed to answer it. If this structure is not clear, by all means clarify away. IMO, relegating this point to a subsequent "academic" section does our readers an extreme disservice. -- Rick Block (talk) 15:12, 7 November 2008 (UTC)

Although the doors may be distinguishable this is not relevant to the core problem where, to all intents and purposes, they are not. The distinguishably of the doors is another sideline which, in my opinion, should be relegated to an 'academic variations' section of the article.

Regarding the host behaviour on selecting between goat doors, the 'Parade' statement of the problem says,'...the host, who knows what's behind the doors, opens another door, say No. 3, which has a goat...' it does not give us any information as to how the host might choose between two goat doors. In such a case it is not an assumption to take it that this is random but an obligation.

The problem with adding in all these complications is that it makes the article useless at one of its primary purposes which is explaining the solution to readers in a way that convinces them. Martin Hogbin (talk) 18:45, 7 November 2008 (UTC)

And the problem with avoiding these complications is that it makes the article useless at its primary purpose which is summarizing what reliable sources have to say about the Monty Hall problem. We don't avoid things just because they're hard to explain. Where the rubber meets the road here is the references. Two different references that appeared shortly after the vos Savant dust up, Morgan et al. and Gillman, bring up the difference between the two questions that may be asked. Yes, they're both academic papers, but unless there are other references that say these papers are obscuring the "core problem" this notion is simply your opinion. Treatments of the problem in non-academic sources still generally (possibly always) ignore this difference but this does not give Wikipedia an excuse to do so. As far as I know, pretty much all academic sources now include the "equal goat door constraint" in the problem statement. Many do so because it's necessary to justify the Bayesian approach which solves for the probability of winning by switching if the player picks Door 1 and the host opens Door 3. The Bayesian treatments solve for this, rather than simply the probability of winning by switching if the player picks Door 1, because it's what the problem ostensibly asks.

I'm aware that our exchange here has the form of an argument, but I actually don't think we're that far apart. As I've said repeatedly, I'm fine with presenting an "intuitive" solution answering the easier question first. And, indeed, the article currently does this (and whether the current intuitive solution is the most convincing is certainly debatable). However, I'm not fine with the Solution section including only something that one of the main academic references calls a "false solution".

I'll solicit other opinions about this at Wikipedia:WikiProject Mathematics. Most folks there are aware that this problem is a notorious quagmire, so it is somewhat difficult to get them to comment but I'll try. -- Rick Block (talk) 03:44, 8 November 2008 (UTC)

The solutions proposed properly solve the paradox using established Probability Theory. All this other stuff adds no value.

Glkanter (talk) 07:10, 8 November 2008 (UTC)

I got it! Start a new Wikipedia article called 'The Equal Goat Door Constraint Paradox'! Marilyn vos Savant can write a column about it in her general interest Sunday magazine column. People all over the world will marvel at how counter-intuitive the solution is, when all along, after a trip to the nearest university library, Morgan, et al and Bayesian statistics were there to explain it. Glkanter (talk) 16:17, 8 November 2008 (UTC)Glkanter (talk) 16:26, 8 November 2008 (UTC)

I'm responding to Rick's WT:WPM post. Any attempt to make the article clearer is a good idea, but it must be based upon the fact that Wikipedia is an encyclopedia. Its job is to document the knowledge found in reliable sources, not to synthesise explanations in the literature to provide the clearest and most convincing one. This article is not entitled "Explanation of the Monty Hall Problem" and Wikipedia generally doesn't have articles with such titles because they are not encyclopedic and typically involve taking a point of view. The job of this article is not to convince the reader, but to present them with information. That's the difference between an encyclopedia and a textbook: the latter aim to educate the reader, the former are a resource which help the reader to educate themselves.

Wikipedia does not have disclaimers, does not assert viewpoints, and does not contain original research. Geometry guy 19:48, 9 November 2008 (UTC)

The application of WP policies to this problem is full of difficulties. We do not need a cut-and-paste approach to verifiability, neither do we want opinion, but where between these two extremes to we want to be? What is a reputable source? In this subject there have been many sources that would normally be considered reputable that have got the answer wrong. Common sense is no help either. I am not saying it is easy but I believe that we can do better.

Clearly, the current article does not just, 'document the knowledge found in reliable sources' neither should it, in my opinion. What is the point of having an article the contains information if nobody believes it?

Finally, what is the justification for the current article's current concentration on academic variations of the problem. This is not what makes the problem notable. Martin Hogbin (talk) 23:24, 9 November 2008 (UTC)

Between the two extremes we want (from Wikipedia:Featured article criteria) to be factually accurate: claims are verifiable against reliable sources, accurately represent the relevant body of published knowledge, and are supported with specific evidence and external citations.

What constitutes a reputable (reliable) source is defined at Wikipedia:Reliable sources.

Per the quote from the featured article criteria above, the point is to accurately represent the relevant body of published knowledge. What is to be believed about any article is that it does this. References are included specifically so readers can verify that what is said in the article is supported by published sources.

I'm not sure what you mean by the article's current "concentration on academic variations", but (also per the FA criteria) articles should be comprehensive: it neglects no major facts or details. More on this from Wikipedia:Neutral point of view: content must be written from a neutral point of view (NPOV), representing fairly, and as far as possible without bias, all significant views that have been published by reliable sources. -- Rick Block (talk) 15:43, 10 November 2008 (UTC)

The following introduction is still confused suffering from poor English, a lack of clarity and some misconceptions.

"Because there is no way for the player to know which of the two unopened doors is the winning door, most people assume that each door has an equal probability and conclude that switching does not matter. In fact, in the usual interpretation of the problem the player should switch—doing so doubles the probability of winning the car from 1/3 to 2/3. Switching is only not advantageous if the player initially chooses the winning door, which happens with probability 1/3. With probability 2/3, the player initially chooses one of two losing doors; when the other losing door is revealed, switching yields the winning door with certainty. The total probability of winning when switching is thus 2/3."

The object of the problem is not whether the person wins the automobile but how the probability shifts when a door is exposed (with a goat). If the person selects the correct door or not on the first guess is irrelevant to the problem - especially as an introduction.

A breakdown:

(1) Because there is no way for the player to know which of the two unopened doors is the winning door, most people assume that each door has an equal probability and conclude that switching does not matter.

Is fine

(2) In fact, in the usual interpretation of the problem the player should switch—doing so doubles the probability of winning the car from 1/3 to 2/3.

Does not need "in the usual interpretation of the problem" in the introdcution.

(3) Switching is only not advantageous if the player initially chooses the winning door, which happens with probability 1/3.

Should read, "If the player initially chooses the winning door then changing is clearly disadvantageous" I don't even think it is necessary as this is confusing in the introduction.

(4) With probability 2/3, the player initially chooses one of two losing doors; when the other losing door is revealed, switching yields the winning door with certainty.

Is badly constructed. It should read, "If the player has initially chosen one of the two losing doors: when one of the losing doors is revealed then switching wins the player the automobile."

However, I would argue that this isn't even needed anyway.

(5) The total probability of winning when switching is thus 2/3.

Is a non-sequitur as the paragraph is referring to two different scenarios (ref to 2 and 3). Both scenarios, incorrect first choice and correct first choice cannot lead to the same probability of winning when switching. --Candy (talk) 22:52, 24 November 2008 (UTC)

So, in summary, you're suggesting a change to perhaps something like:

Because there is no way for the player to know which of the two unopened doors is the winning door, most people assume that each door has an equal probability and conclude that switching does not matter. In fact, the player should switch—doing so doubles the probability of winning the car from 1/3 to 2/3. If the player initially chooses the winning door with probability 1/3, then changing is clearly disadvantageous. If the player has initially chosen one of the two losing doors with probability 2/3, then after the other losing door is revealed switching wins the automobile. The total probability of winning for all players who switch is thus 2/3.

or cutting the explanation after the "In fact" sentence. I'd support cutting the explanation (for reasons discussed at length in previous threads on this talk page this explanation is somewhat less than completely satisfactory). -- Rick Block (talk) 02:54, 25 November 2008 (UTC)

Reversion of good faith edits should not be marked as minor. Martin Hogbin (talk) 20:27, 11 December 2008 (UTC)

Is there some specific revert you're talking about here? -- Rick Block (talk) 00:49, 12 December 2008 (UTC)

Recent reverts marked as minor:

• Nov. 1 by Belinrahs - reverted humorous comment
• Dec. 3 by Iridescent - reverted vandalism
• Dec. 4 by Paul August - reverted change of 2/3 to 1/3 - sneaky, but possibly good faith
• Dec. 11 by Rick Block - reverted additions - probably good faith - the edit combined an addition to an image caption (that could be good faith) with another addition (that clearly wasn't) - I think Martin missed that bit (I know I did!).--Noe (talk) 12:53, 12 December 2008 (UTC)

Sorry, I did miss that. Martin Hogbin (talk) 20:11, 12 December 2008 (UTC)

I've moved the following link which was added to the article here. There's nothing on this page that can't be incorporated directly into the Wikipedia page, per WP:EL that means it is not an appropriate external link.

• The Monty Hall Problem at LEEPS, a lab run by Dr Dan Friedman (a prominent economist at UC Santa Cruz).

-- Rick Block (talk) 14:39, 19 December 2008 (UTC)

--- I believe the above link should be on the main page for the Monty Hall Problem. It cites important academic journals and articles on the issue. We cannot ignore literature that discuss this problem as it was a hot topic of discussion amongst prominent economists and mathematicians. Some of the articles mentioned in the above link do form a basis to the solution that is widely accepted today. - Aadn

From WP:EL#Links normally to be avoided:

1. Any site that does not provide a unique resource beyond what the article would contain if it became a Featured article.

Also from WP:EL (Advertising and conflicts of interest):

You should avoid linking to a website that you own, maintain or represent, even if the guidelines otherwise imply that it should be linked. If the link is to a relevant and informative site that should otherwise be included, please consider mentioning it on the talk page and let neutral and independent Wikipedia editors decide whether to add it.

The first of these definitely applies here and I strongly suspect the second does as well. The LEEPS page itself does not meet Wikipedia's standard for reliable sources, so shouldn't be used as a reference either. You are perfectly welcome to add citations drawn from the LEEPS page to the history section, especially any that are considered major or important. Note that there are dozens (if not hundreds) of published papers on this problem, so clearly most of them will not be mentioned here. -- Rick Block (talk) 05:22, 21 December 2008 (UTC)

What if I want the goat and not the car? Should this probability also be addressed, even if it's not part of the original Monty Hall problem? 76.95.124.146 (talk) 15:09, 8 January 2009 (UTC)

This question may be useful in settling the issue of how best to explain the solution. The goats are actually a distraction from the real puzzle, serving much the same purpose in this trick puzzle as "misdirection" serves a magician. If a goat is an anti-prize, worse than neutral, then it may be more difficult to grasp why the revealing of a goat behind a non-chosen door is not useful information in solving this particular puzzle, although it can be useful in solving other puzzles that resemble it. The first step to providing a convincing explanation of the solution may be to remind the solver that one is not actually required to take the goat home if the goat is chosen! (In fact, a goat is equivalent to no prize at all.) This may disappoint 76.95.124.146, but for other solvers, it may be a good first step to understanding the puzzle. Perhaps it is unfortunate if no reliable source has taken this approach.Simple314 (talk) 03:29, 11 January 2009 (UTC)

Actually, I think that our IP contributor has hit on a decent approach to explaining the solution. If you want a goat, you should stick with your first choice, because you know that you have a 2/3 chance of picking a goat initially. Monty opening a door cannot change the odds of your initial choice being correct, although it can confuse you about those odds.

Now, since sticking with your first choice is the best strategy if you want a goat, and since you're faced with a binary decision, then making the other decision must be the best strategy if you want a car. SHEFFIELDSTEEL^TALK 15:53, 18 February 2009 (UTC)

I've undone this edit which adds an introductory paragraph to the Solution section with numerous WP:MOS issues discussing an alternate problem (boxes rather than doors). The addition is essentially the same as the existing "combining doors" section. The text is in the history if anyone wants to talk about it. -- Rick Block (talk) 06:01, 24 January 2009 (UTC)

I've deleted the addition of the following new section.

Minesweeper analogy

An analogy which might have a more intuitive solution is the computer game Minesweeper with the minor change that the game is played without numbers indicating mines. Suppose one mine (the equivalent of the car) is hidden in a 100x100 grid. The first action by the player is to randomly plant a flag on one of the squares (equivalent of picking a door at the beginning). The player clicks on a square without the mine (this is actually how many versions of minesweeper are programmed, the first click cannot be a mine) clearing the entire grid except for one square and the one flagged by the player (the equivalent of Monty opening the door revealing a goat). For anyone familiar with the game Minesweeper, the intuition here is that the mine is under the unflagged square since the player flagged the square randomly at the beginning of the game. This analogy also removes any possible motivation on Monty's part to trick the player which may be confusing in the classic example.

Although interesting, it's unreferenced and sounds like WP:OR (and requires an understanding of Minesweeper). If anyone can find a reliable source including this analogy we can talk about re-adding it. -- Rick Block (talk) 01:43, 25 January 2009 (UTC)

It's a very good analogy, though, and in fact it's a form of the "increased number of doors" explanation. But it does have a critical flaw: if the player actually manages to flag the mine, all the other squares will get cleared, which would be the equivalent of Monty revealing every single goat. So it actually simulates a very different "Monty" -- one who reveals every goat unless there's one behind your door.--Father Goose (talk) 09:41, 25 January 2009 (UTC)

The description mentions that all the squares except the initially flagged one and one more are cleared (making it not quite like minesweeper). Perhaps a truer version would be you flag one, Monty flags another, and then Monty clicks one he knows isn't the winner. This actually scales down to a 3-square version identical to the MH problem. In any event, if it's not published I don't think we should even consider using it. If it is published we could talk about it, but even then I'm not sure it really adds anything. -- Rick Block (talk) 17:20, 25 January 2009 (UTC)

Still no good: in most cases you'll be left with three unrevealed squares: your flag, the host's flag, and the actual location of the mine. Even in the three door version, it won't work: if both of you pick goats (flag an empty square), when you click on the last remaining square (the mine), the game will move the mine under either your flag or his, presumably randomly. So there's no restricted choice on his part: both his choice and yours are entirely random. It's the "host doesn't know" scenario.--Father Goose (talk) 21:21, 25 January 2009 (UTC)

The, what is often called, "simple solution", saying: the player originally has a chance 1/3 of winning, so switching increases this chance to 2/3, is theoretically wrong! This explanation is also offered directly under "Solution" , and although it offers numerically the right answer,it is not correct, as may be seen by comparing it to the statement of the problem right above it. In the problem statement the question is: Should the player switch to Door 2? And in the solution the player is allowed to switch to Door 3 as well. The point is, and I think it is mentioned somewhere in the above discussions, that the posed question can only ask for a conditional probability, given the situation, i.e. Door 1 chosen and Door 3 opened revealing a goat. This is also clear from the equivalence with the Three Prisoners problem and Bertrand's box paradox.Nijdam (talk) 11:26, 3 February 2009 (UTC)

Rather than flat out "wrong", I'd say the simple solution is a correct solution to a slightly different problem. This is the point of the three paragraphs below the large figure in the Solution section of the article. Many (possibly nearly all) people interpret the question to apply to all players unconditionally rather than only those players seeing a specific open door (and a fair number apparently cannot understand that these are actually different questions). These people would claim the wording "say you've picked Door 1 and the host opens Door 3" is saying that we are to assume all specific situations are equally likely, in which case the unconditional and conditional answers must be the same. If you can make this more clear in the article, please do so. -- Rick Block (talk) 14:49, 3 February 2009 (UTC)

This is an other way of putting it. But as the article is so precise in defining the problem, with all guarantees of no possible misinterpretation, the given "simple solution" is no solution to this precise stated problem.Nijdam (talk) 16:04, 3 February 2009 (UTC) —Preceding unsigned comment added by 82.75.67.221 (talk)

I've revised your clarification. Are you OK with the revised version? -- Rick Block (talk) 19:34, 3 February 2009 (UTC)

Any of you recent contributors may not have read this page in its entirety. It's pretty long. So, just to let you know, many, many people are very unsatisfied with the entire article. It's long winded, confusing, and outright wrong in places. But we respect the process, so here we are. Search for my signature, as one example. Glkanter (talk) 03:30, 4 February 2009 (UTC)

Let me see if I've got this right. Glkanter thinks the simple solution (the part above the large figure in the solution section) is ridiculously long winded but conveys the only essential aspect of the solution, and the part below the figure is incomprehensible and wrong and should be deleted. Nijdam thinks the part above the figure is wrong and, if not deleted, should be prefaced with something like "the following is wrong:". How about if you two talk. I'd be happy to try to moderate. -- Rick Block (talk) 05:48, 4 February 2009 (UTC)

I tried to follow the discussion above between the two of you, and I actually got confused, not about the problem or the solution, but about you. I'm not very happy with Rick's revision of my extension to the "simple solution". My extension shows in essence the flaw in this way of reasoning. I showed that the "simple solution" is not a solution to the stated problem. It's like the man, searching in the evening for his lost wallet under a streetlamp where things are well visible, allthough he knows he lost the wallet in a dark side alley. So I invite either one of you to read my extension an comment on it.Nijdam (talk) 10:49, 4 February 2009 (UTC)

I did a little more reading of the above discussion about this topic and I think I find Rick on my side, but Glkanter opposed because of the reasoning: 1/3 + 2/3 = 1, meaning: the initial probablility is 1/3 of picking the car, so whatever happens, as (!?????) this has not changed, the final probability of the alternative should be 2/3. Well as you may guess, I already indicate where it goes wrong. The "initial probability changes" under the assumed condition. Among all possible cases, the ones with the car behind Door 1 and Door 3 openend, only form 1/6th.Nijdam (talk) 11:28, 4 February 2009 (UTC)

Nijdam's version is here. My revision is the next edit in the history. I have two issues with Nijdam's version. 1) It's a little too harsh on the "simple solution". In its current form, this solution doesn't say anything that is actually incorrect it just doesn't precisely answer the question. Also, like it or not, it is what is commonly presented as the "solution". 2) The style doesn't follow Wikipedia style guidelines, in particular see Wikipedia:Manual of Style (mathematics)#Writing style in mathematics. -- Rick Block (talk) 15:02, 4 February 2009 (UTC)

Nijdam, please show me the error in the 1/3 + 2/3 = 1 (100%) solution. I'd also like to know what is unacceptable about Martin's solution, 2/3 of the time I choose a goat, and 100% of those times Monty show me the other goat? Everything else, from Morgan, et al, to Bayesian, to "We have run simulations that prove this" is wasted binary digits. Glkanter (talk) 23:12, 4 February 2009 (UTC)

I thought you were skilled enough to directly understand the problem. First: The "simple solution" is not a solution at all, i.e. not to the stated problem. As Rick puts it: "it just doesn't precisely answer the question"!! As if this is not enough reason to be harsh. 2) I'm really completely stunned about this. Let us translate the situation to an exam. Well, the professor utters: "let's not be too harsh on this "solution". Nothing is really incorrect, it just doesn't answer my question." 3) At least Rick understands it is wrong. 4) Why is it wrong? As I explained in my text, the "solution" offers the possibility that Door 2 is opened, and the statement of the problem excludes this. 5) Now about the specifc question about Martin's reasoning. It has the same flaw: it doesn't answer the posed question. Of course it is the right answer to the right alternative question, which I may present as follows: the player is blind and Monty only tells him: I opened one of the other doors and there is a goat behind it. But that is not the case in de stated problem. There the player sees that Door 3 is opened and shows a goat, and hence the conditions of the problem are accordingly formulated. 6) All this is because after some events has happened, we want to know the conditional probabilities, given these events. Compare it with throwing a fair dice and suppose it shows 6. What is the probability it will show 5? (0 or 1/6???). I hope it becomes clear to you. Sorry, forgot to log in.Nijdam (talk) 23:56, 4 February 2009 (UTC)

In a moderating kind of way, I have two suggestions here. 1) Please comment on content, not on other editors' mental facilities. WP:COOL has some good suggestions. 2) As far as possible, please support arguments with references rather than arguing what you simply know to be the Truth. There are no shortage of references about the Monty Hall problem - any significant point has almost certainly been published (at least once). -- Rick Block (talk) 02:00, 5 February 2009 (UTC)

Following my own advice - to Glkanter, the issue with both your and Martin's solutions is explained in Morgan et al. These are both variants of what Morgan et al call "false solution F1".

Solution F1. If, regardless of the host's actions, the player's strategy is to never switch, she will obviously win the car 1/3 of the time. Hence, the probability that she wins if she does switch is 2/3.

F1 is immediately appealing, and we found its advocates quite reluctant to capitulate. F1's beauty as a false solution is that it is a true statement! It just does not solve the problem at hand. F1 is a solution to the unconditional problem, which may be stated as follows: "You will be offered the choice of three doors, and after you choose the host will open a different door, revealing a goat. What is the probability that you win if your strategy is to switch?" The distinction between the conditional and unconditional siutations here seems to confound many, from whence much of the pedagogic and entertainment value is derived.

Similarly, Gillman 1992 (referenced in the article) criticizes vos Savant's solution:

Marilyn's solution goes like this. The chance is 1/3 that the car is actually at #1, and in that case you lose when you switch. The chance is 2/3 the car is either at #2 (in which case the host perforce opens #3) or at #3 (in which case he perforce opens #2) - and in these cases, the host's revelation of a goat shows you how to switch and win.

This is an elegant proof, but it does not address the problem posed, in which the host has shown you a goat at #3. Instead it is still considering the possibility that the car is at #3-whence the host cannot have already opened that door (much less to reveal a goat). In this game-you have to announce before a door has been opened [emphasis in the original] whether you plan to switch.

These are both from academic WP:reliable sources (The American Statistician and American Mathematical Monthly), and the article is (at this point) attempting to present the information contained in these sources.

Rick, can you please clarify the following paragraph? It is essential to my understanding of the criticism. Thank you.

This is an elegant proof, but it does not address the problem posed, in which the host has shown you a goat at #3. Instead it is still considering the possibility that the car is at #3-whence the host cannot have already opened that door (much less to reveal a goat). In this game-you have to announce before a door has been opened [emphasis in the original] whether you plan to switch.

Glkanter (talk) 16:45, 7 February 2009 (UTC)

Rick, I'm still waiting for your clarification of the above statement. As it is central to your claim of the non-validity of my proof. What does this mean:

'In this game-you have to announce before a door has been opened [emphasis in the original] whether you plan to switch.'?

Are they talking about the Monty Hall Problem or some varient? Or is this the 'before switching' beast you speak of? MOST IMPORTANTLY, what possible relavence can it have to my proof?

Glkanter (talk) 07:30, 8 February 2009 (UTC)

Is the view that the "simple solution" is sufficient supported by equally reliable sources? If so, which sources and what do they say? -- Rick Block (talk) 04:56, 5 February 2009 (UTC)

Well, don't be offended; take it as a complement instead, because from the discussions above I concluded both of you are well skilled at least in mathematics. Yet you keep asking for arguments, which I gave in the extension of the article and extensively above. Moreover, Rick quotes the same arguments I gave. So what more needs to be said? If the "simple solution" as a solution to the well stated problem, is supported by any source, the conclusion can only be, this source is not reliable. The only necessity is changing he article, as I suggested.82.75.67.221 (talk) 10:01, 5 February 2009 (UTC)

Just to be clear, you're arguing for reinstating this change (right?), which prefaces the simple solution with:

The following "solution" is often stated, but is not the correct solution to the problem, because in the above precise stated problem not only did the player picks Door 1, but is it also known that Door 3 is opened and shows a goat. Let us yet follow the reasoning and see what goes wrong.

and interjects a new paragraph

For the attentive reader it will be clear that the player in this solution is also confronted with the possibility to find Door 2 opened showing a goat and offered to switch to Door 3. This is not allowed in the statement of the problem. However there is a way to work around it. Looking at the pictures we see this is the case in the first and the last picture in the last row. If we restrict the analysis to the other cases (for the probabilistic skilled reader this means conditioning on these events), the (conditonal) probability of winning the car by switching is 1/3 against 1/3+1/6, which is also 2/3.

before the more technically correct solution. The current structure is to start with a commonly presented simple solution being careful to avoid saying anything that is actually incorrect (in particular, qualifying that this solution applies to all players before the host opens a door), and then transition into the more precisely correct solution. I've tried to clarify the transition, as follows:

Although the reasoning above is correct it doesn't answer the precise question posed by the problem, which is whether a player should switch after being shown a particular open door (Morgan et al. 1991). Answering this question requires determining the conditional probability of winning by switching, given which door the host opens. The difference is whether the analysis, as above, considers all possible scenarios or only the scenarios where the host opens a specific door. The conditional probability may differ from the overall probability depending on the exact formulation of the problem (see Sources of confusion, below).

I think this follows the sources fairly faithfully, leading the reader to the more technically correct solution without making a huge point out of it. I think it is true (I don't have a handy reference, but could perhaps find one) that even though the detailed problem statement is mathematically unambiguous many people misinterpret it as asking about the unconditional probability (for which the simple solution is the correct answer). As I've said, calling the simple solution wrong seems overly harsh - particularly since the unambiguous version is specifically designed to end up with the same answer (I don't have a reference for this either, but it seems fairly obviously true). -- Rick Block (talk) 15:36, 5 February 2009 (UTC)

Well, I find it unacceptable to start with a "solution" that isn't a solution. My suggestion (please improve my English, as I'm foreign):

According to the problem statement above, a car and two goats are arranged behind three doors and then the player initially picks a door. Assuming the player's initial pick is Door 1 (the same analysis applies for any other door the player picks):

• The player originally picked the door hiding the car. The game host must open one of the two remaining doors randomly.
• The car is behind Door 2 and the host must open Door 3.
• The car is behind Door 3 and the host must open Door 2.

This leads to the following situations:

Car hidden behind Door 1		Car hidden behind Door 2	Car hidden behind Door 3
Player initially picks Door 1
Host opens either goat door		Host must open Door 3	Host must open Door 2
This hasn't happened	This happens with "probability" 1/3	This happens with "probability" 2/3	This hasn't happened
	Switching wins in 2 out of 3 cases

Players who choose to switch win if the car is behind Door 2. This is the case in 2 out of 3 cases, so with 2/3 probability.

This means if a large number of players, after choosing Door 1 and being showed a goat behind Door 3, randomly choose whether to stay or switch, then approximately 1/3 of those choosing to stay with the initial selection and 2/3 of those choosing to switch would win the car. This result has been verified experimentally using computer and other simulation techniques (see Simulation below).

Nijdam (talk) 17:56, 5 February 2009 (UTC)

How about this? (and your English is far better than my Dutch) -- Rick Block (talk) 02:58, 6 February 2009 (UTC)

---

According to the problem statement above, a car and two goats are arranged behind three doors and then the player initially picks a door. Assuming the player's initial pick is Door 1 (the same analysis applies for any other door the player picks):

• The player originally picked the door hiding the car. The game host must open one of the two remaining doors randomly.
• The car is behind Door 2 and the host must open Door 3.
• The car is behind Door 3 and the host must open Door 2.

This leads to the following situations:

Car hidden behind Door 1		Car hidden behind Door 2	Car hidden behind Door 3
Player initially picks Door 1
Host opens either goat door		Host must open Door 3	Host must open Door 2
Switching loses with probability 1/6	Switching loses with probability 1/6	Switching wins with probability 1/3	Switching wins with probability 1/3
Switching loses with probability 1/3		Switching wins with probability 2/3

Looking at the figure above, in cases where the host opens Door 3 (which is the case according to the problem statement) switching loses in a 1/6 case where the player initially picked the car and wins in a 1/3 case where the player initially picked a goat. Players who choose to switch win twice as often as players who stick with the original choice, which is a 2/3 chance of winning by switching.

This means if a large number of players randomly choose whether to stay or switch after initially choosing Door 1 and being shown a goat behind Door 3, then approximately 1/3 of those choosing to stay and 2/3 of those choosing to switch would win the car.

---

We'd probably need to follow this up with a discussion of the typical unconditional solution and why it is not responsive to the question that's asked. I think this structure is probably less accessible than the current structure to someone not mathematically sophisticated (indeed, as Morgan et al. comment, "the distinction between the conditional and unconditional situations here seems to confound many"). Typical Wikipedia style is to start with broadly accessible content and then go deeper (see Wikipedia:Make technical articles accessible), which is the overall intent of the current structure. As I've said the current structure is meant to present an analysis that perhaps doesn't quite address the question that's asked (but is not actually wrong) leading into an technically correct solution. I think this is an article of more interest to laypersons than mathematicians (although mathematicians frequently get this problem wrong as well), so I think anything we can do to make the solution generally accessible is worthwhile. -- Rick Block (talk) 02:58, 6 February 2009 (UTC)

Sorry, among all the almost simultaneous contributions to this page, I didn't notice this part. I'm sorry too to say I prefer my suggestion. Especially because the exact formulation of the problem, as given in the article, states Door 1 is chosen and Door 3 opened.Nijdam (talk) 12:23, 8 February 2009 (UTC)

Note: There's a summary below, see #Request for brief clarifications. -- Rick Block (talk) 20:55, 8 February 2009 (UTC)

Monty does not pick doors randomly. He always reveals a goat. And it does not matter which goat. I'm still waiting to hear why Martin's solution is not satisfactory.

Glkanter (talk) 23:47, 5 February 2009 (UTC)

Please read the excerpts from Morgan et al. and Gillman, above. Even more directly, Morgan et al. discuss what they call false solution F5:

Solution F5: The probability that a player is shown a goat is 1. So conditioning on this even cannot change the probability of 1/3 that door 1 is a winner before a goat is shown; that is, the probability of winning by not switching is 1/3, and by switching is 2/3.

Solution F5, like F1, is a true statement that answers a different problem. F5 is incorrect because it does not use the information in the number of the door shown.

We've been through this before, but the easiest way I know of to show there are two different problems, and to figure out which one a given solution is addressing, is to change the assumptions slightly so that the answers to the two problems are different. When the answers are the same it's hard to tell which one a given solution is addressing (is it this 2/3 or that 2/3?). The slight change (also from Morgan et al) is to give the host a preference for one door over the other. To make it the most extreme, let's constrain the host to open the leftmost door if possible (still always showing a goat, but opening the leftmost door unless this would reveal the car). The question remains the same, i.e. if a player initially picks door 1 and the host opens door 3 what is the chance of winning by switching? Martin's solution still applies - the chance of initially picking a goat is 2/3 and the host most show the other goat. So, Martin's solution says the answer to this variant is 2/3 chance of winning by switching (right?). On the other hand, in this variant if the host opens door 3 (which we've said he did) we know for sure the car is behind door 2 so with the given setup (player picks door 1, host opens door 3) the chance of winning by switching is 100%. The essentially "wrongness" of Martin's solution is now making it come out with the wrong numerical answer. It is still the right answer for a different question, specifically what is the chance of winning for a player who decides to switch before seeing which door the host opens. But in both variants, this is not the question we're asking.

I think you don't like analogies but I'll try one anyway. Let's say we're asked what the square of squareroot(4) is. One solution is "squareroot(4) = 2, 2 squared is 4, the answer is 4". This is the right answer, but the solution is technically incorrect because squareroot(4) is either 2 or -2. For this particular numerical problem it doesn't matter if you ignore the negative root, but the solution is clearly wrong. We can expose the flaw by changing the question, for example "what is twice the squareroot(4)". We have a very similar issue here. No one's arguing that the answer (2/3 chance of winning by switching) is incorrect. It is correct. It's just not answering the question that's asked. -- Rick Block (talk) 02:01, 6 February 2009 (UTC)

I'll be honest. I don't understand most of what you guys are talking about. It's a simple puzzle. Do you increase your chances of winning the car by switching? It's been years since I took a Logic course, or a Probability and Statistics course, so I can't cite chapter and verse. But the goal is to present a valid proof with as little complication as possible. So you take shortcuts, which don't affect the proof. Two goats? I only care about the car. Ignore the goats in the proof. 3 doors? There'll only be one 'other one' left when I'm asked to switch. Ignore the door #s in the proof. Conditional probability? Don't know what it means. Don't see how anything is conditional here. Two closed doors when I'm asked if I want to switch, exactly one has a car. No conditions exist.

I do remember something about a requirement for proofs being valid and true. 2/3 of the time the remaining door I didn't choose has a car. Both valid and true.

That's why the real game show didn't work like this. Glkanter (talk) 03:16, 6 February 2009 (UTC)

The essential point is regarding the question that's being asked. Is it

a) "what is the chance of winning for a player who decides to switch before seeing which door the host opens"

or

b) "what is the chance of winning for a player who decides to switch after seeing which door the host opens"

I think most statements of the problem at least implicitly ask the second question (the unambiguous version in the article explicitly asks the second). Martin's solution addresses the first question. Since the numerical answers to these two questions can be different (per the variant mentioned above), a solution for one is clearly not the same as a solution for the other. Simply because a "valid and true" solution for #a ends up with the right numerical answer for #b (which it might for some versions of the problem), doesn't make it a "valid and true" solution for #b.

Putting this yet another way, if there are 3000 people who go on the show and initially pick door #1, roughly 1000 will pick the car and roughly 2000 will pick one of the goats. What Martin's solution is saying is that if all 3000 decide they're going to switch before seeing what door the host opens, roughly 2000 will win the car. However, the problem statement says we know the host opens door 3 so the divisor is not 3000. What is the actual divisor (roughly how many times will the host open door 3) and how do you know this? In how many of these cases will the player have initially picked the car? To answer what the probability is of winning the car by switching if the host opens door 3 these are the numbers you need to know. What does Martin's solution have to say about either of these? -- Rick Block (talk) 04:58, 6 February 2009 (UTC)

Okay Rick, at least I see you completely knows the ins and outs. So what to do? I cannot accept a reasoning that's logically wrong. What about the suggestion I made above, by changing the given "simple solution" in such a way that some possibilities are ruled out as not happened?Nijdam (talk) 11:54, 6 February 2009 (UTC)

There are really only two situations to consider. Not 3, not 6.

2/3 of the time I will choose a goat.

100% of those times Monty reveals the other goat, leaving the car.

=>2/3 of the time I should switch.

1/3 of the time, I will choose the car.

100% of those times Monty reveals one of the goats. It doesn't matter which.

=>1/3 of the time I should not switch.

2/3 is greater than 1/3.

Therefore, by switching, I increase my chances of getting the car when offered the switch.

I earlier said a good proof uses 'shortcuts'. A better phrasing would have been 'eliminates the unessential' from the proof. That is, a goat is a goat, and a door is a door.

Martin's proof, and the one above, address the problem as defined. To deny that is incorrect. [User:Glkanter|Glkanter]] (talk) 13:34, 6 February 2009 (UTC) 63.97.108.114 (talk) 14:19, 6 February 2009 (UTC)Glkanter (talk) 14:22, 6 February 2009 (UTC)

Please reread my responses above. Per Morgan et al., Martin's proof, and your proof above are perfectly correct if the question is "what is the chance of winning for a player who decides to switch before seeing which door the host opens". But, the actual question is "what is the chance of winning for a player who decides to switch after seeing which door the host opens". These questions are different and that they happen to have the same numerical answer in this specific case doesn't mean a solution for one is also a solution for the other. I'm sorry if you don't understand this, but I don't know how to make it more clear. Whether you understand it or not, it is what multiple Wikipedia:Reliable sources say so should be included in the article. -- Rick Block (talk) 15:29, 6 February 2009 (UTC)

Nope. I don't get it at all. My proof above very clearly is the case after showing the goat door. I think this 'before and after' dichotomy is a canard. I've said before, and you just agreed above, that Monty's action doesn't change anything. That is, he provides no new useful knowledge. The proof of this is that the probabilities haven't changed.

It takes exactly one valid proof to solve a problem. That proof has been demonstrated.

Glkanter (talk) 16:19, 6 February 2009 (UTC)

The key here is "valid", which your proof is not according to two papers written by mathematicians published in math journals. What we want in the article is what published papers have to say about this problem. I'd prefer if you understood it, but ultimately whether you do or don't doesn't actually matter. -- Rick Block (talk) 05:40, 7 February 2009 (UTC)

Thank you for the specific response to my question. I'll try to look at those papers. I suppose Morgan, et al is one of those mathemeticians, who's the other?

Do I understand your response to Nijdam correctly? Does "many published sources (possibly all popular expositions of this problem) include only an unconditional solution" mean that the solution I've been advocating is what most other references provide as the only solution?

Would you indulge me? In your own words, tell me which of the eight statements, beginning with '2/3 of the time I will choose a goat' and ending with 'Therefore, by switching, I increase my chances of getting the car when offered the switch.' is either untrue, invalid, or not germain to the question 'Now that Monty has revealed a goat, do you increase your chances of winning a car by switching'?

Thank you. Glkanter (talk) 07:06, 7 February 2009 (UTC)

The two papers I mentioned are referenced in the article, see Morgan et al. (written by John P. Morgan and others) and Gillman 1992 (written by Leonard Gillman). Both of these papers are available online for a fee and should be available at any university library. I've quoted relevant sections above.

The response to Nijdam below does indeed mean the solution you're advocating is what many popular (as opposed to academic) references provide as the solution. The two papers mentioned above were written in direct response to vos Savant's solution published in Parade Magazine. I've said all along the simple solution is correct as far as it goes, but it doesn't technically answer the question that's asked. My guess is because the numerical answer is the same, and the distinction between the two questions eludes many, even many academics are willing to let bygones be bygones. On the other hand, some academics (apparently including Nijdam) are less willing to accept the simple solution because it doesn't actually answer the question that is asked (this is like a teacher requiring you to show your work and marking your answer wrong because your work is wrong even though you got the right numeric answer).

I've tried repeatedly to point out what's wrong with your solution. I'll try once again. The problem step is

100% of those times Monty reveals the other goat, leaving the car.

This is where the solution goes astray. It is a correct statement, but "100% of those times" includes both times when the host opens door 2 and times when the host opens door 3. By including both doors the host may open, what this solution is showing is that if you decide to switch before seeing which door the host opens (knowing the host will open a door to show a goat) you'll win by switching 2/3 of the time - meaning roughly 2/3 of all players who switch will win. Absolutely correct. Check. But, the actual question is what is your probability of winning by switching after seeing which door the host opens, i.e. if you see the host open door 3, the question we're actually interested in is how many players who see the host open door 3 win by switching. I think you probably believe it can't possibly matter which door the host opens and the chances must be the same in both cases. The issue is it can matter and the chances might be different in these cases. I'm willing to bet this is where I lose you every single time.

If we're interested in the probability of winning by switching after seeing which door the host opens, there are actually two numbers we need to figure out, not just one. If we assume the player initially picks door 1, we need the probability of winning if the host opens door 2 and (separately, because it might be different) the probability of winning if the host opens door 3. These are driven by our expectations for the following:

A) The percentage of players who initially pick a goat and the host opens door 2 (i.e. 1/3)

B) The percentage of players who initially pick a goat and the host opens door 3 (i.e. 1/3)

C) The percentage of players who initially pick the car and the host opens door 2 (what is this, and why?)

D) The percentage of players who initially pick the car and the host opens door 3 (what is this, and why?)

The simple solution says nothing about these last two numbers. The probability of winning by switching for players who see the host open door 3 is B/(B+D) and, similarly, for players who see the host open door 2 is A/(A+C). If we don't know C or D, we don't know either of these probabilities. The simple solution is based on knowing only A and B, and says for all players (i.e. if we decide to switch before knowing which door the opens) we win with probability (A+B)/(A+B+C+D). We can figure this out because we know whatever C and D are, (A+B+C+D)=1.

As it turns out, the extra condition we impose on the host in the explicit problem statement (If both remaining doors have goats behind them, he chooses one randomly) allows us to determine C and D are both 1/6. This lets us conclude the probability of winning by switching if the host opens door 3 is (1/3)/(1/3 + 1/6) which works out to 2/3. Any solution that does not use this constraint is inherently incomplete.

If we vary the problem slightly by giving the host a preference for one goat door over the other, for example instead of If both remaining doors have goats behind them, he chooses one randomly we say If both remaining doors have goats behind them, he chooses the leftmost door instead of C and D both being 1/6, C=1/3 and D=0. With this change the simple solution still (correctly) says if we decide to switch before seeing which door the host opens we'll win 2/3 of the time, i.e. (A+B)/(A+B+C+D)=2/3. However, if the host opens door 3, switching wins with probability (1/3)/(1/3 + 0) which is 1/1 (not 2/3). So, although the simple solution is correctly telling us something, it's NOT telling us what the probability is of winning by switching if we know which door the host has opened. -- Rick Block (talk) 19:42, 7 February 2009 (UTC)

Your critique of the statement '100% of those times Monty reveals the other goat, leaving the car' does not show it invalid, untrue or not germain to the puzzle. You have not dis-proved my proof. I think you're hung up the doors being numbered, and that which door a goat or a car is behind makes any difference. And I know you think the goats matter, base on 'the random goat constraint'. Your arguments and frame of reference are consistant with that very first line of the solution that you agreed should be removed, "The overall probability of winning by switching is determined by the location of the car." That sentance passed two Feature Article reviews? Enough, already.

Glkanter (talk) 20:31, 7 February 2009 (UTC)

I indulged you. Can you now please indulge me? Which of the following statements do you disagree with:

1) "what is the player's chance of winning if deciding to switch before the host opens a door" is a different question than "what is the player's chance of winning if deciding to switch after the host opens a door".

2) For certain variants of this problem, the answers to these two questions can be different.

3) The question asked by the problem statement is the after question, not the before question.

4) Your solution addresses the before question, not the after question.

Thank you. -- Rick Block (talk) 22:44, 7 February 2009 (UTC)

I'll just address 3 & 4, my answer renders 1 & 2 moot.

Twice, my proof includes the words "100% of those times Monty reveals...(a) goat." I don't see how my proof can be of anything but the after-Monty-opens-a-door scenario.

Enough about before or after! A premise of the puzzle is that Monty will reveal a goat. There is no 'reveals car' scenario to consider! That would not be the Monty Hall Problem! So of my 8 line proof, 2 of those lines, for clarity purposes, repeat a premise. I'm surprised that this has come up again, we've already been around this block.

So, if that's all you got, let's declare this a valid proof and move forward. Especially eliminating that 'flawed solution' talk from the 'Solutions' section.

Glkanter (talk) 00:39, 8 February 2009 (UTC)

Here's where Rick questioned the 'Monty Reveals A Goat' premise a few months ago:

"Regarding the odds not changing, are you saying Monty does not consider opening the door chosen by the contestant? This, by itself, is not sufficient to ensure that Monty's actions don't change the initial 1/3 probability."

This goes on endlessly. People get tired of this monkey business and stop posting. But the problems haven't gone away! But you can be sure the next guy who brings this up will be in for one heck of a fight! I say, it's time for resolution escalation!

Glkanter (talk) 01:06, 8 February 2009 (UTC)

I think I've been more than patient with you. It's clear you're not thinking about (perhaps not even reading) what I'm saying, so it does seem pointless for me to continue trying to explain this to you. Is there anyone you would listen to? Martin perhaps? user:Glopk perhaps (I don't know his real name, but I think he's a math professor at a university)? user:Billjefferys (who is William H. Jefferys)? You might want to read Wikipedia:Dispute resolution. -- Rick Block (talk) 02:12, 8 February 2009 (UTC)

I'd like to weigh in here and say that I also don't understand what is different about when the player decides he or she is going to switch. In 2/3 of cases, a player who goes into the game intending to switch will win. In 2/3 of cases, a player who goes in with no plans, who decides to switch anyway, will win. Assuming the player does not communicate his internal plans to the outside world, whatever the player intends cannot possibly alter the probabilistic assessments of an external observer who doesn't know where the prize is. This seems to me like it is suggesting that the mind state of the player can somehow alter the probabilities of the outside world, which is clearly impossible. Am I misunderstanding? Maelin (Talk | Contribs) 02:28, 8 February 2009 (UTC)

Have you read the whole thread here? -- Rick Block (talk) 05:35, 8 February 2009 (UTC)

I have, but I'm still confused. Is the question "Is there a difference between between the cases in which [(the decision is made before) amd (the decision is made after)]" or is the question "Is there a difference between the probability of winning [(before) and (after)]"? In the latter case I can see there might be differences but in the former case I can't see how "at what stage the decision is made" can possibly influence the outcome. Maelin (Talk | Contribs) 10:50, 8 February 2009 (UTC)

What a cop out! Of course I read your responses. I just responded directly to points 1 through 4! So, answer the question. What is wrong with the 8 step proof? That's what I'll listen to! Come on, the charade is over. Everybody knows. It's OK to acknowledge it.

Glkanter (talk) 02:37, 8 February 2009 (UTC)

OK, I'll continue to ignore your outbursts and pretend you're responding civilly. I've told you what is wrong with your 8-step proof. It answers the wrong question. You say #1 and #2 are moot. Does this mean you agree with these statements? It sounds like you're agreeing with #3 as well. Which leaves only #4 that you apparently disagree with. So, one more indulgence.

5) Does your proof also apply to the variant I've mentioned several times where instead of If both remaining doors have goats behind them, he chooses one randomly we say If both remaining doors have goats behind them, he chooses the leftmost door?

The question remains the after question, i.e. (directly quoting from the article) Imagine that you chose Door 1 and the host opens Door 3, which has a goat. He then asks you "Do you want to switch to Door Number 2?" Is it to your advantage to change your choice? Everything your proof relies on that's in the original problem is also in this one, so I think it does apply and I'm expecting you to say it does as well. There's only one little problem. The correct answer here is 100%. Please explain this to me. -- Rick Block (talk) 05:35, 8 February 2009 (UTC)

Against my better judgement, I will respond to this variant. To clarify, anyone who knows of this new constraint on Monty has, in essence, just been told there is a car behind door #2. Is that correct? Well, then how is that a game of chance? This differs fundamentally from the random selection of a goat, because the random method does not impart new knowledge (we know all along that Monty will reveal a goat and don't care which door). It is new knowledge that triggers a changing of the probabilities. In your variant, sometimes new knowledge is provided. That's why it goes to 100%. And all this has NOTHING to do with you dis-proving my proof.

Did you really say this?

"Everything your proof relies on that's in the original problem is also in this one, so I think it does apply and I'm expecting you to say it does as well."

You actually posit that the addition of a constraint would not change a proof? Or are you saying that by adding a new constraint, you have disproved the proof of the puzzle without the constraint? Get a clue, Jack!

Enough, already. Can we focus on the real issues? Finally? Please?

Glkanter (talk) 14:43, 8 February 2009 (UTC)

I deny the existance of different 'before' and 'after' questions. There is only one. It goes, "After Monty has revealed a goat, do you increase your chances of winning by switching?"

That is the only problem I have addressed since joining the discussion.

That is the only problem I have provided a proof for.

That is the only problem which I have asked you to find a flaw in my proofs.

And it is the only problem I will discuss on the discussion page of the Monty Hall Problem.

You're last gasp at finding a flaw was that I'm solving the 'before' puzzle. I pointed out the error in that statement, that twice the proof says "Monty reveals a goat". Which is a premise, for crying out loud!

So, whether or not there are two puzzles, I am solving the 'right' one. What's your critisism now?

Glkanter (talk) 06:21, 8 February 2009 (UTC)

Is my question above not clear? Does your solution apply to the variant, or not? -- Rick Block (talk) 06:25, 8 February 2009 (UTC)

Your question is immaterial to the Monty Hall Problem we are solving. I have no idea or interest in it's clarity. It is obsfucation. You are avoiding the Monty Hall Problem question. I have presented a proof, then sought meaningful critique. I have explained how a proof is validated. Yet you repeatedly refuse to remain engaged in a constructive discussion of my proofs.

Because it only takes one proof. And I've presented it. And it's valid. And it proves that ALL that other stuff is nonsense.

Glkanter (talk) 06:43, 8 February 2009 (UTC)

I'm trying to clarify for you what the problem is with your solution. It is directly related to the Monty Hall problem, which in fact YOU are avoiding. Let's switch to the terminology mathematicians use for the before and after questions. What I've been calling the before question is the unconditional question, while the after question is the conditional question. In this case, the unconditional question asks about the probability of winning by switching for all players without distinguishing between them in any way. The unconditional question doesn't care if the player picks door 1, or which specific door the host opens in response. The aforementioned Morgan and Gillman papers say the Monty Hall problem is NOT an unconditional problem, but a conditional problem. They each even propose wording changes that turn the problem into an unconditional problem. To save you a trip to the library (or the couple of bucks to get the online copy) I'll even quote them here for you. I'll even add some more of my own:

Morgan's version: You will be offered the choice of three doors, and after you choose the host will open a different door, revealing a goat. What is the probability that you win if your strategy is to switch?

[Rick here - note the scope of this. We're not limiting the population to those who've picked door 1 and see the host open door 3, we're asking a general question about all players.]

Gillman's version: You need to announce before a door has been opened [italics in the original!] whether you plan to switch.

Rick's version #1: Same as original, but at the very end instead of asking "Is it to your advantage to change your choice?" we ask "What is the probability across all players that switching will win the car?"

Rick's version #2: Same as original, but before the host opens a door the player is instructed to close her eyes, put her hands over her ears, and shout "SWITCH SWITCH SWITCH ..." or "STAY STAY STAY ..." and continue doing so while the host opens a door, until the host taps her on the shoulder at which point she can stop shouting, open her eyes, and the outcome of her choice will be revealed.

However you want to phrase it (unconditional vs. conditional, before or after) all of these differ from the Monty Hall problem as stated in the article, and as usually stated pretty much anywhere, by asking about all players without differentiation. The wording in the version published in Parade ("You pick a door, say No 1 ..") and the wording in Krauss and Wang version ("Imagine that you chose Door 1 ...") make it a conditional problem asking about a player who has picked a door and can see which door Monty opens in response. We don't care about all players in general. We care only about the subset of players who (for example) have picked door 1 and then see Monty open door 3. Using the typical probability notation, we're not asking about

P(win by switching)

but rather

P(win by switching | player picks door 1 and host opens door 3)

These are the two questions I've been yammering about that are different. P(win by switching) is the unconditional probability of winning by switching. It answers the before question. It tells you roughly what fraction of all players who play the game will win by switching.

P(win by switching | player picks door 1 and host opens door 3) is the conditional probability of winning by switching given that you've initially picked door 1 and the host has opened door 3. It answers the after question. It tells you roughly what fraction of all players who pick door 1 and see the host open door 3 will win by switching.

These are different questions which may or may not have the same numeric answer.

The Monty Hall problem asks the conditional question, not the unconditional one (according to two different math papers published about it).

The simple solution correctly answers the unconditional question. It says bupkus about the conditional problem. For the Monty Hall problem as stated it says the answer is 2/3. For the variant I've proposed above which you refuse to consider it also says the answer is 2/3. The unconditional probability IS 2/3 for both of these.

Although it is correctly answering the unconditional question, the simple solution is NOT addressing the conditional question. If we take its answer as the answer for the conditional question it "works" for the Monty Hall problem as stated in the article, but this is in effect a coincidence. The problem with the approach is exposed by applying the same solution to a variant (like the one I've proposed above) where the unconditional and conditional solutions are different.

This is EXACTLY the same as someone answering the question "what is 2²?" by saying "2 plus 2 is 4, the answer is 4". It's the right answer, and a true statement, but the wrong reasoning. We can expose this wrong reasoning by asking, "what is 3³?" Similarly, we can expose the wrong reasoning of the simple solution to the MH problem by asking about a slightly different variant, where the wrong reasoning produces the wrong answer.

If anyone else is reading this thread and can make this any more clear, please feel free. -- Rick Block (talk) 15:59, 8 February 2009 (UTC)

So, specifically, which one of my 8 statements invalidates the proof? Because, I'm sure you know that if each individual statement is true and valid, and the conclusion comes from the statements, then it's a valid proof.

Because it only takes one proof. And I've presented it. And it's valid. And it proves that ALL that other stuff is nonsense.

Glkanter (talk) 16:14, 8 February 2009 (UTC)

Here's where I start to wonder if you're reading what I'm saying. I tell you the math sources say there are two different questions, the unconditional question and the conditional question, and explain what these mean, and explain how they're different, and explain that the simple solution correctly addresses the unconditional question, and tell you the math sources say the problem is actually asking about the conditional question - and your reply ignores all of this and simply repeats your claim that you're right.

You said above you "deny the existance [sic] of different 'before' and 'after' questions". Do you deny the existence of conditional probability (before answering you might want to go read the article) ? -- Rick Block (talk) 17:07, 8 February 2009 (UTC)

I read every word you post. Believe me. Look, here's how it works. Someone puts forth a proof. Then everyone else looks for where there may be errors. Then when everyone is satisfied that it's correct, it is accepted. Once it's accepted, there is no saying about it: "Although the reasoning above is correct it doesn't answer the precise question posed by the problem, which is whether a player should switch after being shown a particular open door (Morgan et al. 1991)."

Step 1. Somebody puts forth a proof. I've done that.

Step 2. Everybody else looks for where there may be errors. In the proof. Nowhere else.

All you have ever done is say that I am not solving the appropriate question. To that, I again say, Hogwash! Each of those 8 lines passes. And the conclusion: 'since 2/3 is greater than 1/3, switching wins more often', answers the question being asked.

Enough, already!

Because it only takes one proof. And I've presented it. And it's valid. And it proves that ALL that other stuff is nonsense.

Why don't we admit that neither of us is going to be persuaded by the other? I've recently requested that Martin take this to the next level of Conflict Resolution. I'm tired of the circular nature of the argument, but I think I'll stick around. Glkanter (talk) 18:35, 8 February 2009 (UTC)

How it works at Wikipedia is someone finds reliable sources and uses them to develop an article about some topic. We specifically don't include original research such as putting forth original proofs, so (in articles at least) we have no obligation to examine whether proofs are correct or not. If Leonhard Euler were to come back from the grave and say this article is hogwash, here's a simple, elegant proof you should use instead - the response would be that he needs to get it published in a reliable source before it can be used here (both the proof and the claim that what's here is hogwash). That is not even close to the case here. What's happening here is you, some anonymous Wikipedia editor, are suggesting we ignore what reliable sources have to say and replace content that's based on what they say with a proof that they say does not address the question. I don't care how brilliant you think you are, but that is not what's going to happen. Trust me on this. -- Rick Block (talk) 19:12, 8 February 2009 (UTC)

And leave me out of this. Martin Hogbin (talk) 20:28, 8 February 2009 (UTC)

As usual, you're answering the wrong question. I have little interest in developing material for inclusion in the Wikipedia Monty Hall Problem Article. I'm trying to demonstrate to you and all the other editors why all that other stuff is hogwash and should be deleted! And for that, a logical proof is exactly what's in order.

Is there a Wikipedia methodolgy for determining a good source from a bad source? Maybe Morgan and Gillman are crackpots? They sure seem to have a minority opinion relative to the mainstream, based on what I've read here.

Is there a Wikipedia standard for how much prominance is given to minority opinions? If any?

It's time to escalate. Don't you want to move beyond this?

Glkanter (talk) 19:39, 8 February 2009 (UTC)

I've asked the folks at WikiProject Mathematics to comment (next step in dispute resolution is to solicit more opinions). If anyone watching this page would comment here, that might help as well. There is a methodology for determining what is a reliable source, described at the link I provided above. Academic and peer reviewed publications are usually the most reliable sources (there's a hedge about being outdated or superseded, which does not mean that popular sources published later trump academic sources published earlier). I assure you Morgan and Gillman are not crackpots and their views reflect the still current views in mainstream probability theory.

Several years ago, there was an anonymous editor (editing without a login) who initially brought up the Morgan et al. paper. I argued against him, much like you're arguing against me, but I finally "got it". I've spent a lot of time explaining this to you, not because I like to argue, but in hopes that you'll actually "get it", too. I could have justifiably said "shut up, we say what the sources say" a long time ago and dismissed you as a troll. I didn't, and still haven't, because I don't think you're a troll. -- Rick Block (talk) 20:23, 8 February 2009 (UTC)

MCDD is Morgan and three other guys. <Oh! The three other guys are the 'et al'!>Glkanter (talk) 22:00, 8 February 2009 (UTC)

"In fairness, MCDD do moderate their tone later on, writing, "None of this diminishes the fact that vos Savant has shown excellent probabilistic judgment in arriving at the answer 2/3, where, to judge from the letters in her column, even member of our own profession failed.""

http://www.math.jmu.edu/~rosenhjd/ChapOne.pdf page 48

Who is John Gault?

Glkanter (talk) 21:00, 8 February 2009 (UTC)

Who is John Gault? Perhaps John Galt's cousin? -- Rick Block (talk) 23:05, 8 February 2009 (UTC)

I'll do one effort to explain the problem. The situation is already conditional on the choice of Door 1 by the player. And we know Door 3 has been opened revealing a goat. Let us assume the game has been played 3000 times. What might have happened?

Player has chosen Door 1
Car hidden behind Door 1		Car hidden behind Door 2	Car hidden behind Door 3
1000 times		1000 times	1000 times
If nothing else is revealed
Player wins the car if he doesn't switch		Player wins the car if he switches
But player gets "information"
Host opens Door 2	Host opens Door 3	Host must open Door 3	Host must open Door 2
500 times	500 times	1000 times	1000 times
This case didn't happen	One of these cases happened		This case didn't happen
	Player wins the car if he doesn't switch	Player wins the car if he switches

Hence only in half the cases did the situation arise in which the player finds himself. So we see it cannot be unconditional, because only a part of all possibilities could have happened. Clear?Nijdam (talk) 18:05, 6 February 2009 (UTC)

Rick, I thought that it had been agreed that, for the fully defined problem (host alway offers the switch and always opens a goat door), there is no distinction between the conditional and unconditional cases. Martin Hogbin (talk) 22:56, 6 February 2009 (UTC)

In cases of mathematics the right solution is not reached by agreement. I hope I explained clearly enough why the stated problem requires a conditional solution and why this solution differs from the unconditional one (not numerically in the final answer, but that's not the issue).Nijdam (talk) 23:56, 6 February 2009 (UTC)

Martin, no, I don't think there was ever any agreement that in the fully defined problem there is no distinction between the conditional and unconditional cases. The fully defined problem ensures the numerical probabilities are the same, but these remain distinct questions requiring different solutions.

Nijdam - I have said repeatedly I'm OK with starting with an unconditional solution so long as it is clearly identified as an unconditional solution, doesn't actually say anything that's incorrect, and is immediately followed up with a transition to the more accurate conditional solution. My rationale for including an unconditional solution is because many published sources (possibly all popular expositions of this problem) include only an unconditional solution. I think not providing one here would be a significant omission. How to structure the article is an editorial decision, which is reached by consensus. We want the article to be accessible to laypersons, but also correct, which I think sometimes calls for compromises. -- Rick Block (talk) 05:03, 7 February 2009 (UTC)

Well, to be honest, I'm not. I strongly oppose starting with a reasoning that is not a solution to the stated problem. The right solution, as I suggested above, is quite accessible to the layman. If anything has to be said about the "simple solution", it should be as a solution to a (slgihtly, but essentially) different problem. It doesn't seem right to me, to have thoughts like "keep the laymen in the dark, it is no use to explain things properly to them".[Sorry, forgot to login] Nijdam (talk) 12:59, 7 February 2009 (UTC)

Nick, in what way are the conditional and unconditional cases distinct in the case of the fully defined problem? Martin Hogbin (talk) 14:44, 7 February 2009 (UTC)

Martin - see my most recent reply to Glkanter, two sections above. -- Rick Block (talk) 20:20, 7 February 2009 (UTC)

Your reply seems to me to be arguing that we can show the two cases are different by changing things so that they are different. Martin Hogbin (talk) 00:43, 8 February 2009 (UTC)

Martin - 2+2=4 and 2² = 4. Does that mean "what is 2+2" is the same question as "what is 2²"? I'm saying we have two questions about the MH problem whose answer is both 2/3. We can show they are indeed different questions by asking them about a different problem where they have different answers. -- Rick Block (talk) 05:44, 8 February 2009 (UTC)

Here's something to think about:
The presentator has a simple strategie: when possible he opens Door 3, otherwise he tries Door 2 and is that also impossible he opens Door 1. Quite easy. See what happens:

Chosen 1, opened 2: Switching wins the car

Chosen 1, opened 3: Switching wins the car with probability 1/2

Chosen 2, opened 1: Switching wins the car

Chosen 2, opened 3: Switching wins the car with probability 1/2

Chosen 3, opened 1: Switching wins the car

Chosen 3, opened 2: Switching wins the car with probability 1/2

Yet the initial prob. of winning the car is in all cases 1/3 and according to the "simple reasoning" switching would increase it to 2/3. Notice BTW that the overall prob. of winning the car when switching is (of course) 2/3. And also conditional given the chosen door. But (!) not conditional given the chosen and the opened door. Don't let it keep you out of your sleep.Nijdam (talk) 22:56, 7 February 2009 (UTC)

Firstly, I should have added one more thing to my 'fully defined problem', which is that the host chooses a goat door randomly when he has a choice.

Between the start of the show and the player choosing a door, many things happen; the host opens a door, the host talks to the player, the audience may applaud or someone in it may cough, there may be a break for advertisements. The outcomes of all these events represent conditions based upon which the players choice is made. We choose to ignore most of those conditions for one reason, we take it that they do not reveal any new information about the location of the car and thus cannot possible affect the outcome of the show. That is the criterion upon which we decide what conditions we must take into account in answering the problem.

Let me now ask this question: if the problem were stated an a form that explicitly stated that nothing occurred between the start of the show and the player making his choice that reveals any information about the position of the car, are the conditional and unconditional statements of the problem then distinct? Martin Hogbin (talk) 10:05, 8 February 2009 (UTC)

Interesting that you put is this way. Because what is the meaning of "no information is revealed"? This actually means that the possible outcomes are not restricted. And here they are: allthough the conditional probability is the same as the unconditional, the information revealed is for instance that the car is not behind Door 3. Nijdam (talk) 11:12, 8 February 2009 (UTC)

Perhaps I should have said, 'no information is revealed that would affect the probability of winning by switching'. In that case would you accept that there is no distinction between the conditional and unconditional cases. Martin Hogbin (talk) 18:42, 8 February 2009 (UTC)

Alas(?!), no. You really miss the point. The information revealed - with the proper strategie of the host - does indeed not affect the probability of winning by switching. But the meaning of such a statement is that the conditional probability given this information, is the same (numerically) as the unconditional one. And as I said before: the revealed information restricts the possible outcomes. I get the feeling that all efforts are made, against better judging maybe, to avoid rejecting the "simple solution". I sincerely hope this is not the case. Nijdam (talk) 22:58, 8 February 2009 (UTC)

You argument would apply to everything that happens between the players original choice of door and his decision as to whether to switch or not. As I said above, why do we not consider the conditional probability given that the host has spoken to the player. What I mean by this is why is the host opening a door a condition any more that the host speaking to the player? Martin Hogbin (talk) 23:30, 8 February 2009 (UTC)

Well, some things happen and do not limit the possible outcomes. Like the started rain outside or the joke the host tells in between. But, as I over and over argued, the open door does. I gave a "simulated" example further down, in reply to Gkanter. Have a look there and be convinced. I really can't think of anything more that should be said. Maybe the real issue is some discussiants are not familiar with probabilities, let alone conditional probabilities. Nijdam (talk) 00:00, 9 February 2009 (UTC)

That was exactly my point. What we include as a condition in any probability questions depends on what what believe can possibly affect the outcome. If the statement of the problem were to explicitly state that 'no information is revealed that would affect the probability of winning by switching' by a particular event then that event would not represent a condition, and the conditional and unconditional cases would be indistinguishable. 86.133.179.19 (talk) 09:28, 9 February 2009 (UTC)

I agree with Glkanter: "Everybody else looks for where there may be errors. In the proof. Nowhere else." He may not be responding to the conditional problem, as presented by Rick Block, but should he? People try to explain the conditional situation, but why do they fail to explain to him why the particular problem cannot be unconditional? Where are the errors in the simple solution, as an answer to the given question? I found some probable 'answers' to that:

- Morgan et al. : "F5 is incorrect because it does not use the information in the number of the door shown."

- Glkanter: "I think you're hung up the doors being numbered, and that which door a goat or a car is behind makes any difference."

- Nijdam: "alternative question <..> : the player is blind and Monty only tells him: I opened one of the other doors and there is a goat behind it."

- Hogbin: "Between the start of the show and the player choosing a door, many things happen <..> we take it that they do not <..> affect the outcome"

- Nijdam: "what is the meaning of "no information is revealed"? This actually means that the possible outcomes are not restricted."

The question is: should the requested chance be regarded as a conditional probability, and if so, why? Morgan et al. say it should, but their only argument or hint is that the information in the number of the door is otherwise not used. What information is in the number? Does it matter if the (blind) player has knowledge of that? What other information might be relevant? Should it be limited to events which restrict the possible outcomes? Even if it doesn't affect the outcome?

The article Conditional probability states that P(B|A) = P(B) if A and B are statistically independent. In other words: conditional and unconditional chances are the same if A does not change the probability of B. And it doesn't. Heptalogos (talk) 15:34, 10 February 2009 (UTC)

I've been re-reading some past postings. According to Rick, this article has been reviewed on 2 occasions as a 'Featured Article', and that much of what I find inessential actually was a (by)-product of those reviews. Rick is proud of 'shepherding' this article through at least one of those reviews.

So, in some ways, I seem to be arguing against Conventional Wisdom. But I don't feel that way. I have a few college courses on this topic, over 30 years ago, and a lifetime of being a data analyst. My viewpoint is, 'There is no possible way I am wrong about this'. To me, this whole discussion has as much to contribute as a discussion of whether the sun will rise in the east tomorrow morning.

How does a single voice effectively confront the Conventional Wisdom? This is a question not just for Wikipedia, but any societal system. In the US, a swindler set up a Ponzi scheme on Wall Street. Individual investors went to the regulatory agency numerous times, but to no avail. The guy didn't actually get caught. He turned himself in! How does a minority, but important, voice get heard?

Yes, I look at this entire article, excepting maybe 5% of it, as an elaborate hoax. I think everyone went along because they did not want to admit to limited knowledge of the subject matter. Everybody drank the kool-aid. And the emperor is wearing no clothes.

2/3 of the time I will select a goat. Therefore I should switch. Glkanter (talk) 15:32, 7 February 2009 (UTC)

You are not alone Glkanter, I agree that the page could do with improvement. My main complaint is not that the current solutions do not properly and fully address the subject; this is done well and with references to reliable sources, thus it ticks all the boxes to be a featured article. My complaint is that it lacks a section that will quickly convince the average reader of the right solution. This is unfortunately not something that appears in the FA criteria. However, the really notable point about this problem is that even when all the facts are presented in a clear and unambiguous way (and I believe if if the problem were stated in a fully unconditional form) the average punter gets it wrong. It is common in many walks of life today to find situations where you can tick all the boxes but still not do the job well. The question that should be asked of all WP articles, but generally is not asked, is, 'Does this article address the needs of the expected readership?'.

In this respect I believe that the conditional/unconditional issue is an unnecessary, and to a large degree unwarranted, complication that only serves to obfuscate the central and notable problem.

I have not pressed for the inclusion of 'my' solution because I am not totally happy with it as a convincer. I have bored many of my friends and family with the problem to try to find out what arguments are the most convincing. The solution I gave does work quite well but stumbles over the fact that the decision is not made at the start but after the host has opened a door (arghh! the very issue I claim is not important). I still stand by what I say, however, but am looking for a way to treat this issue in a different way. Martin Hogbin (talk) 11:41, 8 February 2009 (UTC)

There is a difference between a proof being valid, and being 'intuitive'. If the solution were 'intuitive', the puzzle would not be well known. I've done the same thing with friends, and generally, they're just not in the mood for this. The important point of the proof being valid, however, is that it renders all that other stuff as hogwash. Including the 2nd paragraph of the Solution section which says the just-offered solution is no solution at all! What does FA criteria say about that?

No. There's no compromise on this. It's math. Not Economics. It's time to end this horrible charade. And I am MUCH more interested in the immediate deletion of all non-value-added (wrong) (BS) stuff from the article than the elevation in prominance of any one of the elegant, valid proofs we've put forward.

Glkanter (talk) 14:07, 8 February 2009 (UTC)

And really, who wants to argue when at the top of the page it says:

Please note: The conclusions of this article have been confirmed by experiment

There is no need to argue the factual accuracy of the conclusions in this article. The fact that switching improves your probability of winning is mathematically sound and has been confirmed numerous times by experiment.

Two mentions of proof via experimentation. I'll bet not a single reference source uses 'experimentation' as their solution. Because 'experimentation' is not a statistical or logical proof. An error like this confirms my above stated concerns. I'm curious, is it common for Wikipedia discussions to have such a banner? I've never seen anything like it in any 'academic' setting before. Anywhere. Glkanter (talk) 15:54, 7 February 2009 (UTC)

And this, it's the 2nd paragraph after the 1st chart in the Solutions section. It's one of the more prominent items in the Solutions section.

"Although the reasoning above is correct it doesn't answer the precise question posed by the problem, which is whether a player should switch after being shown a particular open door (Morgan et al. 1991)."

What sort of a 'Solution' section leads off with a proof it is going to immediately (and fraudulently) discredit? And then goes on endlessly doing so? For who's benefit? The once-interested reader is by now, long gone. Glkanter (talk) 17:06, 7 February 2009 (UTC)

Here's my only edit to the actual Article. On October 23, 2008 I deleted the following erroneous line:

"The overall probability of winning by switching is determined by the location of the car."

The above statement was the very first words of the Solutions section.

Imagine. Being THAT wrong on the very first line.

Glkanter (talk) 17:57, 7 February 2009 (UTC)

So, I posted the following two days ago, at 13:34, 6 February 2009:

There are really only two situations to consider. Not 3, not 6.

2/3 of the time I will choose a goat.

100% of those times Monty reveals the other goat, leaving the car.

=>2/3 of the time I should switch.

1/3 of the time, I will choose the car.

100% of those times Monty reveals one of the goats. It doesn't matter which.

=>1/3 of the time I should not switch.

2/3 is greater than 1/3.

Therefore, by switching, I increase my chances of getting the car when offered the switch.

Eight lines. Including a premise repeated twice for clarity. Since then, there have been countless postings by Rick. Running off on tangents to and fro. But we NEVER focus on the 8 statements. It's always some BS about 'before or after', or whatever the mcguffin of the day is.

It's a valid proof, and could be shorter. Mr. Block! Tear down your wall!

Glkanter (talk) 07:46, 8 February 2009 (UTC)

This is why I say it's time to end this charade, now.

In October, 2008, Martin posted this to Rick:

"If you remember, I first came to this article in response to an RFC which claimed that the current editors were being overly protective."

So, it's not just me. It's been enough people, for a long enough time, that the offical Wikipedia RFC process was put in motion. Good. It's time for the next step in the process. BTW, who do suppose could be the 'overly protective current editors' referred to?

Glkanter (talk) 15:34, 8 February 2009 (UTC)

Do I sound frustrated? Well, I am. Here's another one from October. Sound familiar?

Maybe we should take this one step at a time. Do you agree there may be a difference between the probability of winning by switching before the host opens a door and after the host opens a door? Or, at least, that these are different questions? -- Rick Block (talk) 02:09, 27 October 2008 (UTC)

I've read this entire discussion page from top to bottom. Other people have come before me, and pointed out essentially the same things I'm saying. No, thank you, I do NOT want to debate some other puzzle questions with you. It's a simple puzzle. In fact, the puzzle is almost like a Seinfeld episode. Nothing happens! The probabilities DON'T CHANGE! You seem to not understand Probability Theory. Otherwise, you would have acknowledged the validity of the proofs, and therefore the uselessness of those other issues as they relate to the Monty Hall Problem. Despite your valiant efforts at requiring 'a rigorous solution', you allowed a COMPLETELY ERRONEOUS STATEMENT to lead the solutions discussion. And have resisted multiple efforts to improve that section! That erroneous statement is at odds with everything that Probability Theory stands for. At times, you've argued with me over the premises of the Monty Hall Problem. Monty opening the CONTESTANT'S door? Give me a break. Glkanter (talk) 02:28, 27 October 2008 (UTC)

What was that completely erroneous statement? Just this:

"The overall probability of winning by switching is determined by the location of the car."

So, yes, I'm personally invested. I'm interested. I just read that there are 'archive' pages for this discussion. So what we see here, is just the most recent discussions of this lunacy. The tip of the iceberg, so to speak.

So, enough of the charade!

Because it only takes one proof. And I've presented it. And it's valid. And it proves that ALL that other stuff is nonsense. —Preceding unsigned comment added by Glkanter (talk • contribs) 15:54, 8 February 2009 (UTC)

You know what? It's been long enough. Martin, I understand that at some time last year you were specifically requested to get involved, in order to facilitate the resolution of some conflict(s) relating to the Monty Hall Problem.

I ask Rick to invalidate my proof, he tells me I'm not addressing the Monty Hall Problem.

It is obvious these discussions have gotten nowhere, and are going nowhere. So I request that you declare this situation as 'at an impasse', and escalate this to the next level of Conflict Resolution.

Thank you.

Glkanter (talk) 17:05, 8 February 2009 (UTC)

Since October 25, 2008 I have posted on this discussion page 70 times. 66 as Glkanter, and 4 previous times as an ip address. In addition, there was a separate discussions page that was set up, and I posted there many times as well.

70+ postings over a 2 line proof! When I pick a goat, Monty leaves a car. I pick a goat 2/3 of the time.

I feel that this has gone on long enough! I honestly wonder if there isn't a bot out there generating responses from a limited selection of inaccurate/meaningless/non-relavent statements.

This has been going on with countless other editors since at least 2005. Check out the archives sometime.

To the powers-that-be at Wikipedia, I implore you, please bring this to a conclusion!

Glkanter (talk) 15:43, 10 February 2009 (UTC)

I just went to the page where Rick requested assistance. One of the people there, who described himself as 'an expert in probability' had this to say:

One probabilistic point that I observe is, (ir)relevance of the (un)conditional probability. I'd say that in this case they are equal not just by a numeric coincidence. Rather, the conditional probability (treated as another random variable) is constant (a degenerate random variable) in this case, due to an obvious symmetry. Taking into account the total probability formula we conclude that the conditional probability must be equal to the unconditional probability in this case. Thus I feel indifferent. Both are relevant in one sense or another. Do you agree? Boris Tsirelson (talk) 21:42, 10 February 2009 (UTC)

http://en.wikipedia.org/wiki/Wikipedia_talk:WikiProject_Mathematics

Does this mean what I hope it means?

Glkanter (talk) 22:37, 10 February 2009 (UTC) moved comments 76.243.187.238 (talk) 01:29, 11 February 2009 (UTC) doh! Glkanter (talk) 01:50, 11 February 2009 (UTC)

After just 4 months, I've run out of new things to say. So rather than clog up other people's exchanges, I'll just add commentary here. I don't see the point in further arguing, but I'm not giving up the quest.

I see the 'random goat constraint' has reared it's (their) ugly head again. In my proof, which I maintain is sufficient for this puzzle, the goats are immaterial. The puzzle asks about increasing the liklihood of selecting the car, not the location of a goat.

Does the probability change if instead of goats there is nothing? So would we have a 'random nothing consraint'?

My understanding of Probability Theory says if an item isn't specifically addressed, it's considered random. And anything that's random is not a constraint. And if it's not a constraint, it doesn't need to be addressed.

For those keeping score, I was indeed reported to the authorities. I, and others with my criticisms were described as a 'cadre', 'wanting to "dumb down" ' the solution by Rick.

Glkanter (talk) 14:36, 11 February 2009 (UTC)

And, the doors and their numbers are meaningless. The doors only exist to shield the contestant's view of the car and the two goats.

Let's focus on why this is such a famous puzzle. Because it's easily understood (2/3), and easily misunderstood (50/50). So, no reader really understands the solution until he has mastered the 'random goat constraint'? Pure folly.

Nobody cares about the specific case of doors 1 and 3, any more than they would care about suitcases 11 and 25 in Deal or No Deal. That's not what Probability Theory is about. Here, I disagree, until my last breath, with Rick. Probability, and this puzzle are always solving the 'over time' question. If repeated endlessly over time, on aggregate, what would the results be?

Glkanter (talk) 14:54, 11 February 2009 (UTC)

I was struggling for the right word earlier, but it came to me. Despite what Rick is posting elsewhere about 'physical doors' and such, all Probability can do is create a mathematical model that approximates real life. That's what a proof sets out to do. And if valid, it serves as a proxy for 'real life'. From which we can analyze and draw conclusions.

I, of course belief I have presented various proofs that meet this criteria. Rendering all that other stuff, at best, redundant and confusing, and at worst, erroneous.

Glkanter (talk) 16:19, 11 February 2009 (UTC)

Glkanter, I agree to many things you say. But you should keep one thing in mind: we need an objective way to prove ideas, even if everyone seems to agree to the logic presented by e.g. you or me. So, maybe maths fails to prove what is true in this case, but maybe (our) logic fails to understand the real causes of reality in this case. Do we have other objective systems but maths to prove our logic? Are those limited to science? I think we should each try to step outside our custom systems to see if we can meet on another level. Heptalogos (talk) 21:49, 11 February 2009 (UTC)

The Monty Hall Problem gained much (most) of its current noteriety when it was written about by Marilyn Vos Savant in Parade Magazine. I read about it there. We all know the story about how a thousand PHDs challanged her, etc., etc.

But ultimately, Vos Savant was acknowledged as having the right answer at 2/3.

Let's hear from the great lady, herself, courtesy of Wikipedia'a Marilyn Vos Savant page:

Under the most common interpretation of the problem where the host opens a losing door and offers a switch, vos Savant's answer is correct because her interpretation assumes the host will always avoid the door with the prize. However, having the host opening a door at random, or offering a switch only if the initial choice is correct, is a completely different problem, and is not the question for which she provided a solution. Marilyn addressed these issues by writing the following in Parade Magazine, "...the original answer defines certain conditions, the most significant of which is that the host always opens a losing door on purpose. Anything else is a different question." [16] In Vos Savant's second followup, she went further into an explanation of her assumptions and reasoning...

http://en.wikipedia.org/wiki/Marilyn_vos_Savant

Or this, from the Newspaper of Record:

"The problem is not well-formed," Mr. Gardner said, "unless it makes clear that the host must always open an empty door and offer the switch. Otherwise, if the host is malevolent, he may open another door only when it's to his advantage to let the player switch, and the probability of being right by switching could be as low as zero." Mr. Gardner said the ambiguity could be eliminated if the host promised ahead of time to open another door and then offer a switch.

Ms. vos Savant acknowledged that the ambiguity did exist in her original statement. She said it was a minor assumption that should have been made obvious by her subsequent analyses, and that did not excuse her professorial critics. "I wouldn't have minded if they had raised that objection," she said Friday, "because it would mean they really understood the problem. But they never got beyond their first mistaken impression. That's what dismayed me."

Still, because of the ambiguity in the wording, it is impossible to solve the problem as stated through mathematical reasoning. "The strict argument," Dr. Diaconis said, "would be that the question cannot be answered without knowing the motivation of the host."

Which means, of course, that the only person who can answer this version of the Monty Hall Problem is Monty Hall himself. Here is what should be the last word on the subject:

"If the host is required to open a door all the time and offer you a switch, then you should take the switch," he said. "But if he has the choice whether to allow a switch or not, beware. Caveat emptor. It all depends on his mood."

http://query.nytimes.com/gst/fullpage.html?res=9D0CEFDD1E3FF932A15754C0A967958260&sec=&spon=&pagewanted=3

So, even as we argue semantics on this page, it's unambiguous what problem she was solving. With all that hub bub, what proof did Marilyn and all these people use to come to the conclusion that 2/3 is right? Well, it wasn't Morgan et al, via the 'random goat constraint'.

So, if the unconditional probability proof was good enough for Marilyn, Monty, 1,000 PHDs, and 10s of millions of Parade magazine's general interest readership, why is it not good enough for the Wikipedia readers of today?

Glkanter (talk) 08:01, 12 February 2009 (UTC)

It's surely good enough for everyone with less logic. Every era has it's own conventional wisdom. At the same time science is always requesting systematical proof, which is one of the reasons that conventional wisdom improves. Of course we need both, that's what I'm saying. I also believe that scientists statistically have better wisdom than random crowds (who speak through individuals), which indeed doesn't mean that science 'truth' is always superior to any common truth. So the unconditional approach is very welcome, but it shouldn't be presented as the only correct answer. Thanks for the links, I am getting curious about the exact logic of Marilyn. Heptalogos (talk) 09:53, 12 February 2009 (UTC)

Please note, I'm not saying that something like the 'Combined Doors' solution is the only correct answer. I'm saying that two paragraphs later, the Solution section should not say that the explanation just offered is incorrect. And then spend 90% of the article expanding on that. Which is exactly how the current article reads.

I suppose there's 'Wikipedia Merit' to the Morgan arguement, after all it's been published. But to hijack the entire article from the commonly understood solution? As I've recently learned, that is not the 'Wikipedia Way'.

Glkanter (talk) 16:42, 12 February 2009 (UTC)

I've just learned that Rick's comment that being 'Right' is trumped by being 'Verifiable' for Wikipedia purposes has some merit. I further understand that being in the mainstream (my term) trumps being in the minority (my term).

We're still arguing over who's 'right'. But apparently, that's not even the salient point.

Would anyone describe the 'random goat constraint' as being in the mainstream of the published literature? How about after reading this?

MCDD is Morgan et al.

"In fairness, MCDD do moderate their tone later on, writing, "None of this diminishes the fact that vos Savant has shown excellent probabilistic judgment in arriving at the answer 2/3, where, to judge from the letters in her column, even member of our own profession failed.""

http://www.math.jmu.edu/~rosenhjd/ChapOne.pdf page 48

Glkanter (talk) 13:35, 12 February 2009 (UTC)

Oh, look! Rick agrees with me that the unconditional solution represents the mainstream.

"The "vos Savant" version is far and away the best known, but it's not only conditional (sic) but under-specified."

So, now that we agree what the mainstream is, let's agree that it is under-represented and mis-represented in the article, and that the article emphasizes the minority of the published works.

Who's going to take the first stab at proposing changes to the article? I've already proposed some ideas under the heading "Request for brief clarifications".

Glkanter (talk) 16:42, 12 February 2009 (UTC)

I've posted here nearly 80 times trying to prove my proof is valid, and that I'm 'right'. Turns out, that was never the argument I needed to win.

So why, since 2005 at least, hasn't the response been that the more meaningful (for Wikipedia purposes, anyway) arguement is, to paraphrase, 'popularity of the published material'? Not until about two days ago, anyways.

So, thanks for wasting 4 months of my time. And 4 years of various other people's time.

Now, can we start fixing the Article?

Glkanter (talk) 14:48, 12 February 2009 (UTC)

Pretty interesting exchange relating to my 'being reported' by Rick at the bottom of Rick's talk page. First, he gets spanked for crying wolf, then he writes this:

There's a current crowd (Glkanter is one of them) unhappy with the Morgan et al. approach who want it removed, commenting on the talk page to gain consensus for their desired change. I guess rather than convince them I could just let them know they will never gain consensus for this change. -- Rick Block (talk) 12:23, 11 February 2009 (UTC)

Maybe next I'll be reported for trying "to gain consensus for their desired change". Does trying to build consensus make me a bad Wikipedian?

Glkanter (talk) 17:35, 12 February 2009 (UTC)

Would you consider the following statement as an indication that an editor has claimed 'ownership' of an article?

"I guess rather than convince them I could just let them know they will never gain consensus for this change. -- Rick Block (talk) 12:23, 11 February 2009 (UTC)"

Could this be an 'Aid To Understanding' for why there have been 4 years, 7 archives, and thousands of postings calling for significant changes to the Monty Hall Problem article, all to no avail?

Let me ask the 'cadre', is there 'consensus' that this editor should be reported for violating the Wikipedia Ownership policy as it relates to the Monty Hall Problem article? If forced, I guess I could be the one to make the report.

Glkanter (talk) 18:06, 12 February 2009 (UTC)

Does anybody know what form any sanctions would take? I hope it would include being blocked from editting both the MHP Article and this talk page. Glkanter (talk) 18:45, 12 February 2009 (UTC)

Here's where Rick first asked for assistance to aid in Resolving our Conflict.

http://en.wikipedia.org/wiki/Wikipedia_talk:WikiProject_Mathematics

All these other Wikipedia Math gurus already knew about Rick's MHP article Ownership issues!

I'm a first-timer here. It's been way too long, but is has been instructive as to how horribly mishapen things get when an editor claims ownership of an article.

Glkanter (talk) 19:25, 12 February 2009 (UTC)

If you're still reading these edits, you night appreciate my very first posting. I created a new section that day, but I still don't know how to link to it. "Monty's Action Does Not Cause The Original Odds To Change."

We were all so civil then! I was all ready to make my first edits to the Article! Glkanter (talk) 19:47, 12 February 2009 (UTC)

You guys should read the Featured Article Reviews. There's a link to each of them at the top of this page. In addition to some of the inane discussions we take part in here, the FA reviewers also argue about footnotes.

And there is one recognizbale name constantly making edits. That would be Rick. More documentation as to his 'Ownership' of the article.

Now, after his encouragement to suggest edits, he says this:

"Although not a veto, for consensus purposes unless you can address reasons raised to keep the content it would not be proper to make the deletion you suggest, regardless of how many editors agree with you (please see WP:NOTDEMOCRACY). -- Rick Block (talk) 03:15, 13 February 2009 (UTC)".

Looks like an 'Ownership' issue to me.

Basically, Rick is saying that the Article is already perfect. Therefore, any changes will make it un-perfect. And he knows, because he's written most of it, nominated it for FA, 'sheperded' it through FA, and personally responded to every FA critism himself. Through his 4 years of Ownership-fueled protectionism, he also has granted the existing Article 'tenure'. I wonder if there is such a policy as WPTENURE? Glkanter (talk) 04:02, 13 February 2009 (UTC)

I wrote the above about 'tenure' because this had been posted as part of a larger paragraph:

"...Given this content and these references are fairly long standing in this article and were added in response to a featured article review it would not be proper to remove them unless there is a strong consensus here..."

Rick Block (talk) 03:15, 13 February 2009 (UTC)

Then, after my 'tenure' comment and some other comments by me, this is posted, verbatim:

"I fell for it. I let him use the old 'rope-a-dope' on me. Next thing you know, instead of argueing about my proof, we'll be argueing about 'who is more mainstream', or 'what is prominant'. We are not arguing about your proof. Your proof is WP:OR and of no relevance, no matter how correct it may be. Please realise that. Leaving out the hyperbole would be helpful. To comment on the principles: no, this is not a democracy, yes all have the same potential to contribute, no Rick doesn't have a veto, no Rick did not say that he had a veto, no the argument that the content has been in place for ages is not a compelling reason to keep it William M. Connolley (talk) 08:31, 13 February 2009 (UTC)"

William has thoughtfully taken an interest in this page following Rick's request for intervention in his dispute with me. That makes him at least the second current editor brought to this page due to an intervention request involving Rick, although I do not believe the first was at Rick's request.

Yep, William gives it to me pretty good. But don't let his last sentence slip by unseen:

"no the argument that the content has been in place for ages is not a compelling reason to keep it".

So, the next time you suggest a change, and are countered with "Given this content and these references are fairly long standing in this article and were added in response to a featured article review ..." you may properly disregard such criticism. Glkanter (talk) 12:18, 14 February 2009 (UTC)

I'll probably have to document my claim. Here's another good one from Rick:

"I generally treat the talk page of the Monty Hall problem as a sort of "virtual office hours". My intent is to respond to any and all posts in a friendly and welcoming manner, in much the same way as you presumably respond to students who drop by during your office hours."

http://en.wikipedia.org/wiki/User_talk:Tsirel

Thanks, dude. You're too generous. No, really. Glkanter (talk) 08:01, 13 February 2009 (UTC)

I'm working on a new Wikipedia policy, I call it WP:DUDE-YOU'RE-NOT-SOCRATES . Glkanter (talk) 12:21, 14 February 2009 (UTC)

"This page is 495 kilobytes long. It may be helpful to move older discussion into an archive subpage." Plus 7 archive pages dating as far back as 2005.

"That's not writing, that's typing." Truman Capote

With my edits to this talk page, I have been accused of violating WP:CIVILITY, and worse. I'm comfortable with everything I've written. As I wrote at the start of this section, it's difficult for a minority voice to be recognized as credible, when it defies the Conventional Wisdom. So, I am trying to accomplish what seems, so far, to be a difficult task. The only tool I have is my ability to post on various Wikipedia pages. Talk about a probability problem! How do I know who to turn to?

So, I post here. I can't post in that pseudo-collegial, 'oh, beg to differ, chum', style that seems so popular. And I can't out-reference or out-WP:Policy Rick. He's got like 10,000 article edits to his name. No, all a punter like me can do is write with common sense and clarity, and try to draw some attention. So I have my own 'style'. Now you know why. Glkanter (talk) 14:49, 14 February 2009 (UTC)

No, it's not 'like 10,000'. His first edit (must be all edits, not just articles), was on February 20, 2004. His 10,000th was on March 21, 2005. Let's extrapolate: 10,000/ 13 months * 60 months = 46,153.8. I'm at about 100+. Little-known fact: it only SEEMS like all 46,153.8 are on this talk page. Glkanter (talk) 15:18, 14 February 2009 (UTC)

Let me ask it this way, in the 1/3 of the time when I select the car, how is Monty's motivation or actual actions going to change the fact that the car was my choice? And that by switching, I would give up the car? How is the 'equal goat door constraint' the solution to that question? It isn't. For probability proof purposes, like the most simple 2 or 3 line proof, we never even need to go there. I reject anew Morgan et al. Glkanter (talk) 16:13, 14 February 2009 (UTC)

Here's my new proof.

1/3 of the time I will pick a car.

Since 1 - 1/3 = 2/3, 2/3 of the time I will pick a goat.

I increase my likelihood of winning by switching.

Look at that. No Monty. No Monty's behaviour. Thank you, thank you very much.

Glkanter (talk) 16:21, 14 February 2009 (UTC) Glkanter (talk) 16:37, 14 February 2009 (UTC)

I think this is even better.

1/3 of the time I will pick a car.

Since 1 - 1/3 = 2/3, 2/3 of the time I will not pick a car.

I increase my likelihood of winning by switching.

No Monty, and now no goats. Glkanter (talk) 16:53, 14 February 2009 (UTC)

This is the simple solution in it's simplest form. Nothing new. Vos Savant did the same. Some people raised objections because they assumed that the problem is a conditional one. They forgot to explain why. They only said something about a numbered door being opened, maybe assuming that this number was already there before it was opened. This would reveal new information. But even then it would surely not affect the 1/3 chance of the picked door, so you are still right. But some people here insist that if part of the problem is conditional, the whole problem is. I am still waiting for the mathematical rule by which a problem is defined as conditional. I think I found it at Conditional probability where is stated that there should be statistical dependency, which means that the asked probability is affected, which is surely not the case here. But I don't get any answers to that. They just stopped explaning there. Heptalogos (talk) 14:00, 15 February 2009 (UTC)

I don't know...without Monty or the goats even mentioned, I don't see where they come into play. What did you think of Boris' comments?

Here's a different approach: My new solution is valid because the entire discussion about Monty and the goats is a carnival distraction. And doesn't affect the probabilities. It always end up a contestant, two doors, one car, and the cars haven't been moved since the original selection. It's still a 1/3 likelihood that you picked the car, so... Glkanter (talk) 14:21, 15 February 2009 (UTC)

Sorry, I just corrected 'unconditional' in my text above into 'conditional'. About your solution: it's not new and I think there's no use in repeating it all the time. What we need is solid proof/explanation that this problem is exclusively conditional. Without it, I think the article has to be changed. Let's give them some more time. You can call me optimistic, but I think something's moving. ;: Heptalogos (talk) 16:12, 15 February 2009 (UTC)

Those of you who reject the existance of Original Research are excused, and free to resume cataloging references to Bigfoot, Unicorns, etc. Glkanter (talk) 17:17, 14 February 2009 (UTC)

I just realized that any answer other than 'never switch' inproves your liklihood of winning. The worst you can do is not switch, and go 1/3. Do anything else, I'm just thinking 'go random', and yours odds increase, in this case to 50%. Glkanter (talk) 23:13, 14 February 2009 (UTC)

I came here from a request on WT:WPM. But the conversation is too long to read. Could each person post a 1-paragraph summary of what she or he thinks are the main issues under discussion? thanks, — Carl (CBM · talk) 20:30, 8 February 2009 (UTC)

In the thread above (#Glkanter's objection), user:Glkanter insists an unconditional solution is sufficient for the Monty Hall problem. I claim the specific wording used both here and in nearly all sources makes it technically a conditional problem asking about

P(win by switching | player picks door 1 and host opens door 3)

rather than

P(win by switching)

My stance is that the specific wording used in the article here ensures the numeric value is the same (2/3), but presenting an unconditional solution to a conditional problem (even one that happens to produce the correct numeric answer) is not sufficient. More specifically, the last two paragraphs at Monty Hall problem#Solution are mathematically accurate and important to include in the Solution section. -- Rick Block (talk) 20:42, 8 February 2009 (UTC)

In September or October I used the Monty Hall Problem Article to further my understanding of the puzzle. I found about 1000% more editorial matter than I would have expected. It's roughly 1% useful, 99% BS. Since then, I've been trying to establish why I believe it's 99% BS in order that this be deleted. I have chosen to use Probability Theory as the (only) appropriate method to convice the other editors. I have proferred what I am confident is a valid proof, and have requested that other editors find any errors. This has gone on for 4 or 5 months now. I am not unique in this. There is about 4 years of history attempting to do what I have set out to do. Rick says I'm not addressing the right problem. I insist that I am. Here's the proof. It's longer than it needs to be for clarity:

There are really only two situations to consider. Not 3, not 6.

2/3 of the time I will choose a goat.

100% of those times Monty reveals the other goat, leaving the car.

=>2/3 of the time I should switch.

1/3 of the time, I will choose the car.

100% of those times Monty reveals one of the goats. It doesn't matter which.

=>1/3 of the time I should not switch.

2/3 is greater than 1/3.

Therefore, by switching, I increase my chances of getting the car when offered the switch.

Because it only takes one proof. And I've presented it. And it's valid. And it proves that ALL that other stuff is nonsense.

There's another dozen points of disagreement. There's no point getting to those until we resolve the question of whether or not the 1st Solution (or something like it) is correct, and that all that other stuff is BS.

But, we're basically at a standstill. Neither Rick or I is going to pursuade the other. I want to see the page improved, finally, and requested that our Conflict get some Escalated Resolution help. Glkanter (talk) 21:06, 8 February 2009 (UTC)

Glkanter I totalt agree with you the current article is Bull crap! 99% useless and 1% useful. It does not do a good job communicating a simple and straightforward unconditional solution! I totaly agree with you and I want you to change it!! I have however started to lose interest because RickBlock is married to the current article and he interpret any attempt of changes as an attack on him. I just wonder why is his name RickBlock by the way? I thought the whole point was to collaboration?! I am actually a bit insulted by his choice of name!!--92.41.214.24 (talk) 22:14, 8 February 2009 (UTC)

Just FYI - it's my real name. -- Rick Block (talk) 22:50, 8 February 2009 (UTC)

I'm still not up to speed on this, but I have a few general comments.

• 92.41.214.24: the content of the "solution" section of this revision is far too fragmentary to be the actual content of a WP article. It would need to be turned into actual proseto be readable by an untrained reader.

ha, ha what do you mean by an "untrained reader"...My solution is the most simple one! (No BS, No waffle, like a punch in the stomach. Even though I have a PhD I dont expect anyone ells to have the same traning or understanding..:-) --92.41.112.145 (talk) 00:01, 9 February 2009 (UTC)

• Glkanter: if your proof is correct when written out, this does not mean that "And it proves that ALL that other stuff is nonsense." There are always multiple proofs of any result, and different people will likely find one or another more pleasing.
• Rick Block: the difficult with the Monty Hall problem is always the specific wording of the problem (hence the issues with Marilyn vos Savant). In the end there will never be a perfect wording. I think it will be possible to model the natural-language problem successfully either as a conditional or unconditional probability. It may be that the article could explain this in a footnote.

I also have a few questions if none of you objects:

• Glkanter: when you talk about there being 99% extraneous stuff, do you mean just the "solution" section, or the entire article?

Glkanter has a point and that is that we should focus on the critical stuff. The more waffle you introduce the harder is it to understand. The solution should be max 5-6 sentences, all other stuff is just NOISE....bla...bla...blabbla....blabblallaaa...The current article is located at the pinnacle of confussion, waffle and BS. --92.41.41.161 (talk) 23:35, 8 February 2009 (UTC)

• Rick Block: would there be a clear way that the article could explain the conditional/unconditional thing, so the article can handle it thoroughly at some point and then move on from there?

— Carl (CBM · talk) 23:03, 8 February 2009 (UTC)

Carl - having lived with this for several years, the least contentious approach has seemed to be to use quoted versions of the problem description (and a fully explicit version constraining the host to pick randomly between two goat doors is necessary to justify the Bayes treatment). The "vos Savant" version is far and away the best known, but it's not only conditional but under-specified. The conditional/unconditional thing is mentioned in the Solution section, and again under Sources of confusion. If we're to expand it (which I suspect Glkanter and others will argue against), I think the natural spot would be the "Sources of confusion" section. -- Rick Block (talk) 23:31, 8 February 2009 (UTC)

Of course, various styles of proofs would be included. You're two questions seem like one...What would be gone specifically from the Solution section is pretty much everything. I think the existing solution is overly complex. I'd obviously like to see one of the proofs offered here in the last few months be considered. Then a few other proofs. All the other current stuff in the Solution section should be deleted.

I'd like to see the 'combined doors' method elevated to the Solution section from the Aids to Understanding.

The rest of the stuff? I don't care. Just as long as each and every reference to the Solution being 'incomplete' or 'lacking rigour' is deleted. Variants? Sources of Confusion? Morgan et al? Bayesian? That stuff's above my paygrade.

Oh, yeah. And let's get rid of the banner at the top of this page. I've never seen anything like it. The two reference to 'confirmed by experiment' are awful.

Glkanter (talk) 23:29, 8 February 2009 (UTC)

Upon further review, I would eliminate the Sources of Confusion section. Anything in there that can't be moved to Aids for Understanding is itself a source of confusion and should be eliminated.

Glkanter (talk) 03:03, 9 February 2009 (UTC)

@Glkanter: look at what happens in 18 realisations of the game;
I sorted the outcomes for a better overview:

Choice  1 1 1 1 1 1 1 1 1 1 1 1 2 2 2 2 2 2 2 2 2 2 2 2 3 3 3 3 3 3 3 3 3 3 3 3
Car     1 1 1 1 2 2 2 2 3 3 3 3 1 1 1 1 2 2 2 2 3 3 3 3 1 1 1 1 2 2 2 2 3 3 3 3  
Open    2 2 3 3 3 3 3 3 2 2 2 2 3 3 3 3 1 1 3 1 1 1 1 1 2 2 2 2 1 1 1 1 1 1 2 2

6 times there was the same situation as in the player's case; here they are:

Choice  1 1 1 1 1 1 
Car     1 1 2 2 2 2   
Open    3 3 3 3 3 3 

The conditional (!) probability to win the car by switching is (surprised?): 4/6 (BTW: the unconditional probability is 24/36, different, but numerically the same!) After all that is allready said, what needs to be said more? If you're not convinced, I guess you don't want to be convinced, or worse.Nijdam (talk) 23:13, 8 February 2009 (UTC)

Nijdam...what are you doing?? This is not quantum physics!! There is no need for simulation. It is a straight forward argument that does not need simulation. The more complex you make it the higher I will scream ! —Preceding unsigned comment added by 92.41.251.196 (talk) 23:45, 8 February 2009 (UTC)

It is not the general relativity theory either, yet the above figures explain it all. Please scream, if it make you feel better, I'll go to sleep.Nijdam (talk) 00:03, 9 February 2009 (UTC)

ha, ha you are funny ! yes, I think I will go to sleep also...I have had enough of this —Preceding unsigned comment added by 92.41.112.145 (talk) 00:06, 9 February 2009 (UTC)

What would make this article better would be a rearrangement of content that puts like things together, progresses from simple to complex, and uses headings that clearly define the issues. Here is a suggestion:

1 History of the problem (This would not be about the Three Prisoners problem or other “pre-history” problems, but about what happened when the problem appeared in Parade and in follow-up columns. This satisfies the needs of the casual reader.)

2 Explanations clearly consistent with the original solution (This would include 2.1 Name for the first explanation, 2.2 Name for the second explanation, etc.)

3 The common objection (This would be about the difference between asking the more general question whether one should switch, versus the more specific question whether one should switch when, say, door #3 is opened.)

4 Explanations that meet the common objection (This would include 4.1 Name for the first explanation, 4.2 Name for the second explanation, etc. Bayes would be here.)

5 Another objection (This would be about the objection that one does not know if the host is as likely to open one wrong door as another when the player chooses the right door, and the Morgan, et al. solution.)

6 Similar problems (The Three Prisoners problem would be moved into this section.)

7 Theories about the problem

Omit objections that clearly contradict the problem as stated, or put them into a final section 8: Other objections and why they are irrelevant

This proposal, or something like it, meets the needs of both the casual reader who has heard of the problem and wants to know what the deal was, and the reader who is interested in a greater understanding of the issues.Simple314 (talk) 01:10, 9 February 2009 (UTC)

Can anyone answer these questions:

1. Why is the Parade quote included in both the unnamed introduction and the first named section, “Problem”?

2. What is the significant difference between the introduction and the “Problem” section?

3. What is the purpose served by including both as separate sections?

Seriously, the article looks like a bunch of things added onto each other, one after another. The design begs for pointless arguments. Simple314 (talk) 02:05, 12 February 2009 (UTC)

1) The unnamed introduction is the "lead", which according to Wikipedia:Manual of Style must exist and (according to Wikipedia:Lead section) "should be able to stand alone as a concise overview of the article".

2) The intro contains an overview of the entire article, the "Problem" section describes the Problem statement in detail.

3) Whatever the first section is after the lead must (because of local style guidelines) repeat content from the lead. -- Rick Block (talk) 02:27, 13 February 2009 (UTC)

Thanks for your response. However, it is not completely consistent with the way things actually happen, and deciding what counts as the "Problem" section is happening far too early. Simple314 (talk) 04:06, 13 February 2009 (UTC)

I don't understand what you mean. Can you please explain? -- Rick Block (talk) 06:12, 13 February 2009 (UTC)

The reason many people are confused is that they wonder what happened to the odds that the car was behind Door #3, once Door #3 was opened. Did the odds disappear? Did they go somewhere else in the problem? According to the usual answer, they joined the odds that the car is behind Door #2. But why? Why did they go there, instead of going with the odds that the car is behind Door #1? Or splitting themselves in half, one half going with Door #1 and one half with Door #2?

Did they scurry over to hide behind Door #2 because Door #2 was closer? What if the player had picked Door #2 to begin with?

Instead, the answer tends to be, they joined the odds behind Door #2 because of some inexplicable, impossible to follow reason that avoids the question, where did the odds go?

They stay within the parenthesis of 1/3 + (1/3 + 1/3) as per the 'Combined Doors' solution. More correctly, the 1/3 is distributed randomly (evenly) across the remaining relavent doors, of which there is exactly 1. So it now reads 1/3 +(2/3 + 0). Glkanter (talk) 14:21, 15 February 2009 (UTC) Glkanter (talk) 15:29, 15 February 2009 (UTC)

Okay, got the main point, but does that mean that "random" means the same thing as "even"? Simple314 (talk) 02:51, 19 February 2009 (UTC)

I don't know. There may be a math rule that says they are. When I mentally set up models of what I think is or will happen, I do equate random with evenly. Absent any info to the contrary, what else can you do? But that's just me. Glkanter (talk) 03:35, 19 February 2009 (UTC)

A better understanding is based on this story, a metaphor, and what is talk of probability but metaphor? When the host opened Door #3, the odds that the prize was behind Door #3 were immediately banished to the Land of Things that Did Not Happen, where they live in a village called “the Host Opened Door #2.”

What is not so easy to realize is that some of the other odds on stage were also banished to that land and that village when Door #3 was opened: namely, “the odds that the prize was behind Door #1 WHEN the Host Opened Door #2.” We take it on faith that those odds are exactly ½ the original odds that the prize was behind Door #1.

That leaves on stage ½ of the original 1/3 odds that the prize was behind Door #1, and the original 1/3 odds that the prize was behind Door #2: 1/6 v. 1/3. The good wizard Ratio of Fractions magically changes those odds into 1/3 v. 2/3, and the moral is, “Switch, because it doubles your odds”

There is another version of this tale, in which a scheming bad wizard casts a spell that makes it impossible to tell what portion of the original odds the prize was behind Door #1 were odds the prize was behind Door #1 WHEN the host opened Door #2, but the people who promote that version are members of a tiny secret order, a portion of those who believe the Monty Hall Problem is fundamentally a probability problem. Their motto is “If it isn’t explicitly stated, don’t assume it is true!” The moral of their morganian story is, “Switch, because it won’t decrease your odds, but it might increase them!”

The rest of us know that the Monty Hall Problem is fundamentally a cute trick designed to fool us into thinking that the odds are even when they definitely aren’t. Our motto is “If you must assume something to make the ruse work, then the assumption must be true! But we may forget to say that.”

I dare anyone to demonstrate this is more pointless than the other points made here. Rearrangement of the article into History, Objection 1, Objection 2, etc., would help avoid silliness and endless arguments. Simple314 (talk) 02:51, 12 February 2009 (UTC)

A brilliant metaphor, is the story of the missing odds published anywhere? -- Rick Block (talk) 02:27, 13 February 2009 (UTC)

A clever example of sarcasm, is there any indication above that the author of the story is suggesting that it should be included in the article? Simple314 (talk) 04:06, 13 February 2009 (UTC)

In all sincerity, I do like it. I realize you were not intending the phrasing above to be added, and a published version would almost certainly not be quite so whimsical, but in all sincerity if there is a published analysis of this sort I think we should consider adding it. I think it is at least as convincing as what is currently in the "Why the probability is not 1/2" section. -- Rick Block (talk) 06:12, 13 February 2009 (UTC)

Sorry for the misunderstanding.Simple314 (talk) 21:22, 13 February 2009 (UTC)

The Monty Hall Paradox is only a paradox for people who like to compare apples to oranges. If a player were to pick one door out of three, two out of three times that player would be wrong. So a player should always switch if they get a second chance. With respect to the POSSIBLE OUTCOMES of this game, there are more scenarios of a player who did switch won a car. But that is not to say that the act of 'switching' improves probability. The probability of picking one door out of two is ALWAYS 1 to 2. This is true by definition. Trying to say othrwise is simply meaningless, and you can not prove it with a computer simulation. Just as you can not prove that the probability of flipping heads of a fair coin is 1 to 2. Try it, it is only true by definition. —Preceding unsigned comment added by 68.198.159.238 (talk • contribs)

If I take 3 cards, say two red twos and the ace of spades, shuffle, deal 1 to you, keep two, look at my two cards and throw out a red two (that I show you), is this equivalent to the Monty Hall problem? Are you saying you now have a 50-50 chance of having the ace? How about if I take an entire 52-card deck of cards, deal one to you, keep the rest, look at them and throw out 50 with none of them being the ace of spades (keeping only 1 card)? Still 50-50? Please try this a few times and let me know how it goes. -- Rick Block (talk) 05:24, 9 February 2009 (UTC)

Rick, is that experiment you describe above the equivalence of the conditional or the unconditional problem? Does it make a difference?

Glkanter (talk) 08:46, 9 February 2009 (UTC)

Glkanter is referring to this discussion, above. In a technical mathematical sense, since the cards are individually distinguishable and since the question of the probability of having the ace is asked at the point the discards are visible, this is a conditional problem. If you want a deeper understanding of this problem, when playing the role of the dealer as your one remaining card always keep the ace if you have it and if not then keep the two of diamonds. Keep track of how many times you try altogether and then (in the three card version) separate tallies for how many times you have the ace when the dealer shows you the two of diamonds and how many times you have the ace when the dealer shows you the two of hearts. I.e. fill out the following table:

Total tries	Total times you had the ace
Number of times dealer showed the heart two	and you had the ace
Number of times dealer showed the diamond two	and you had the ace

If you do this enough (maybe 60 times), you should see your table start to converge (see Law of large numbers) to these numbers

Total tries	Total times you had the ace
60	20 (1/3 of total tries)
Number of times dealer showed the heart two	and you had the ace
40 (2/3 of total tries)	20 (half of these tries)
Number of times dealer showed the diamond two	and you had the ace
20 (1/3 of total tries)	0 (all of these)

What this is showing you is that you (the player) have an unconditional (meaning ignoring which card the dealer discards) 1/3 chance of having the ace even after the dealer only has one card left. However, if the dealer doesn't discard randomly (when he has the ace) your conditional chances of having the ace might be different depending on which card the dealer discards. -- Rick Block (talk) 15:51, 9 February 2009 (UTC)

This is a good improvement on the card simulation as usually described. A version of the card simulation that even more closely approximates the problem as presented involves discarding a card without showing it, and works like this:

Show the ace of spades, the 2 of hearts, and the 2 of diamonds; shuffle them; then deal them in a row, into positions first, second, and third. The card in first position is the card chosen by the player. The dealer (host) looks at the other two cards, and discards the 2 when he sees both the ace and a 2, and discards the 2 of diamonds when both cards he sees are 2s. (Choosing the 2 of diamonds in such cases does indeed make the choice between discarding the second card and the third card equally likely, when both are 2s.)

Keep track of how many times the ace is in the second position, how many times the ace is in the third position, how many times the ace is in the first position and the second card is discarded, and how many times the ace is in the first position when the third card is discarded. After many repeated experiments, it will be clear that of all possible cases, the player wins by keeping the first card when the third card was discarded 1/6 of the time, and wins by switching from the first card to the second card 1/3 of the time—thus doubling the chances of winning by switching from the first card to the second card.

Why is it better that the card is discarded without being shown? The player doesn't know the difference between the two goats, but does know the difference between hearts and diamonds.Simple314 (talk) 02:52, 10 February 2009 (UTC)

Your last paragraph confuses me. Isn't it a premise of the puzzle that the dealer discards a two (reveals a goat) from among his two cards? There's never anything random about this action. It may be random how he chooses which of the two two's, but the fact that he's going to discard a two is a premise. Let's switch back to Monty Hall. Unless the contestant knows something about how Monty chooses 'which goat', he gains no new knowledge when Monty reveals the goat. If he knew something about how Monty chose goats, then that's a new premise or constraint. Which makes it a completely different puzzle.

We have a saying in my business. "If it looks like a duck, quacks like a duck, and smells like a duck, it's a duck."

At the risk of showing my ignorance, I don't think there is a difference between the conditional and unconditional problems. It's already agreed that they have the same statistical probabilities. Now, it looks to me like you're using the exact same simulation that I would use to 'aid in the understanding' of my proposed proof. Since the probabilities are the same, I would suggest that there is no difference in the total knowledge (useful information) on the contestant's part. (That is, the premises and constraints are identical, unlike the 'Monty always chooses the left-most goat-door' variant). Lastly, In order for the two puzzles to be different, yet have the same probabilities, it seems that those probabilities would diverge at some time, yet co-incidentally return to the same values. I don't see that happening. They just both start out at 2/3 and never go anywhere.

Glkanter (talk) 17:04, 9 February 2009 (UTC)

To summarize: in response to my question, you found it necessary to add a constraint, in order to make it a conditional probability problem. That makes it a different puzzle than the Monty Hall Problem. Further, one would not say that the probabilty for this new puzzle is 2/3. Going back to the Monty Hall Puzzle, since this new constaint (left-most goat-door) is known by the contestant (or else, what's the point?), there are scenarios when he knows exactly where the car is. So the answer would be stated "100% when Monty reveals door #3, 100% when I've chosen door #3 and Monty reveals door #2, etc." So this contestant makes more informed choices than the contestant in the real puzzle. So the contestant will win MORE than 2/3 of the time.

Glkanter (talk) 17:50, 9 February 2009 (UTC)

You're constantly missing the point. The player who is offered the option to change, is in the situation of having chosen a door and seeing a door opened with a goat. For different players these doors may differ from the ones for "our" player. But "our" player finds himself in a specific situation, and in this situation he is asked whether he wants to change. In the normal case the answers are the same for all the possible combinations, but all the answers involve conditional probabilities. I suggest you study the explanation I gave above, with all the possibilities summed up. In fact it is a representation of the sample space of the problem. Study it and ask me if you do not understand anything. Nijdam (talk) 18:12, 9 February 2009 (UTC)

No Nijdam I think you are missing the point.If you want an ice-cream you say "I want an ice-cream" you dont say I want a barn, I want animals, I want a cow, I want ice, I want an machine..... The closes way between two point is a straight line and your argument is not located on that line. You argument is just confusing and your intention are at best selfish! Secondly why is "Rick Block" discussing card games?! It does not have any thing to do with the Monty hall problem !! Some of you are all so deluded and confussed that I am just amazed how you manage everyday life. Further, "Rick Block" are you the Evangelist Preach "Rick Block" because if you are everything falls into place. Your stubborness and unwillingness to accept the truth must be a high in demand trade in religious circles since it can not be easy when you have invested your whole life in god to realize that GOD DOES NOT EXIST.--92.41.3.118 (talk) 18:55, 9 February 2009 (UTC)

Easy things first - I don't see the relevance, but I'm not the evangelist who comes up if you google my name. I'm bringing up card games because they are a useful simulation of the Monty Hall problem for those of us who don't have television studios with doors big enough to hide cars and enough money to hire Monty Hall. And please go read WP:NPA.

Glkanter - yes, it's a premise the host discards a red two and the randomness is how he chooses between two of them if he has both. Switching back to the Monty Hall problem, we assume the contestant knows the rules of the game we're telling her. When the host opens a door, she sees the specific door the host opens. What Nijdam is saying is that it's always a conditional problem (at least in anything like the normal presentation of the problem). If the problem statement doesn't say how Monty chooses between two goats, it's still a conditional problem and the mathematically correct answer is we don't exactly know what the probability is of winning by switching but it is something between 1/2 and 1. This is the entire point of the Morgan et al. paper.

Many people don't care about being this mathematically correct (although mathematicians certainly do!) and rather than answer the actual question mentally shift to a different question - specifically, across all players who switch, how many will win by switching (the "unconditional" question, i.e. the all 60 trials in the table above). We can get an answer to this question even if we don't know how the host chooses between two goats, but this isn't the question that is actually asked (go read it - does it say anything about "all players" anywhere?).

In the fully explicit version of the problem we avoid the unsettling "we don't know, something between 1/2 and 1" answer by saying If both remaining doors have goats behind them, he chooses one randomly. This constraint allows us to figure out a single number (2/3), but we're actually saying "given any door the host opens, the player's chance of winning by switching is 2/3". If the chance is 2/3 given any door the host opens, then of course the answer to the "unconditional" question (the probability of winning for all players who switch) is 2/3 - but not the other way around (A -> B does not mean B -> A).

In the left-most goat-door variant of the fully explicit version we can also figure out an exact, single, numeric answer, but there are two answers depending on whether the host opens the left-most or right-most door. In the problem as usually stated the host is opening a right-most door, so (for this variant) we'd say the player has a 100% chance of winning. The more general answer (for this variant) is "the chance of winning by switching is 50% if the host opens the left-most door, and 100% if the host opens the right-most door". For this variant, the answer to the "unconditional" question is still 2/3.

Please pardon my intrusion here. In the next-to-last sentence above, you state "the chance of winning by switching is 50% if the host opens the left-most door". No, it's 2/3. That's because the contestant's original selection has a 2/3 chance of being a goat. Therefore, the remaining door has a 2/3 chance of being the car. Assuming everything else you wrote is correct, your conclusion is therefore wrong. The probability would be somewhere between 2/3 and 100%. Which by definition is not "still 2/3." So it's not equivalent mathematically to the actual puzzle. That's because Monty's added constraint sometimes gives us additional information. Like when it's 100% right to switch. We would expect our chances of success to increase above the previous level of 2/3. This would appear to seriously disrupt your following statements about B=2/3. So, what's the point of the left-most goat variant, anyway? It somehow disproves my proofs in what way?

Glkanter (talk) 07:01, 10 February 2009 (UTC)

50% is correct. The cases are as follows: player selects a goat and the car is behind door 2 (1/3), player selects a goat and the car is behind door 3 (1/3), player selects the car (1/3). In the left-most variant, if the host has opened the left-most door (door 2), we can only be in the first or third of these cases. Players in these cases have selected a goat or the car with equal probability. For the players who have seen the host open the left-most door, switching wins with 50% probability. -- Rick Block (talk) 17:09, 10 February 2009 (UTC)

With the left-most door constraint added, Monty either tells us exactly where the car is, or he doesn't. So, compared to the actual puzzle, he either adds to our knowledge, or does not. But he CAN NOT, under any circumstance, subtract from our original knowledge that 2/3 of the time the contestant chose a goat. Therefore, the contestant always has at least a 2/3 chance by switching, and sometimes 100%. I'd be interested to see the proof that this varient results in a 2/3 overall probability by switching. I don't believe it. And, BTW, this variant (more correctly, 'different puzzle') doesn't matter one bit. It doesn't dis-prove my proof.

Glkanter (talk) 17:29, 10 February 2009 (UTC)

If we call the answer to the conditional question A, and the answer to the unconditional question B, what your "proof" is saying is that A = B. This is true for the "random goat" variant (fully explicit version in the article) variant. However, it's not true if we say nothing about how the host selects between two goats (in which case .5 <= A <= 1, and B=2/3) or if we say the host picks the left-most goat (in which case, A=.5 or A=1, and B=2/3).

I'll freely admit this is VERY confusing. But, it is mathematically correct. Anything else is simply a fuzzy approximation. -- Rick Block (talk) 20:51, 9 February 2009 (UTC)

Rick, would you accept that, if the statement of the problem were to explicitly state that 'no information is revealed that would affect the probability of winning by switching by anything that happens between the players original choice of door and his decision to switch or not' then the conditional and unconditional cases would be indistinguishable. Martin Hogbin (talk) 21:10, 9 February 2009 (UTC)

You asked me somwhere above about the same question. And I replied it is not a matter of not changing probabilities (meaning unconditional and conditional being numerically the same?), but of not limited outcomes. If the information does not limit the possible outcomes, yes, then there is no actual condition. But in the problem, the information limits the outcomes considerably. I.e. only one of the doors may be chosen, what allready excludes 2/3 of the outcomes. Look at my "number example" above. Nijdam (talk) 00:57, 10 February 2009 (UTC)

But the problem is symmetrical with respect to doors.{inserted by Martin Hogbin}

You might think this is kind of a cop out, but it might help some folks understand how things are supposed to work here. Would this change make the conditional and unconditional cases indistinguishable? I really don't care. I would accept it, but only if you (or someone) can provide a significant number of reliable sources, in particular academic ones, that include some condition like this in their statement of the Monty Hall problem. I say "significant number" and "academic" because I've personally read all the references in the current article, many of them academic, and several dozen more and I don't recall anyone ever stating the problem this way. On the other hand, lots of references fully qualify the host's behavior (including constraining the host to choose between two goats randomly). The article needs to be about the same problem the sources are about. Inventing our own version would be original research. -- Rick Block (talk) 03:06, 10 February 2009 (UTC)

I know how things are supposed to work and this is the discussion page, where we are allowed to think for ourselves. All I am trying to do here is establish the fact that what is and what is not a condition is a matter of choice. A condition is anything which is considered might affect the probability. The point I am making is that on this discussion page, you and others use the issue of conditional probability as a indisputable fact whereas it is in fact a decision made by certain authors of academic papers. I agree that they are generally to be considered reliable sources but that does not prevent us questioning their decisions in some matters. Martin Hogbin (talk) 09:53, 10 February 2009 (UTC)

A condition is a restriction imposed on the possible outcomes. The question of affecting "the" probability is a popular way of speaking about the unconditional and the conditional probability. A specific probability is never affected. So if someone speakes about "affecting the probability", he inherently speaks about conditioning. In the problem there is a heavy conditioning: firstly restriction to the chosen door and further restriction to the opened door. Please consider the example given above (with all the numbers) and be aware of the unconditional situation and the restricted conditional one. Nijdam (talk) 11:21, 10 February 2009 (UTC)

The following thought crossed my mind in trying to understand the lines along which some discussiants think. If someone says: no information is revealed, he should complete his statement with "in respect to some event", because in the problem information is revealed about the car being behind Door 2. It is hence tricky to decide that no information is revealed in general just by the wording of the problem. And if one wants to know that no info is revealed about some event: well, he has to compare the unconditional and the conditional prob. So let us consider Door 2. Show me the "unconditional reasoning" for it. Nijdam (talk) 12:08, 10 February 2009 (UTC)

For ease of editing I have answered in a new section below. Martin Hogbin (talk) 21:29, 10 February 2009 (UTC)

Rick, here's one of the areas where you and I fundamentally disagree.

You just wrote, "We can get an answer to this question even if we don't know how the host chooses between two goats, but this isn't the question that is actually asked (go read it - does it say anything about "all players" anywhere?)."

My belief system in Probability Theory says that 'all players' is ALWAYS the question being asked. Isn't that the question being asked when someone asks 'what's the probability of a coin coming up heads?' Why would this be different?

Glkanter (talk) 21:34, 9 February 2009 (UTC)

Different questions are different. We have to pay attention to what they say. The Monty Hall problem says "Imagine [or say] you pick door 1 and the host picks door 3. Is it to your advantage to switch?" If you want to generalize this to a bunch of players it would be "for any player who picks door 1 and the host then opens door 3, what is the chance of winning by switching?". All these players would find themselves in the same situation as our given player. Generalizing this to "for any player who plays the game, what is the chance of winning by switching" ignores aspects of the problem that may, or may not, be significant. The stated conditions are "player picked door 1 and host opens door 3" (and host always opens a door, and host always shows a goat, and host picks which goat to show randomly if he has a choice). Ignoring ANY of these conditions may make the solution mathematically unsound. I keep bringing up the example of how the simple solution (which ignores several of these conditions) results in the wrong numeric answer for the question actually asked by the left-most door variant. It produces the correct numeric answer for the fully qualified version stated in the article, but right answer sometimes and wrong answer other times is pretty much the definition of mathematically unsound. -- Rick Block (talk) 03:06, 10 February 2009 (UTC)

Two things. In the specific door 1, door 3 question, why isn't it 2/3? Doesn't the contestant have a 2/3 chance of picking a goat? Then Monty shows the other goat, leaving a car. That's all we know at this point, right? That fits in perfectly with my new and improved, customized Super Proof! (Tip of the hat to a certain MH, who I shall keep out of this.)

Every time this contestant picks a goat, Monty will reveal the other goat, leaving the car. (As you just wrote above, it is a premise that Monty will always randomly reveal a goat behind one of the remaining doors).

[When selecting door 1], 2/3 of the time this contestant will pick a goat.

Therefore, when it is offered, this contestant should switch door 1 for door 2 to improve his/her chances of selecting the car.

The second thing is, I reject the door 1, door 3 literal interpretation. (Not that it makes any difference, as I just proved.) That's not how Probability Theory works. And that's not what makes this an internationally known paradox. Heck, the real Monty didn't even use doors. He used curtains.

Glkanter (talk) 05:16, 10 February 2009 (UTC) Glkanter (talk) 06:14, 10 February 2009 (UTC)

The third point is, the 'left-most door variant' is a different puzzle. It adds a new constraint on Monty. Which, in some cases, causes Monty to reveal the exact location of the car. My proof was never intended to solve that problem. I wish you would stop using this as your 'proof' that my proofs are flawed. I think it's this action on your part that I react the most strenuously against.

Glkanter (talk) 05:24, 10 February 2009 (UTC) Glkanter (talk) 06:14, 10 February 2009 (UTC)

The left-most door variant is not my example, it's what is used in the academic literature to show the exact difference we've been talking about all along. The point is in this variant the player still has a 2/3 chance of initially selecting a goat, and Monty must still open a door revealing the other goat. Which means your "proof" should still apply, since these are the "givens" that your proof uses. The way math works, a proof has a "givens" section and applies to any instance of a problem satisfying those givens. Your proof does not distinguish this variant from the fully specified problem given in the article because it does not use the "given" in the fully specified version that says the host picks randomly between two goat doors. If it's a valid proof, it must be valid for any instance of a problem meeting its "givens". In effect, your proof changes the fully specified problem statement, replacing If both remaining doors have goats behind them, he chooses one randomly with If both remaining doors have goats behind them, he may choose one however he'd like - randomly or not.

The problem statement doesn't have to be taken exactly literally (meaning player picks door 1 and host opens door 3), but it clearly means we're talking about a case where a player has picked some door and the host has opened some other door in response. We're talking about 6 possible cases: player=1/host=2, player=1/host=3, player=2/host=1, player=2/host=3, player=3/host=1, player=3/host=2. The problem as worded in the article (as worded nearly anywhere) is asking about the probability of winning by switching in only one of these cases, not the probability of winning by switching in the aggregate. We could list the six cases and say, "for a player in any one of these six cases, what is the probability of winning by switching". Your solution does not apply to any of these cases individually but treats them all as one undifferentiated clump. The probability in each of these cases (the conditional probability) doesn't have to match the probability in the aggregate (the unconditional probability). -- Rick Block (talk) 16:40, 10 February 2009 (UTC)

I stated once before that I was unsure of your grasp of the subject material. The above posting increases my concern. It's unpleasant to write that. It's important that I write it. Because it's my reason for not addressing your posting point by point. I will never do that again.

Monty's 'motivation' is immaterial, unless it is known to the contestant. At which point that becomes a new premise/constraint of a new puzzle. Following your theory, we should also concern ourselves with the 'motivation' of the stage hand who originally arranged the 3 items behind the doors. For probability purposes, we call those actions 'Random'. And they deserve no further scrutiny.

Glkanter (talk) 17:02, 10 February 2009 (UTC)

And I stated before I didn't think you were a troll. You have now convinced me otherwise. I'll enlist uninvolved admins to enforce this if necessary, but in my view your posts have now reached the point of disruptive editing. If you continue in this manner I will report you to WP:ANI and suggest you be blocked from further editing. -- Rick Block (talk) 17:54, 10 February 2009 (UTC)

I've wondered how you would respond when the inevitable happened, and your arguments were proven to be meritless. Now we know. You attack the messenger, and start posting that for Wikipedia purposes, the Truth (being right) is less important than having been published.

I've asked for Wikipedia intervention for days now. I welcome any actions you take to bring closure to this festering sore.

Glkanter (talk) 18:35, 10 February 2009 (UTC)

There may be a kind of solution that comes close to the "simple intuitive solution", but is really a solution to the problem. Suppose the player is in the situation of having chosen door 1 and being opened door 3. We indicate this situation as [13]. Of course other players may find themselves in [12], [21], [23], [31] or [32]. Together all these 6 situation represent the unconditional one. With the "normal" strategie of the host, there is no fundamental difference between these 6 situation, hence the (conditional) probability of winning the car by switching is the same for each. But the overall probability, the unconditional, is 2/3, as we know from the intuitive (simple) solution. But then all the conditional probabilities must aldo be 2/3. Will this be satisfactory? Nijdam (talk) 15:38, 10 February 2009 (UTC)

Given no original research and verifiability are fundamental Wikipedia policies, how would you reference this? The bottom line is we care less about the Truth™ than accurately representing what reliable sources say. From an academic viewpoint, what we do is summarize published literature - and that's all. -- Rick Block (talk) 17:28, 10 February 2009 (UTC)

Somehow I unintentionally deleted this:

Does anyone else find the above paragraph troubling? I certainly do. And after 4 years, and thousands of postings on the Monty Hall Problem, I find it incredibly ironic.

Glkanter (talk) 18:22, 10 February 2009 (UTC)

Glkanter (talk) 18:24, 10 February 2009 (UTC)

Glkanter (talk) 20:36, 10 February 2009 (UTC)

Yes, I find it troubling also! I just hear bla bla bla bla bla.. there are so many word but no insight and understanding at all. WAFFLE WAFFLE WAFFLE --92.41.187.141 (talk) 21:02, 10 February 2009 (UTC)

What's ironic is that you think it's ironic. I've consistently been pointing you to sources that you have consistently ignored, while you have offered up not a single source to support any of your views. What I've been trying to do on this talk page is help you understand what the sources say, in an effort to get you to understand that the changes you'd like to make to the article would turn it into something other than an accurate summary of the sources (which is what it is supposed to be). Most folks tend to believe what peer reviewed academic sources have to say is correct, and if faced with a conflict between what such sources say and their own internal beliefs are at least willing to consider the possibility that their internal beliefs may be incorrect. -- Rick Block (talk) 19:13, 10 February 2009 (UTC)

It has been a fact for a long time that "Rick Block" is a burden for other wikipedia users when it comes to producing a high quality Monty hall article. That "Rick Block" has started to threaten other wikipedia editors such as Glkanter is even a bigger concern! You think you own wikipedia and no one has the right to question your arguments. I suggest you tone down your involvement because there are a lot of people that is starting to get very tired of your lenghty, emotional, unintelligent, stubborn and confussing posts. When you have realize that the best answer is a simple one then you are welcomed back.......--92.41.187.141 (talk) 20:56, 10 February 2009 (UTC)

Personal threats and accusations are undesirable from all contributors to Wikipedia. Martin Hogbin (talk) 22:12, 10 February 2009 (UTC)

Hey Rick, which "peer reviewed academic sources" did you get this gem from?

"The overall probability of winning by switching is determined by the location of the car."

That was sentence #1 of the Solutions section until I deleted it last year. It is 180 degrees counter to every bedrock principle upon which Probability Theory rests.

Glkanter (talk) 21:46, 10 February 2009 (UTC)

ha, ha that is a good one! That is just bad!! I am a bit scared actually! The person that wrote that has no clue...--92.41.187.141 (talk) 22:46, 10 February 2009 (UTC)

This afternoon I posted a reply above the big black table which I falsely assumed to be the end of the page. Now I also read the rest of it and I will post some of it again, with added content: my opinion is that this whole issue is about one simple question: should the requested chance be regarded as a conditional probability, and if so, why? I agree with Martin Hogbin that the issue of conditional probability is regarded "as an indisputable fact". Morgan et al. only give us a hint: "F5 is incorrect because it does not use the information in the number of the door shown." What information is in the number? Nijdam writes: "what is the meaning of "no information is revealed"? This actually means that the possible outcomes are not restricted." and: "The question of affecting "the" probability is a popular way of speaking about the unconditional and the conditional probability." However, the article Conditional probability states that P(B|A) = P(B) if A and B are statistically independent. In other words: conditional and unconditional chances are the same if A does not change the probability of B. And it doesn't. Heptalogos (talk) 21:51, 10 February 2009 (UTC)

yes that is correct when A and B are independent then P(B|A) = P(B). Good observation! :-) --92.41.187.141 (talk) 22:42, 10 February 2009 (UTC)

I am trying to get agreement on a hypothetical question. Suppose the question posed was this:

Suppose you're on a game show, and you're given the choice of three doors: Behind one door is a car; behind the others, goats. You pick a door and the host opens another door which has a goat and he does this in a way the does not affect the probability that your original choice was a car. He then says to you, "Do you want to pick the other unopened door?". What is your advice?

I know that this is not the question actually posed but in the above case do you accept that the conditional case is identical to the unconditional one? Martin Hogbin (talk) 22:09, 10 February 2009 (UTC)

I think that the statement of Boris Tsirelson confirms the point that I am making.

This makes the result of the conditional case the same as the result of the unconditional case, but does not make them "the same". The question is still, formally, a conditional question. -- Rick Block (talk) 05:23, 11 February 2009 (UTC)

In that case, why do we not consider all the other actions that occur between the original choice and the decision to swap as conditions? 09:39, 11 February 2009 (UTC)

What I would like to have is an addition to this article of a very simple and convincing explanation of the essential Monty Hall problem.

I believe that, for this purpose, it is acceptable to consider the unconditional problem for the following reasons:

1 The inability of most people to get the right answer, however the problem is formulated, is what makes it notable.

2 The academics who have studied the problem have to some degree (understandably) obfuscated the central problem with unwarranted and unjustified complications, including making it necessarily conditional.

3 Even if the conditional version is considered to be the best one, it is not uncommon in mathematical expositions to start by answering a related, and often simpler, problem and then to explain how this relates to the full blow problem.

The more academic discussion can remain as it is for those who are interested. Martin Hogbin (talk) 23:09, 10 February 2009 (UTC)

Martin - we've discussed this before and I think we're on basically the same page. The problem is notable because most people get the answer wrong, and people who assert the wrong answer are typically certain that they are correct (which makes for a large number of popular references, and a fair number of academic references including psychology papers exploring why the problem is so difficult). I'd rephrase point 2 somewhat - the academics who have studied the problem have shown even people who think they understand it and get the "correct" answer are often using mathematically unsound approaches. I view this as layers of understanding. We have people who will believe to their dying day it must be a 50-50 choice because (as any idiot can see) there are only two doors! Any of the simple solutions (treating the problem unconditionally) are more sophisticated answers. However, if we look closely at the problem, we see it is a conditional problem, not an unconditional one, so even the people who get that it's not a 50-50 choice aren't exactly correct either. Some of these people will apparently believe there is no difference between unconditional and conditional problems until their dying day because (as any idiot can see) 2/3 of the players will initially pick a goat and will win if they switch. Explaining that it is actually a conditional problem is not "obfuscating the central problem with unwarranted and unjustified complications". It's actually solving the problem as its given. -- Rick Block (talk) 05:53, 11 February 2009 (UTC)

I take it that we more or less agree about the first point.

I think you are wrong about people who get the right answer using unsound approaches. As I hope to show below Morgan et al do make the solution unnecessarily complicated by failing to take account of the natural symmetry of the problem and inventing doubts in the formulation of the problem when in fact there are none.

Even if one accepts that the conditional answer is the right one, what about my point 3. This approach is not at all uncommon in published papers. Martin Hogbin (talk) 11:12, 11 February 2009 (UTC)

Well, isn't this the exact structure of the current solution section? It correctly solves the unconditional problem, and then goes on to show a solution for the conditional. -- Rick Block (talk) 12:34, 11 February 2009 (UTC)

We can start by observing that, if the player switches, he always gets the opposite of his original choice. The are no conditions involved, no probabilities, no dependence on host action - this is a certainty. Obviously of he does not switch he keeps his original choice.

All we have to show now is that the action of the host does not affect the probability the he had originally chosen a car, or to put it another way, that no information is revealed that might indicate the players original choice was.

Let me ask this question, looking at the Parade statement, what is the information that is revealed? Martin Hogbin (talk) 23:23, 10 February 2009 (UTC)

The information that is revealed is the specific door the host opens. It might not be a random choice if the player's initial pick is the car, in which case the probability of winning by switching might be anywhere from .5 to 1 (per the Morgan et al. and Gillman papers). Regardless, isn't the text currently in the solution section above the figure almost exactly this "simple" solution? -- Rick Block (talk) 03:51, 12 February 2009 (UTC)

Yes, I forgot, there is an explanation along these lines buried in the article. Perhaps my only complaint is that it is not clear or prominent enough. That section seems to try to answer several questions at once.

However, you are not answering the question, you are merely speculating on what the question might have been. Do you see my point? We both agree that you must answer a probability question on the information given in the question. Looking at the Parade statement, what is the information that is revealed? To put it another way, does the question tell is that it is more likely or less likely that the player originally picked a car after the host has opened a door. It clearly does neither, that is all the information that we have.

You are free to speculate on what might be the case, but that is not answering the question, it is changing it. Martin Hogbin (talk) 09:22, 12 February 2009 (UTC)

The question of wheter any information is revealed or not, is precisely where it is all about in this discussion. But here Martin merely states that no information is reavealed and hence the conditional prob. is the same as the unconditional, and also he has to admit that it is the conditional prob. which is of interest. The only thing is, he says I know on forehand what it's value will be. But the arguments why no information is revealed are missing. And the arguments may come by computing the conditional prob. or by considering the symmetry in the problem. But it is always the conditional prob. that has to be considered, and always some argumentation is needed. Nijdam (talk) 18:40, 14 February 2009 (UTC)

For clarity in the discussion: I will remove any comment of someone else besides RickBlock and Martin Hogbin given between this header and the corresponding trailer and move it above this header. Also I put this section allways at the end of this page.

@RickBlock. It's sad and frustrating all these people, hardly knowing anything about probability, but yet thinking they just know all the ins and outs of this problem. From now on, I'll only discuss matters with you (as one expert), if necessary, and with MartinHogbin, who seems to me at least responding in an adequate manner. Others may profit by reading the comments, I will no longer respond to them. Also I think it is about time this discussion ends. My suggestion above under "work around" (maybe not so well chosen title) is a sound reasoning, in the line of the "simple solution". It lookes if you crititizised it. It is (seemes?) easy to proof and may be helpfull in understanding the conditional nature as well. Nijdam (talk) 22:55, 10 February 2009 (UTC)

You say above With the "normal" strategie of the host, there is no fundamental difference between these 6 situation, hence the (conditional) probability of winning the car by switching is the same for each. I think this is the same endpoint Martin is trying to get to. I'm not sure if you're asking what I think about the math of this, or if you're suggesting including something like this wording someplace in the article. I'll answer both questions.

As math, if by "normal strategy of the host" you mean the behavior as prescribed in the fully explicit version including the "random goat" constraint I think "no fundamental difference between the 6 cases" needs to be a conclusion rather than an assumption. The "random goat" constraint is what forces the 6 situations to be symmetric - it is (at a fundamental level) why this constraint must be included implicitly or explicitly in a Bayesian analysis.

As for including this in the article, I think we might add something like it as an observation following the conditional solution, or in the transition between the unconditional and conditional solution. I know you object to the unconditional solution, however there are certainly plenty of reliable sources that present unconditional solutions. Would you be better with "so and so's solution, which says this, shows the unconditional probability is this", followed with an explanation of conditional vs. unconditional, and then a conditional solution? This is meant to be the current structure. I said this elsewhere (not sure if you noticed) but if you are an academic I think the right way to think about the article is that it is supposed to be a detailed summary of the popular and academic literature. How would you summarize the popular literature that treats the problem in an unconditional manner? -- Rick Block (talk) 13:07, 11 February 2009 (UTC)

Like you. I also strongly object the 'unconditional' non-solution, that's the whole point in this discussion. Maybe I didn't express myself clear enough. The "work around" idea is to incorporate the basic idea of this unconditional reasoning as to explain the right conditional explanation. Of course in the 'random goat' strategy, only then there symmetry in the 6 basic cases. And this symmetrie is not a conclusion of the calculation of the condtional probs. The suymmetry leads to equalness of the conditional probs. Hence it can be used ([123] means chosen 1, opend 2 car 3) as follows: for all a,b,c all different:

${\displaystyle {\tfrac {1}{3}}=P({\text{winning by switching on forhand}})=}$

${\displaystyle P([123]\lor [132]\lor [213]\lor [231]\lor [312]\lor [321])=}$

${\displaystyle \!\,\sum _{[ij*]}P(...|[ij*])P([ij*]=P([abc]|[ab*])}$

Hence all conditional probs equal 1/3. But it remain (are) cond. probs.

The 'random goat' strategy is part of the premisses and I think the 'unconditional' non-solution doesn't find support in other cases. or is this the point you are making, that people reason in the same way even when the host has another strategy? Nijdam (talk) 12:26, 12 February 2009 (UTC)

Yes, the point is various host strategies make the problem symmetric or not and the unconditional non-solution (as you put it) ignores the host's strategy. If you assume the problem is symmetric, the conditional probabilities are all the same as the unconditional probability but how do you justify this assumption? The "random goat" constraint is the only thing that makes the problem symmetric, but it does so by making the conditional probabilities all identical which makes the problem symmetric. It's not the symmetry that makes the conditional probabilities the same, it's the other way around. Try to solve the problem with a Bayesian analysis without using the "random goat" constraint. I think you'll find you have to introduce the "random goat" constraint to get the 2/3 win by switching answer. This is the exact same issue.

BTW - please don't move the section (it's fine to add to a section that is not at the bottom of the page). -- Rick Block (talk) 03:26, 12 February 2009 (UTC)

Okay! Indeed is the problem symmetric only with the 'random goat' strategy. But this strategy is part of the formulation of the problem. The symmetry doesn't stem from the equality of the probs, but from the fact that the problem is then invariant under permutations of the doors. And hence all the conditonal probs must be the same. And this implies they are equal to the unconditional 1/3. But they are of course conditional. So I don't say the 'simple reasoning' is correct, but a kind of 'simple reasoning' may be used. And yes, I know, without the 'random goat' there is no symmetry. And also then it are the conditional probs that had to be considered. Nijdam (talk) 12:26, 12 February 2009 (UTC)

How does the random goat strategy make the problem invariant under permutations of doors? Note that the host is in some cases constrained by the players first pick (when the player initially picks a goat) but in other cases not (when the player initially picks the car)? I can see an argument that the problem must be symmetric if the host always randomly picks (that would be the "forgetful host" variant), but that's not the case here. If you can provide a reference for this, or some sound reasoning based on probability theory, that would be great. I.e. treat it like a theorem:

Theorem: In the Monty Hall problem, the random goat constraint makes the problem invariant under permutations of doors.

Proof: ??

From the perspective of including this line of reasoning in the article, if the proof is not simply "see <so and so>, published <here>" you're doing what Wikipedia calls original research (which is disallowed - making Wikipedia in a sense the inverse of academia where original research is one of the primary goals). -- Rick Block (talk) 14:54, 12 February 2009 (UTC)

What is there to be proven? In the 'random goat' strategy there is no reference to any specific door, hence no door plays a different role than another one. Hence all the situations on stage chosen a and opened b are equivalent. Is this original research? I think, this is what the advocates of the 'non-solution' really have in mind wthout being able to formulate it. Nijdam (talk) 17:07, 12 February 2009 (UTC)

@Martin Hogbin. I repeat the following points:

1. The precise stated problem can only be solved by determining the conditional probability given the situation the player is in, i.e. given the number of the chosen door and of the opened door.
2. The simple solution is therefore not a solution to the stated problem.
3. The simple solution lookes very attractive and its line of reasoning may be used as follows.
4. The conditioning will be on one of the 6 possible situations: [12], [13], [21], [23], [31] and [32], (I repeat here what I stated above), where for instance [21] means door 2 is chosen and door 1 opened. They form a partition of the complete sample space. But from the symmetry of the problem it is also clear that conditioning of either of them leads to the same probability of finding the car behind the chosen door. Hence these conditional probabilities are (numerically) equal to the unconditional one of 1/3. In the article this should be phrased in a proper way as to be understandable to the reader.
5. You keep asking about conditioning, so I give you (again) the sample space and derivations.
   

chosen  1 1 1 1 2 2 2 2 3 3 3 3

car     1 1 2 3 1 2 2 3 1 2 3 3

opened  2 3 3 2 3 1 3 1 2 1 1 2

prob    1 1 2 2 1 2 2 1 2 2 1 1 /18

The columns form the outcomes with their probability (/18 as indicated)
In which situation is the player? That is which event has occurred? Well in the stated problem [13], which is:

chosen  1 1

car     1 2

opened  3 3

prob    1 2 /18

consisting of 2 outcomes, and really a proper part of the sample space. In the second column the car is behind the not chosen door, and the well known conditional (!) probability of winning the car by switching is: (2/18)/(3/18) = 2/3.
Nijdam (talk) 23:41, 10 February 2009 (UTC)

A am suggesting that the formulation of the problem by Morgan et al introduced unnecessary uncertainties. Here is the Parade statement for reference:

Suppose you're on a game show, and you're given the choice of three doors: Behind one door is a car; behind the others, goats. You pick a door, say No. 1, and the host, who knows what's behind the doors, opens another door, say No. 3, which has a goat. He then says to you, "Do you want to pick door No. 2?" Is it to your advantage to switch your choice?

What does it say about the host offering the choice, it says: 'He then says to you, "Do you want to pick door No. 2?" '. Note that it does not say 'sometimes says to you' or 'may say to you' but 'says to you'. There is no mention in the statement of the problem that the host may not offer you the choice. That possibility is an invention of Morgan.

It says the host, 'opens another door'. It does not give the way that the host decides which door to open. We must therefore take this as random. This is perfectly normal in probability problems, in cases where the method of selection is not given we take it as random, this is not an assumption it is an obligation.

Does the host always reveal a goat. The statement says, 'which is a goat'. It is therefore pure invention to assume that it might not be.

There are an infinite number of perverse actions that could occur in the problem - what if sometimes there are three goats? We do not address these possibilities because they are not part of the stated problem.

Martin Hogbin (talk) 11:34, 11 February 2009 (UTC)

I think Morgan accounts that one cannot define chances in a single situation; one should always have in mind a statistically justified experimental situation. Hence, a statement could be made about the consequent behaviour of the host, making it possible to repeat the show. But I agree with you, that if you simply repeat (theoretically) the exact behaviour of the host, you shouldn't need to fantasize about behaviour rules, let alone other options. I guess Morgan is trying to make it better understandable, and actually Morgan's article seems to be written for an average public, which may make it less reliable as an academic source. Heptalogos (talk) 12:08, 11 February 2009 (UTC)

Martin - I think you may be missing the point Morgan et al. are making. I believe their primary point is that the problem is about the 6 cases of player pick and host door Nijdam has enumerated above, not the aggregate. They then solve the problem as literally stated in Parade (granting the assumption that the host always opens a goat door and always makes the offer to switch - which plenty of others, not them, criticized vos Savant for). The problem as stated in Parade doesn't say how the host decides to pick between two goat doors, so in their solution they assume nothing about this. The "natural" assumption might be the host picks randomly, but there's no mathematical justification for this. Using Nijdam's notation (i.e. [12] means player initially picked door 1 and host opened door 2), their solution could be reformulated as a theorem of the form:

There is every justification for taking it that the the host's choice of door as random and that is that we are given no information about how the host decides. We therefore musttake this as random, this is not an assumption or a supposition it is the only thing that you can do when you have no information, it is the standard thing to do in all probability questions. To invent a number of perverse scenarios and then calculate the probabilities on that basis is not maths, it is speculation. I have added a section below to demonstrate this. Martin Hogbin (talk) 21:43, 11 February 2009 (UTC)

Given <Parade description plus host must open a goat door and must offer the chance to switch>, the probability p of winning by switching for [PH] is .5 <= p <= 1 for [PH] in ([12], [13], [21], [23], [31], [32]).

In the "given" of this theorem we've said nothing about how the host decides to pick between two goat doors, so we can't assume anything about this. I think they'd be perfectly happy to solve the same problem again with a different "given", but their approach would be the same - i.e. what the question is asking is the probabilities of the individual cases, not their aggregate. I don't really know, but I think they might have been surprised by the answer they got. It's surprising enough that Glkanter apparently flat out refuses to believe it. -- Rick Block (talk) 13:46, 11 February 2009 (UTC)

Rick, Martin writes that "the host may not offer you the choice. That possibility is an invention of Morgan." I will quote Morgan: "Before proceeding, another point not addressed by the question needs to be considered. If the player's original choice does not contain the auto, does the host has the option of revealing the door that does? That is, in the playing of the game, does the host always give the player another chance, or does he sometimes end the game immediately by opening the door with the car?" Heptalogos (talk) 14:12, 11 February 2009 (UTC)

Yes, Morgan et al. are acknowledging the controversy about this. My point is this controversy preceded their paper. To be thorough, they show the effect of assuming this or not. -- Rick Block (talk) 15:09, 11 February 2009 (UTC)

OK, apologies to Morgan, I blame whoever first proposed the idea. Martin Hogbin (talk) 21:43, 11 February 2009 (UTC)

The Parade statement: "You pick a door, say No. 1, and the host, who knows what's behind the doors, opens another door, say No. 3" What does this mean? It seems to me that after you pick a door, it is labeled No. 1. After the host opens another door, it is labeled No. 3. Nothing is said about every door having it's own identity on beforehand. If that is true, I do not agree with these possible outcomes: ([12], [13], [21], [23], [31], [32]). So is there really a conditional restriction, or do we initially present more outcomes than possible anyway? This may seem strange, but I think it's the exact problem: if we cannot distinguish doors, we should see them as one possible outcome all together.Heptalogos (talk) 14:21, 11 February 2009 (UTC)

I don't think it matters when we label them. We're talking about three physical doors that have separate (constant) physical identities. If we want to prevent any possibility of the host's choice affecting anything, I suggested a version some time ago where after the player picks but before the host opens one of the other doors a curtain is dropped in front of the two unchosen doors. The host then, behind the curtain, opens one of them and leads a goat on to the stage from behind the curtain, and makes the offer to switch to the remaining closed (but hidden) door. There are any number of ways to turn it into an unconditional problem, but I think the essential "oh my god, how can it not be 50-50" aspect of it requires putting the player squarely in front of two doors, the one she initially picked and one more and then asking the "want to switch" question. I think this makes it inherently conditional. -- Rick Block (talk) 15:09, 11 February 2009 (UTC)

There are indeed three physical doors, but the problem has a natural symmetry. The doors can be described as the initial choice, the one the host opens, and the unopened one, there is no need to number them, in fact to do so hides a natural symmetry of the problem. Martin Hogbin (talk) 21:43, 11 February 2009 (UTC)

The curtain idea is nice, but not necessary, because there is actually only one property by which the player can distinguish door 2 from door 3, which is the fact that one is open (No. 3) and the other is closed. There is only an open door and a closed door, and the open door is always No. 3. Why do you assume that all three doors have separate physical identities? Or why do you even assume that the player notices the differences (which differences)? Heptalogos (talk) 15:23, 11 February 2009 (UTC)

I understand your point. On the other hand, I think it's fairly clear we're modeling this on physical reality - in which case the doors aren't simply abstract shields behind which we've hidden two abstract goats and an abstract car but real, physical doors which makes them distinguishable whether we label them or not (for example, if they're physical they have a physical location by which they can be distinguished even if they're not labeled). I'm not sure I've ever seen a published version of the problem that treats it as abstractly as you're suggesting. Have you seen one? -- Rick Block (talk) 16:02, 11 February 2009 (UTC)

There are indeed three physical doors, but the problem has a natural symmetry. The doors can be described as the initial choice, the one the host opens, and the unopened one, there is no need to number them, in fact to do so hides a natural symmetry of the problem. Martin Hogbin (talk) 21:43, 11 February 2009 (UTC)

The doors may be on moving platforms, thus having no location. We are inventing reality, even Morgan et al. There may indeed be a curtain in front of the doors, the player may be blind. When we use playing cards we even skip the doors, because we may understand that 'doors' are indeed abstract tools to limit our knowledge. We hide cars and goats by turning them around. The three doors may be lighting up one by one very quickly, which is stopped by the player hitting a button. He may be throwing balls at doors behind him. We only know that he picks a door, say No. 1, and the host, who knows what's behind the doors, opens another door, say No. 3. So the first door is surely identified after picking, and the second door is surely identified after opening. Morgan makes the mistake to ask for the host's strategy, creating realities around the facts. This is a mistake, because by experiment in every situation the host will open No. 3 revealing a goat, just that. Heptalogos (talk) 20:03, 11 February 2009 (UTC)

Very metaphysical. Again, are you aware of references that treat this problem in this manner? -- Rick Block (talk) 20:14, 11 February 2009 (UTC)

Please quote any metaphysical issue mentioned by me, in your interpretation. My approach may seem unusual to you, and others, but you'd rather react to the content instead of the shape. What is surely not physical is maths. As far as I know, the only references to this are mathematical references. Two things are not (exclusively) supervised by that discipline:

1. The translation of (supposedly) real situations into mathematical problems.

2. Logic itself.

Above I argumented that this problem really has two ways of approaching: logical and mathematical. It might even solve most of the disagreement here. Heptalogos (talk) 20:43, 11 February 2009 (UTC)

Btw, Devlin, a mathematician, uses the logical approach instead of the mathematical. This is the way I would like the main explanation in the article to be, understandable for everyone. Nijdam already wrote him to say he's wrong. :) We might introduce him here. Heptalogos (talk) 21:28, 11 February 2009 (UTC)

Devlin is already referenced in the article (in the "Combining Doors" section). The combining doors solution is another unconditional variant. Are you saying the first few sentences in the existing solution section are difficult to understand? Or are you only concerned about the part that starts "Although the reasoning above is correct ..."? -- Rick Block (talk) 03:36, 12 February 2009 (UTC)

The solution part now is a mixture of easy to understand logic and mathematical objections to that. I would suggest to make two solution sections. The simple one should be just logical. I like the graphics, but I do miss an explanation like "There are two doors you did not choose, and the probability that the prize is behind one of them is 2/3. I'll help you by using my knowledge of where the prize is to open one of those two doors to show you that it does not hide the prize. You can now take advantage of this additional information. Your choice of door A has a chance of 1 in 3 of being the winner. I have not changed that. But by eliminating door C, I have shown you that the probability that door B hides the prize is 2 in 3." Heptalogos (talk) 10:22, 12 February 2009 (UTC)

To support a point that I make above I ask people to answer this question:

A ball is chosen from a bag containing only red and white balls. What is the probability that it will be red?

Please answer the question as posed. Martin Hogbin (talk) 22:11, 11 February 2009 (UTC)

Unknown to me. Heptalogos (talk) 21:58, 11 February 2009 (UTC)

That is not an answer. Martin Hogbin (talk) 22:11, 11 February 2009 (UTC)

I suspect you are looking for an answer like: if R are red and W are white, R /(R+W) (assuming they're otherwise identical, and the bag is opaque, yada, yada, yada). -- Rick Block (talk) 01:16, 12 February 2009 (UTC)

That is unknown, because 'chosen' may mean that a red ball is always the target. Even if you replace 'chosen' by 'randomly chosen', what is a bag? Are all balls equal, apart from the color? One cannot strictly define chances for two things:

1. Single specific events.

2. Physical events.

If the source problem is physical, it should be translated to a similar mathematical problem. From then on, it's math discipline. Heptalogos (talk) 10:29, 12 February 2009 (UTC)

No not at all. As I understand it, according the usual rules of statistics, there is a numerical answer to the above question. I guess that it is now up to me to demonstrate that. Martin Hogbin (talk) 08:55, 12 February 2009 (UTC)

You're aiming at the answer 1/2. Probability is here to be understood as relative frequncy in all possible realisations of the experiment. The symmetry in the colours brings the answer. Nijdam (talk) 12:38, 12 February 2009 (UTC)

and, 1/2 in this case has the same mathematical meaning as Heptalogos's "unknown". -- Rick Block (talk) 14:21, 12 February 2009 (UTC)

Not really. If there were red, green, and blue balls the probabilty of choosing a red would be 1/3. Martin Hogbin (talk) 20:57, 12 February 2009 (UTC)

To the question, as posed, I believe that 0.5 is the correct answer. To say that I am aiming at that answer suggests that ther may be more than one answer. I think there is only one correct answer to my question and that it is 0.5. Are we all agreed on that or not? Martin Hogbin (talk) 20:26, 12 February 2009 (UTC)

No, I said deliberately 'aiming', because it's (again?) a matter of wording. It starts with what is meant by probability. It is good practice to interpret this as the relative frequency. Then the next question is, which experiment is to be repeated. Here it is also good practice to repeat the action of choosing and keeping the rest unchanged. So I could have assumed that the same bag i.e. with the same content, was used over and over after replacing the chosen ball. The next question is what is meant by 'a ball is chosen'. Nothing is said here about whether it would be a random choice. If the strategy would be to pick a red ball, and in the wording of the problem is stated there is at least one, the answer would be 1. In the 'random' case there is no numerical answer, only the formula Rick gave. Agree on this? Nijdam (talk) 21:36, 12 February 2009 (UTC)

'What is meant by probability'? Surely we are not meant to be discussing that here.

In addition, this problem obviously has the form of an urn problem, which is such a classical form that there is even an article here about it. I assume where you're going with this is that lacking other information, "random" is the best assumption and you'll proceed to argue that this means that in the Parade wording of the Monty Hall problem we should assume that the "random goat" constraint from the explicit wording is in effect. -- Rick Block (talk) 01:35, 13 February 2009 (UTC)

Yes exactly that. That is precisely what you should do. It is absolutely normal practice to take what we have no information about to be random, it is not something that I have just made up. Martin Hogbin (talk) 09:16, 13 February 2009 (UTC)

One will make necessary assumptions, and even best assumptions, if there is such a thing. The assumptions should create the missing sample space, but many times create a missing sample space. For every experiment we create like that, we can define the chances mathematically. Judging which physical problem fits into which experiment is not maths discipline. It's a statistician's good practice because he has to be pragmatic in some way. Heptalogos (talk) 14:17, 13 February 2009 (UTC)

This talk page is actually for talking about changes to the article, not for talking about the ins and outs of the Monty Hall problem or probability theory or the meaning of what a "bag" is. There are really only three legitimate topics for discussion here.

1) Things not in the article that should be added.

Suggest away. Please provide references in accordance with reliable sources and no original research. This article is already a Featured article and has had a fairly recent featured article review (May 2008) so the standard for its content is quite high (in particular, any significant point needs to have a high quality reference).

2) Things in the article that should be deleted.

Also, suggest away. The content is referenced, in detail, so if you're suggesting something be deleted please provide a reason.

3) Things in the article that should be changed.

Yet again, suggest away. This could range from minor wording changes (which I'd strongly suggest you just make, see WP:BOLD) to structural changes such as suggested above.

The 0.999... article has a subpage of its talk page called "Arguments", see Talk:0.999.../Arguments, and a FAQ. I've set up such a structure here, in the hopes that it might be helpful. If anyone wants to move a section they created here to that page, please go right ahead. I'd appreciate everyone's help in moving sections from here to there when it seems appropriate. Thanks. -- Rick Block (talk) 01:35, 13 February 2009 (UTC)

See Talk:Monty Hall problem/Arguments and Talk:Monty Hall problem/FAQ, both linked from the header at the top of this page. -- Rick Block (talk) 02:07, 13 February 2009 (UTC)

Yes, I would like to see the paragraphs in the Solutions section that says the first solution offered does not solve the Monty Hall Problem be removed. I believe is it not consistant with what the majority of the published references says.

I would also like to see the references to the minority point of view as espoused by Morgan et al moved out of the Solutions section.

I believe both of the changes are consistant with Wikipedia policy regarding regarding authoritative sources.

Rick, how will we know when it's proper to edit the Article? Would that be when a consensus is reached? Would any editors reserve a veto power?

Glkanter (talk) 02:19, 13 February 2009 (UTC)

Just to be clear, you're suggesting this specific content and the references (both Morgan and Gillman) be completely removed (correct?). It would be proper to remove these given a consensus on this page, where what is meant by consensus is described at WP:consensus. In the consensus process, all editors are equal to all other editors. Note it is not a vote, but a discussion where points raised for and against are considered. Given this content and these references are fairly long standing in this article and were added in response to a featured article review it would not be proper to remove them unless there is a strong consensus here.

Google Scholar (perhaps not the most authoritative citation index in the world, but it is at least a free one) says the Morgan paper is cited by 49 other works (see [3]), and the Gillman paper is cited by 30 other works, which says to me these are not simply crackpots. Deleting this content and these references, would leave the Solution section completely unreferenced as well. In my opinion, the article and this section in particular complies with Wikipedia:Make technical articles accessible (which, as it is included in the WP:MOS, is one of the criteria for being a Featured article) by presenting an easily understood solution followed by a more technically correct solution as described in the Morgan and Gillman references. For these reasons, I think this content should not be deleted.

Although not a veto, for consensus purposes unless you can address reasons raised to keep the content it would not be proper to make the deletion you suggest, regardless of how many editors agree with you (please see WP:NOTDEMOCRACY). -- Rick Block (talk) 03:15, 13 February 2009 (UTC)

I fell for it. I let him use the old 'rope-a-dope' on me. Next thing you know, instead of argueing about my proof, we'll be argueing about 'who is more mainstream', or 'what is prominant'.

Ricks comment about his veto power is not supported by the NOTDEMOCRACY paragraph. Basically, it's all give and take. And nobody 'Owns' the article.

Rick, are all editors equal, but some are more equal than others?

Glkanter (talk) 03:45, 13 February 2009 (UTC)

I fell for it. I let him use the old 'rope-a-dope' on me. Next thing you know, instead of argueing about my proof, we'll be argueing about 'who is more mainstream', or 'what is prominant'. We are not arguing about your proof. Your proof is WP:OR and of no relevance, no matter how correct it may be. Please realise that. Leaving out the hyperbole would be helpful. To comment on the principles: no, this is not a democracy, yes all have the same potential to contribute, no Rick doesn't have a veto, no Rick did not say that he had a veto, no the argument that the content has been in place for ages is not a compelling reason to keep it William M. Connolley (talk) 08:31, 13 February 2009 (UTC)

I guess I'll have to understand and follow Wikipedia protocol if I'm going to be successful in ending Rick's Ownership of this Article. This is from Wikipedia:Ownership of articles:

If the ownership behavior persists after a discussion, dispute resolution may be necessary, but at least one will be on record as having attempted to solve the problem directly with the primary editor.

http://en.wikipedia.org/wiki/Wikipedia:Ownership_of_articles

Rick, as you are aware, I believe you have improperly taken ownership of the Monty Hall Problem article to the detriment of the article. I estimate this has been the case for nearly 4 years. I would like to find a solution to this, in order that I, and others could edit the article, without fear of either your veto, or entering into a reversion war.

I lay out my reasoning beginning with my post of 17:35, 12 February 2009 (UTC), which comes in the section title Conventional Wisdom.

I look forward to your response to this serious issue.

Thank you Glkanter (talk) 07:36, 13 February 2009 (UTC)

I emphatically deny that there is an ownership issue. I have never claimed I own this article, have never edit warred over content, and, if you check the history you'll see numerous editors have contributed content. I have done my level best over many days now to help you understand why the change you seek won't happen. Your response has been a continuing stream of personal attacks and incivilities, including your own personal rant section above. There is definitely a problem here, but it is not ownership. -- Rick Block (talk) 08:50, 13 February 2009 (UTC)

"I have done my level best over many days now to help you understand why the change you seek won't happen" (The Dictator aka Rick Block, 2009) '

This to me implies that "Rick block" actually belives that he can decide by himself what changes should be made to the Monty hall article !!!! Rick Block should decide everything and if someone does anything that "Rick Block" does not like then "Rick Block" is going to mobilize enough support to force such a person out of the game by telling people to revert any changes to the article. Abuse and Bullying on a higher level !! Definitely ownership with capitalized 0 --92.41.74.138 (talk) 21:36, 13 February 2009 (UTC)

William M. Connolley if you remove my comment another time (just cause you cant stand the truth) I will remove ALL your comments  :-) --92.41.74.138 (talk) 21:36, 13 February 2009 (UTC)

There is another source of unnecessary complication introduced by the academic papers on this subject and it is this:

The Parade statement is clearly written from the point of view of the player, 'Suppose you're on a game show...What is your advice?'. The questioner is obviously asking for advice as to what they should do if they were a contestant on the show.

Some academics, however, have reformulated the question from the perspective of some imaginary third party. Someone who may know, for example, that the host has a preference for a particular door. This is something that the player does not know.

As a result of this reformulation, there have been countless arguments on this page over whether it matters if the player knows about the host's preferences. This reformulation is a major obstacle to understanding the solution. Martin Hogbin (talk) 09:30, 13 February 2009 (UTC)

Generally speaking you're right. There are many variants, involving those where the player doesn't know the rules etc. But let us stick to the problem stated in the article. There it says: these are the rules, and I suppose it means the player knows them. Even this quite restricted version brings so much confusion. Actually also Marilyn, yes she, gave the "simple explanation", and being attacked for it, and of course realizing she was wrong, tried in all possible ways to interpret the problem in such a way that she wouldn't have to admit it. Nijdam (talk) 09:46, 13 February 2009 (UTC)

I mentioned this several times. If 'we' define the chances, no player and no host have to know anything; it's all in their behaviour which is simply described. The same mistake is made describing a host who knows where the car is. It doesn't matter what he knows, as long as he does this or that. We are all inventing and assuming realities, but it all comes down to the same issue again: the specific physical problem should firstly be described as a statistical experiment or reality, which can then be translated to maths. Heptalogos (talk) 13:35, 13 February 2009 (UTC)

Martin - is this thread about the article, or about underlying mathematical issues relating to the problem? If the latter, please relocate this thread to the /Arguments subpage. Thank you. -- Rick Block (talk) 15:01, 13 February 2009 (UTC)

It is about how to improve the article, which is the purpose of this page. You know my position, which is that the concentration on certain academic papers serves only to introduce unnecessary complications, obfuscate the central and notable problem, and confuse the reader. One way in which those papers confuse the issue is by changing the viewpoint from that of the contestant (as it is in the well known Parade statement of the problem) to that of a third party observer. Martin Hogbin (talk) 20:14, 13 February 2009 (UTC)

I have an alternate suggestion regarding the conditional vs. unconditional question that keeps coming up. How about if we add a more comprehensive discussion about this, perhaps like the following (a slightly edited version of an explanation I originally posted above that might have been buried before many people noticed it). If we don't add it to the article, I suggest that it be included in the FAQ linked at the top of this page. The wording may not be quite Featured Article quality, but I think it is close. -- Rick Block (talk) 05:28, 14 February 2009 (UTC)

Please comment in the appropriate subsection below, #Why we should or should not add this content, #Does the suggested wording fairly summarize what these articles say, or #I don't think they're correct. -- Rick Block (talk) 19:24, 14 February 2009 (UTC)

Feel free to try to improve the wording as well. -- Rick Block (talk) 19:32, 14 February 2009 (UTC)

Suggested wording

Morgan et al. and Gillman claim the Monty Hall problem must be solved as a conditional probability problem. As usually stated, the problem asks about a player who has picked a door and can see which of the remaining two doors the host opens in response, and is then given the opportunity to switch doors. The question pertains not to all players in general, but only to the subset of players who have picked a door (for example door 1) and then have seen the host open a different door (for example door 3). The point concerns the difference between

${\displaystyle P({\text{win by switching}})\,}$

and

${\displaystyle P({\text{win by switching}}|{\text{player picks door 1 and host opens door 3}})\,}$

${\displaystyle P({\text{win by switching}})\,}$ is the unconditional probability of winning by switching. It is roughly what fraction of all players who play the game will win by switching. Gillman suggests this would be the probability of interest in a revised version of the problem where "you need to announce before a door has been opened whether you plan to switch." [italics in the original!]

${\displaystyle P({\text{win by switching}}|{\text{player picks door 1 and host opens door 3}})\,}$ is the conditional probability of winning by switching given that the player initially picked door 1 and the host has opened door 3. It is roughly what fraction of all players who pick door 1 and see the host open door 3 will win by switching.

These are different questions which may or may not have the same numeric answer. As usually stated, Morgan et al. and Gillman both say the Monty Hall problem asks the conditional question, not the unconditional one.

An unconditional solution such as "a player has a 2/3 chance of initially picking a goat, all of these players who switch win the car, so 2/3 of all players who switch will win the car" correctly answers the unconditional question, but doesn't necessarily say anything about the conditional problem. For example, this solution says the answer for both the Parade version and the Krauss and Wang version of the Monty Hall problem is 2/3. The Morgan and Gillman papers both introduce a different variant, identical to the Krauss and Wang version except instead of

If both remaining doors have goats behind them, he chooses one randomly

they specify

If both remaining doors have goats behind them, he chooses the leftmost door

In this variant, an unconditional solution also correctly answers the unconditional question. The player still has a 2/3 chance of initially picking a goat, and in this case the host must reveal the other goat, so the solution above still applies and 2/3 of all players who switch will win the car. However, in this variant, if the player initially picks door 1 and the host opens door 3 the player knows the car is behind door 2 and has a 100% probability of winning by switching. If the player initially picks door 1 and the host opens door 2, either the player's initial pick was the car (a 1/3 chance) or the car is behind door 3 (also a 1/3 chance). This means, given that the host has opened door 2, the player's chance of winning by switching is 1/2. The point of introducing this variant is to show the difference between the unconditional and conditional questions. In this variant, these questions have different answers exposing the difference between unconditional and conditional solutions.

Using an unconditional solution produces the correct answer for the more exact Monty Hall problem as stated by Krauss and Wang, but this is in effect a coincidence. The problem with the approach is hidden because in this version the conditional and unconditional answers are the same. Applying the same solution to a variant where the unconditional and conditional solutions are different, like the "leftmost door variant", reveals the problem.

This is exactly the same as responding to the question "what is 2²?" by saying "2 plus 2 is 4, the answer is 4". This is the right answer, and a true statement, and related to the right reasoning, but not actually right. This wrong reasoning can be exposed by asking, "what is 3³?" Similarly, the problem with using an unconditional solution to answer the Monty Hall problem can be exposed by asking about a slightly different variant, where the wrong reasoning produces the wrong answer.

Initial reactions from Glkanter, Martin Hogbin, Heptalogos, and 92.41.236.242

I think it's perfect. Long overdue. I've always said, "What the Monty Hall Problem article needs is another 5,042 bytes dedicated to Morgan, including the final three paragraphs which refer to no references or footnotes." What's the word for that? Come on, someone help me. Oh, right! It's called Original Research! Us Wikipedians are Big Fans of OR.

Oh, wait. No mention of the 'random goat door constraint'. The Rosetta Stone of the MHP. Sorry, back to the drawingboard.

Glkanter (talk)

Glkanter (talk) 06:13, 14 February 2009 (UTC)

I do not accept that the problem is necessarily conditional, and I have given reasons why. Boris Tsirelson put it like this, ' who said I'd say that in this case they are equal not just by a numeric coincidence. Rather, the conditional probability (treated as another random variable) is constant (a degenerate random variable) in this case, due to an obvious symmetry. Taking into account the total probability formula we conclude that the conditional probability must be equal to the unconditional probability in this case'. Martin Hogbin (talk) 09:23, 14 February 2009 (UTC)

Exactly! Thank you! There is no reason why the Monty Hall problem should be conditional! A simple unconditional solution is the best solution! This will also limit "Rick Block" abilty to introduce NOISE inorder for him to increases his leverage to make sure that no one understand anything (included himself) by OVER COMPLICATING THINGS)! --92.41.236.242 (talk) 12:37, 14 February 2009 (UTC)

Would it be fair to infer that the the next sentence from Boris Tsirelson would be 'In this case then, one may, by proving the (easier) unconditional probability, also prove the conditional probability?' Glkanter (talk) 11:27, 14 February 2009 (UTC)

What is the mathematical rule for a problem 'being' conditional? Heptalogos (talk) 12:41, 14 February 2009 (UTC)

Interesting position, Martin. How do you reconcile it with WP:BECAUSE-MORGAN-SAID-SO?

Glkanter (talk) 10:10, 14 February 2009 (UTC)

So, how does this work in practice? There's no vote taking, and consensus doesn't necessarily rule the day. But Rick can still change his article, right? Glkanter (talk) 10:14, 14 February 2009 (UTC)

Yes he can! and from "Rick Blocks" perspective as long as he agree with the change then consensus has been reached, ha ha !! It is like the fucking wild west !! The thing is even though we would agree that an unconditional solution (consensus, as of now 4 against 1 in favor for an unconditional solution) is the best way forward then I promise you that anal "Rick Block" is going to enter into an edit war by mobilizing his "I want to become an administrator" grupies.........--92.41.236.242 (talk) 12:52, 14 February 2009 (UTC)

Actually I think we now should change the conditional solution to an unconditional one. Concensus has been reached (4 against 1)

Glkanter, Heptalogos, Martin Hogbin and 92.41.236.242 against "Rick Block" which means that the unconditional solution is the winner

What do you want to include in the unconditional solution guys? --92.41.236.242 (talk) 12:52, 14 February 2009 (UTC)

To help structure this discussion, I'm adding subsections. Please stay on topic within the subsections. -- Rick Block (talk) 18:18, 14 February 2009 (UTC)

Why we should or should not add this content

The reason I am suggesting adding this content is because the basic point made in these two papers is clearly not widely understood. If the article includes a comprehensive discussion of what they say, the wording can be improved by anyone who may be able to express the point better. We should not add the content if the point is insignificant, or mathematically discredited. It is my belief that these two papers, nearly simultaneously published (Morgan et al. was first by 2 months), are the first mathematically rigorous treatments of the Monty Hall problem which makes them crucial to include in this article. I also believe these papers were published specifically in response to the nationwide furor over this problem that followed the Parade articles published in 1990-1991. The Morgan et al. paper is cited 49 times according to Google scholar. The Gillman paper is cited 30 times. As far as I know, the central point they make is not reflected in non-academic literature, but this doesn't mean we shouldn't include what they say. -- Rick Block (talk) 18:18, 14 February 2009 (UTC)

I am not thoroughly against the conditional solution. I think that in fact there are two problems:

We have the simple, fully defined, problem that is a direct equivalent to the three prisoners problem in which the host acts simply as the agent of chance. For the reasons given by myself and Boris Tsirelson this is not a conditional problem. From what I can see from the free bit, even Morgan et al do not claim that it is. This problem, in my opinion is the most interesting and notable one in that it is a simple problem that most people get wrong. This problem is obviously not very well covered in peer reviewed journals because it is a simple probability problem whose solution has been well understood for years.

The second problem is the real world one concerning a contestant on a TV game show. In this the problem is very poorly defined. What does the contestant want? What outcome do the TV company want? How will the host act? What things could possible happen? and many more. This is the problem that has been addressed by many published papers. It is a conditional problem and it is very complicated but in my opinion it is not very interesting or notable. It is a complicated probability and psychology problem that has no clear answer and which experts have argued about for years.

So what I would like is to have more on the 'basic', paradoxical problem. In particular a solution that will convince readers of its correctness. I have no desire to get rid of the, academic conditional problem, leave it there for those who are interested but I am convinced that this article fails its readers in that it does not give a clear enough answer to the 'basic' problem. It is not that the published papers are wrong, just that they, obviously, do not cover the basic , interesting and notable unconditional problem

I have made some changes, see above, and let me know what you think. I appreciate that this article is a FA and accept the we should not go bashing it about. Let us all try to work together to improve the article. Martin Hogbin (talk) 18:34, 14 February 2009 (UTC)

You started by saying the fully defined problem is directly equivalent to the 3 prisoners problem. This is somehow contradictory to your opposition to accept that it is about conditional probability. The 3 prisoners problem is! Nijdam (talk) 21:10, 14 February 2009 (UTC)

Does the suggested wording fairly summarize what these articles say

If you think the suggested wording doesn't fairly summarize what the papers are saying, please say how or where (the analogy at the very end is original, but everything else is directly from the papers). The papers are short, but I could add references to specific paragraphs if that would help. A point they both make, not in the proposed wording above, is that viewing the problem as a conditional probability problem means the Parade version of the problem lacks a condition necessary to justify the 2/3 answer. Specifically, they BOTH mention this version does not say the host picks between two goat doors randomly. BOTH of these papers make this point, and provide a solution where the host's preference for one door or another is left as a variable q. They BOTH show the probability of winning by switching is then in the range of .5 to 1, exactly equal to 1/(1+q). I think this additional point should likely be added as well, but first things first. -- Rick Block (talk) 18:18, 14 February 2009 (UTC)

I don't think they're correct

Arguing that what these papers say is wrong in a mathematical sense has no bearing on whether the content should be included or not. If you would like to discuss the points they make, please post at /Arguments or Wikipedia:Reference desk/Mathematics. -- Rick Block (talk) 18:18, 14 February 2009 (UTC)

I, for one, am not arguing this. I am now becoming more and more convinced that there are two Monty Hall problems. The simple one, and the complicated one (which could be treated as several). My point would now be that the published statistical papers are not about the simple problem, although they do mention it in passing, but they cannot comment about it in detail because there is nothing new to say. There clearly is a simple version of the problem, as insisted on by vos Savant. So the statistical papers on the problem are not wrong but irrelevant to the simple problem. There is one other issue that academics do cover, which is why people get the simple problem wrong. Perhaps more on that would be interesting.

I think making the two versions of the problem clear in the article might prevent a lot of argument. Martin Hogbin (talk) 20:34, 14 February 2009 (UTC)

Rick thanks for making the players plural in my recent addition. I agree that is is a better mathematical representation and it is more PC.

I have restored the emphasis on 'always' to indicate that there is no doubt, uncertainty, or probability other than 1 for a swap to change a car to a goat and a goat to a car. I think this needs to be spelled out to the reader so that there are no lingering doubts. I was going to add either a footnote or a picture to make this absolutely clear. What do you think.

I have also put back the probabilities of swappers and non-swappers getting a goat. You may consider this obvious and superfluous but to a newcomer to the problem this may not be so. Martin Hogbin (talk) 09:05, 14 February 2009 (UTC)

Thinking about this some more, I am not sure that this solution should even be in the lead section, which is meant to be a summary of the article as a whole. Would it be better to make a very brief reference in the lead and move this explanation into the start of the 'solution' section, maybe with pictures? What we have now (and had before) is one simple solution in the lead and a different one in the body. Martin Hogbin (talk) 17:14, 14 February 2009 (UTC)

I agree with your reasoning here, although I (still) don't understand how what you're suggesting adding to the start of the Solution section is different from what is already there. -- Rick Block (talk) 18:47, 14 February 2009 (UTC)

I guess that it is just the way it is written and presented. I understand that it is done the way that it is to lead in to to a discussion of the 'academic' problem but I think this just spoils it simplicity of the solution. Can we agree that there are two problems - see above. Martin Hogbin (talk) 19:09, 14 February 2009 (UTC)

I agree there are two problems, however the conditional/unconditional distinction pertains to both. Lots of people get the "simple" (not the real world) version of the problem wrong (and say switching does not matter). They're told, "Well, you see, it's like this - you have a 2/3 chance of initially picking a goat, if you switch you get the other thing, so if you switch you get the car. Understand?" OK. Got it. Then vos Savant publishes the "host forgets" variant. Now what? You still have a 2/3 initial chance of picking a goat. Switching still inverts your initial choice. But now you have a 1/2 chance of winning by switching? WTF? The issue is these are BOTH conditional probability problems, and if you approach them both this way you get the right answer both times. IMO (and, to be clear, this is only my opinion) encouraging an unconditional approach for the "standard" variant is doing the public a disservice. -- Rick Block (talk) 20:37, 14 February 2009 (UTC)

I think you are wrong. There are many variants which must be conditional but the simple problem need not be. Any problem can be made superficially conditional by picking an event that occurred during it and making it a condition. But if that event cannot in any way possibly affect the outcome then it is a null condition, a irrelevant condition, basically not a condition at all. The fact that the conditional and unconditional solutions to the MH problem have the same value is not a coincidence 'the conditional probability (treated as another random variable) is constant (a degenerate random variable) in this case, due to an obvious symmetry', as Boris, who seems to know about these things, puts it. I am not sure that even Morgan et al claim that the basic problem is necessarily conditional. I do agree, however, that all sorts of, apparently minor, changes to the problem can make it necessarily conditional but the 'basic' problem does not need to be treated that way any more than the 'three prisoners problem' does. Martin Hogbin (talk) 21:09, 14 February 2009 (UTC)

Correction - I have just checked Morgan and they do claim the basic problem should be treated as conditional. Martin Hogbin (talk) 23:32, 14 February 2009 (UTC)

Yes, but they seem to take it for granted. There's no explanation. It's one of the disadvantages discussing within a small group of people who agree in the first place; there is no stimulus to think in any other way. And let us not forget that they spent something like "a whole afternoon" at this problem. We know how much that is. Heptalogos (talk) 10:13, 15 February 2009 (UTC)

I was not supporting Morgan in any way, just admitting a factual error in what I had said above. I agree with you, the Morgan paper is just an exercise in arrogance. Martin Hogbin (talk) 23:47, 15 February 2009 (UTC)

Quote: "But if that event cannot in any way possibly affect the outcome then it is a null condition". Martin, which rule says so? Heptalogos (talk) 22:02, 14 February 2009 (UTC)

Sorry Heptalogos, you are right. I meant, but did not say, outcome of the probability calculation, not physical outcome of the show.

If not, the why should not everything that happened between the players initial choice and his decision whether to swap or be treated as a condition. What is it that makes the opening of a door to reveal a goat a condition? Martin Hogbin (talk) 23:32, 14 February 2009 (UTC)

To explain further. Why do we ask, 'What is the probability of getting a car, given that the host has opened a door to reveal a goat?', but we do no ask, 'What is the probability of getting a car, given that the host has said the word "pick" to the player?'? In formulating any problem we have to decide what the significant conditions are, in other words define our sample space. This is not automatically done for us, it is our choice. Martin Hogbin (talk) 10:02, 15 February 2009 (UTC)

Not everything that happens reduces the sample space, like the word "pick". Opening a door with a goat does. So this could be a significant condition? Heptalogos (talk) 10:05, 15 February 2009 (UTC)

Why? How does one decide what to take into account? Martin Hogbin (talk) 10:36, 15 February 2009 (UTC)

What to take in account: every given event that reduces the sample space? Why: because it's a rule of conditional probability cq statistical dependency? Heptalogos (talk) 11:01, 15 February 2009 (UTC)

But, to be perverse, use of the word 'pick' might do just that. The host might, for example use the word 'pick' when he knows that you have chosen a car and the word 'choose' when he knows that you have chosen a goat. My point, which I think that you agree with, is that what might be a condition is more a matter for imagination than mathematics. (Also see my added comment above) Martin Hogbin (talk) 23:36, 15 February 2009 (UTC)

I do agree with you, and actually I was hoping for you to say that 'reducing sample space' is not a rule for conditional probability, but 'affecting probabilities' is. Somehow nobody reacts to that statement. Can you please, on the Arguments page? Heptalogos (talk) 10:50, 16 February 2009 (UTC)

Have you guys had a chance to see my newest solution (it's not a 'proof', after all)? If I'm right, it shows the unconditional solution solves the conditional problem. And, I won't quote anybody here, but if you follow my 'contribs', you will find an editor-of-apparent-authority saying that the solution is a valid unconditional proof of the MHP. All that would remain is to find a published source, which, since it's right, must be out there. But, see for yourself. Make your own judgements... Glkanter (talk) 12:37, 15 February 2009 (UTC)

Where is your newest solution? You'd better ask your question there. Heptalogos (talk) 13:11, 15 February 2009 (UTC)

I've copied it from near the end of the Conventional Wisdom section.

1/3 of the time I will pick a car.

Since 1 - 1/3 = 2/3, 2/3 of the time I will not pick a car.

I increase my likelihood of winning by switching.

Note that it has no Monty, and no goats. Un-conditional! And please, since I'm currently being accused of mis-representing other editors' statements, please follow my 'contribs' from roughly 16:53, 14 February 2009 for what looks to me like unqualified (that is, without reservation), corroboration. Glkanter (talk) 13:26, 15 February 2009 (UTC)

This is the suggested unconditional solution. Feal free to make any improvments to the layout etc. This is the best I could do.--92.41.74.110 (talk) 21:03, 14 February 2009 (UTC)

There are three doors. Two doors have a goat behind them and one door has a car behind.
(Remember goat is bad and car is good)

1) Choose one door
2) Game host opens one door containing a goat
3) Do you change door?

For example:

Door 1	Door 2	Door 3
Goat	Goat	Car

>>>>The example is not complete, because it doesn't tell which door is chosen and which one is opened. Nijdam (talk) 21:13, 14 February 2009 (UTC)

>>>> Your initial door pick does not affect your probability of success. You have now way of knowing where the car is so your best guest is a random coin toss which means that the actual door chosen is not relevant.--92.41.74.110 (talk) 23:37, 14 February 2009 (UTC)

In the definition of the problem door 1 has been picked and door 3 has been opened. You should use that information. I presented such a solution below, based on yours. Heptalogos (talk) 12:52, 15 February 2009 (UTC)

Now you have two opions: Not switch or Switch

Not switch

pick	show	outcome
1	2	lose
2	1	lose
3	2 or 1	win

If you do not switch the probability of winning is 1/3

Switch

pick	show	outcome
1	2	win
2	1	win
3	2 or 1	lose

If you switch the probability of winning is 2/3

You should therefore choose to switch doors 92.41.74.110 (talk) 21:03, 14 February 2009 (UTC)

That is indeed the unconditional solution for the situation in which no door has been chosen/opened yet. But the options 'pick' and 'show' are perfect! Here's the unconditional solution for the exact problem:

Switch

pick (No. 1)	show (No. 3)	outcome
car (1/3)	goat (1)	lose (1/3)
goat (2/3)	goat (1)	win (2/3)

The chances are between brackets. The difference is that the doors aren't numbered on beforehand. Heptalogos (talk) 21:48, 14 February 2009 (UTC)

It's one thing to mention the "chances" as you called them, another is what there meaning is and where they come from. Hopefully this leads you to finally understand that what you called "chances" here, are the conditional probabilities. How else could door No. 3 have "chance" 1 to reveal a goat, whence the (unconditional) probability of having a goat behind it, is 2/3? Nijdam (talk) 13:29, 15 February 2009 (UTC)

There is no unconditional probability less than 1 of having a goat behind door No. 3. You are inventing this unreality yourself. Door No. 3 has a goat per definition, per condition. This condition is similar to any precondition used in any 'unconditional' probability. Heptalogos (talk) 13:36, 15 February 2009 (UTC)

Do you suggest the goat is always placed behind door No 3?? Do me a favour and keep out of discussions you clearly don't have the slightest idea what they are about! Nijdam (talk) 17:44, 15 February 2009 (UTC)

As I told you before, you should get rid of your assumption that there is a door which is labeled No. 3 even before cars and goats are placed. All we know is that it is labeled No. 3 after it is opened. Hence, the opened door is always No. 3. When does this possibly arrive at your comprehension? Gimme a sign. However, you even use this information in your 'Probabalistic analysis' on the arguments page and that's very well done Nijdam. You were called Bert after you were born, right? It's really to prevent people from having to say "the guy born Nijdam in the night that turned all chances" all the time. What's in a name, amigo. Heptalogos (talk) 20:22, 15 February 2009 (UTC)

Dash it, if you would have secretly switched places with your brother, he would have been called that! ;) Heptalogos (talk) 20:29, 15 February 2009 (UTC)

I don't know what the meaning is of this 'Bert' stuff. May be you're watching way too much Sesam Street, I at least don't see any connection with the discussion. And you may persist in thinking the doors are not labelled, why not, you may even think there are no doors at all. Or 3 doors and 7 little goats and a wolf, or prince William and his girlfriend behind one door and his grand grand uncle behind the curtains. If it makes you feel better, please do. Nijdam (talk) 17:56, 16 February 2009 (UTC)

Rick went to http://en.wikipedia.org/wiki/Wikipedia_talk:WikiProject_Mathematics today to drum up support for his proposed changes.

I followed him by informing them of my allegations of Ownership by Rick. I suggested that today's behaviour alone shows this problem. Glkanter (talk) 22:21, 14 February 2009 (UTC)

Above you claimed that the project members have verified Rick's supposed ownership issue ("All these other Wikipedia Math gurus already knew about Rick's MHP article Ownership issues!"). That is false. We are all familiar with Rick and this article. What we are familiar with is that occasionally people unable to understand simple probability come to this article, argue for ages on the talk page, and accuse Rick of a bunch of stuff. Then he argues and discusses in good faith with the person, very patiently and correctly, while enduring a verbal assault. --C S (talk) 03:23, 15 February 2009 (UTC)

I just posted this exact post at the Math page:

This is the original post from the Monty Hall Problem talk page, verbatim:

Here's where Rick first asked for assistance to aid in Resolving our Conflict.

http://en.wikipedia.org/wiki/Wikipedia_talk:WikiProject_Mathematics

All these other Wikipedia Math gurus already knew about Rick's MHP article Ownership issues!

I'm a first-timer here. It's been way too long, but is has been instructive as to how horribly mishapen things get when an editor claims ownership of an article.

Glkanter (talk) 19:25, 12 February 2009 (UTC)

You are 100% correct. Two days ago, before I ever brought the topic of Ownership to your attention, I was guilty of pre-judging you all. I apologize for that. When I took a leap from your being aware of Rick's fondness for the Article, to the conclusion that you would therefore have already identified a WP:Ownership situation, that was wrong on my part. I'll post my apology on the MHP talk page immediately. Glkanter (talk) 03:41, 15 February 2009 (UTC)

-end of exact post

Does your past experience excuse you from researching this claim, but still commenting on it? Have you asked among the other respected editors who regularly post here for their opinions? Or done your own readings recently? Glkanter (talk) 03:53, 15 February 2009 (UTC)

Have you stopped beating your wife? Your presumptions are arrogant. I am familiar with all past discussion on this page and related discussions on the WikiProject Mathematics talk page. I saw nothing new in what is going on in this current discussion, and yes, I did read through this whole page before making my comment. It's the same thing again. I have noticed no disagreement of my assessment versus others in the WikiProject. --C S (talk) 04:34, 15 February 2009 (UTC)

Rick proposed a major addition to the article today. Just hours after about 4 of us were discussing the merits of a 'formal' proposal for deleting stuff. Then he goes to your page to drum up support. What's up with that? Who's stirring the pot? Who's not showing good sense? I know of one highly respected math editor who today described 'the discussion is so turbulent'. And Rick proposes a major addition that he flat-out knows his primary critic is dead-set against? No. That's not normal.

Here's a probability: if you don't look into it, you will not find what I'm describing. However, If you look, you might find I'm right. Glkanter (talk) 04:54, 15 February 2009 (UTC)

Since you like to misrepresent Boris' quotes, perhaps we could press him on whether the turbulence is caused by your refusal/inability to understand basic probability. --C S (talk) 05:12, 15 February 2009 (UTC)

Nice. Blame the innocent editor who's trying to play by the rules. And such a professorial tone. Rick complained about my civility. You are way beyond the customs of the past 4 months on this talk page. Don't the rules apply to you? Glkanter (talk) 13:07, 15 February 2009 (UTC)

And you knew that your smear was false. Because I didn't say it. Why not include a link? So you either intentionally smeared my good name, or you were careless with your research and accusation. Look, if you're not going to be part of the solution, you are part of the problem. Glkanter (talk) 19:11, 15 February 2009 (UTC)

You might even ask me if I have any documentation to support my claim. Glkanter (talk) 05:04, 15 February 2009 (UTC)

What documentation is relevant to your lack of mathematical understanding? --C S (talk) 05:12, 15 February 2009 (UTC)

With your question, are you arguing that being 'Right' is germain to the discussion of whether to edit the article? Have you seen my newest proof? Seen the corroborating unambiguous opinion? Nice civility, again. Glkanter (talk) 13:07, 15 February 2009 (UTC)

Here's a pretty interesting exchange relating to my 'being reported' by Rick at the bottom of Rick's talk page. He writes this:

There's a current crowd (Glkanter is one of them) unhappy with the Morgan et al. approach who want it removed, commenting on the talk page to gain consensus for their desired change. I guess rather than convince them I could just let them know they will never gain consensus for this change. -- Rick Block (talk) 12:23, 11 February 2009 (UTC)

The only 'evidence' of my WP:Ownership claim I will find will be Rick's own words and actions. Re-read the above paragraph. Is there a problem with concensus building among editors? He says, "I could just let them know they will never gain consensus for this change." I'm telling you, this isn't right. Glkanter (talk) 05:24, 15 February 2009 (UTC)

I don't think your understanding of the statement you quote assumes good faith. By its plain language, the statement you object to is a prediction that consensus for your change is not going to arise. Right or wrong as it may be, Rick is offering this prediction as a reasoned guess based on his experience with the editors of this article, and which kinds of edit ordinarily seem to achieve consensus. Do you have any particular reason to believe that this prediction actually masks an intent to forbid such a consensus from forming (assuming, arguendo, that this was within Rick's powers)? –Henning Makholm 05:41, 15 February 2009 (UTC)

Without question, I am reading into it that Rick is stating that he will not allow it. I refer to it as his 'veto' power. And, it could be interpreted that there exists a consensus for some changes contrary to Rick's wishes. But I'll let the other editor's recent and future edits speak for themselves. Glkanter (talk) 05:49, 15 February 2009 (UTC)

On which evidence do you base this assumption of bad faith, particularly given that a good-faith interpretation of the statement is readily available (that being the straightforward English meaning of what he said)? –Henning Makholm 05:53, 15 February 2009 (UTC)

Get your facts straight. I was not responsible for the previously discussed quote attributed to Boris.

And now you've accused me of being a wife-beater and mis-representing Boris' quotes. Both lies. Forget it. I do not need help like yours. Glkanter (talk) 05:30, 15 February 2009 (UTC)

LOL. Wife-beater comment was in response to your own wife-beater style question. I'm not here to help you push your ignorant points or false accusations either. Misrepresentation of quotes? Maybe I see it that way because I'm more familiar with his style of comment, whereas you want to read any nuanced, non-committal response as being in your favor. Like I said, if you believe your repeated quoting of him is justified, we can always ask him to clarify.

As for Rick's supposedly damning words, he's merely stating the obvious. Ignorant people come by Wikipedia articles all the time, trying to change article to crap. Usually they don't try that on a Featured Article. In any event, doing so is just going to fail. Rick is correct. You are so wrong you don't even know why you aren't going to garner any consensus. A less patient editor than Rick wouldn't have even bothered wasting all this time on you. --C S (talk) 05:47, 15 February 2009 (UTC)

This is 2009. In the United States, anyway, wife-beating is not generally associated with 'LOL'. I would refer you, at last, to WP:Incivility. Glkanter (talk) 13:07, 15 February 2009 (UTC)

If you're going to be dense about my reference to a standard loaded question, there's nothing I can do to help you. Learn what a loaded question is and not to use them, like you did before. --C S (talk) 15:58, 15 February 2009 (UTC)

As the former leader of the free world once said, 'Fool me once, <pause>, uh, shame on you. Fool me again...won't get fooled again!'

I fell for the 'rope-a-dope' a second time! Turns out in C S's case, my apology was unnecessary. He, at least, had already made up his mind. Hostile mother.

And don't be coy. Tell me why I am 'so wrong you don't even know why you aren't going to garner any consensus.' I'll change my posting techniques if it's futile. Just tell me the rules. Glkanter (talk) 13:07, 15 February 2009 (UTC)

As Will Connelly pointed out to Rick Block, further discussion is pointless. You have no idea what you're arguing about, and you can't even understand expert comments you solicit, instead you misinterpret them as justifying your ignorant comments. Like it or not, I am a 3rd party subject matter expert. And I clearly see you have no idea what you're going on about, nor have you even bothered to understand any of Rick Block's points. He has given more than enough explanation. There are no "rules" here that will make you right. --C S (talk) 15:58, 15 February 2009 (UTC)

Apparently it's valid for you to interpret other editors' postings to fit your POV, but not appropriate for me to do so. Which rule book do you have that I don't have. Because William Connelly said nothing of the sort. How about a link? Where does William Connelly's 'opinion' end in that paragraph directly above, and where does your's begin? Glkanter (talk) 19:11, 15 February 2009 (UTC)

I am referring to [4] where Connelly does in fact tell Block there is no reason to continue discussion. So how am I interpreting other editors' postings to fit my POV? You've been doing that, so you seem to feel it's a good tactic to accuse me of kind, but I'd like to see a single example. By the way, you like to accuse people of breaking WP:CIV (apparently partly based on your inability to understand English idiom), but you know, stopping a comment short like "Hostile mother" doesn't fool anyone. Consider this an NPA warning and tone down your language in the future.

The article says:

The host opens a known door with probability p, unless the car is behind it (Morgan et al. 1991).

If the host opens his "usual" door, switching wins with probability 1/(1+p). If the host opens the other remaining door, switching wins with probability p/(1+p).

The latter formula cannot be correct. In the extreme case, set p=1 and assume that the host does not open his usual door. This can only have been because the car is behind the usual door, so switching in this case wins with certainty. However p/(1+p) is only 50%.

According to my own analysis, the 1/(1+p) is correct, but the other formula should be 1/(2–p). (It is okay for the two probabilities not to add up to 1; conditional probabilities under mutually exclusive conditions have no necessary relation).

Is this an error in the source, in the reporting of it here, or in my understanding of what the behavior is supposed to be? –Henning Makholm –Henning Makholm 04:46, 15 February 2009 (UTC)

I think this situation needs to be hammered down more precisely. In the Morgan et al article, the situation considered is when door 1 is picked; host will always open a door, and always one without a car behind it; avoiding contradicting previous assumption, he opens door 2 with probability p and door 3 with probability 1-p. Then they arrive at your formulae.--C S (talk) 05:36, 15 February 2009 (UTC)

OK. I have tries to edit the description accordingly. It is not particularly elegant, though -- feel free to simplify the language if you can. An interesting observation here is that (a) it is never a disadvantage to switch no matter which door and what p; (b) the "always switch" still wins with probability 2/3, independently of p; (c) therefore the assumption that Monty flips a fair coin if he has a choice is not necessary for the standard answer to be correct (though it does simplify the analysis). –Henning Makholm 06:13, 15 February 2009 (UTC)

The error is not in the source - they say nothing about the probability of winning if the host opens his "non-preferred" door. They do say, as C S mentions, if the host opens one of the doors with probability p (and must open a door and must not reveal the car) he must open the other one with probability 1-p. I haven't chased down where the error came from, but it may be my mistake. -- Rick Block (talk) 02:29, 16 February 2009 (UTC)

Is there a procedure for investigating WP:Ownership allegations? I'll be happy to share everything I can.

Otherwise, read the Conventional Wisdom section. That's where I lay everything out. —Preceding unsigned comment added by Glkanter (talk • contribs) 06:03, 15 February 2009 (UTC)

There is no such procedure, because one is not necessary. There is no formal sanction for pretending or believing that one owns an article. The principal sanction is that other editors will consider the would-be owner childish and annoying, and will be less likely to assume that his opinions about the article have a rational basis. We don't need a formal finding of ownership to start doing that; our individual reasoned opinions will suffice.

What is "punishable" is actual disruptive editing of the article, e.g. if the would-be owner attempts to enforce his veto by repeatedly reverting against a consensus of other editors. In that case it is not important whether the disruptive editor's motive for getting into a revert war is a misplaced sense of ownership or something else. –Henning Makholm 06:24, 15 February 2009 (UTC)

I hope your right. But that's not what was just implied by a recent poster. I got the impression from him that the standards are much higher than that, especially for a Featured Article. Just going by what I just read. Glkanter (talk) 06:34, 15 February 2009 (UTC)

I'm curious, who usually wins the revert wars? Glkanter (talk) 06:50, 15 February 2009 (UTC)

They are a strange game. The only way to win is not to play.

Who lose revert wars? The one who tries to force through his minority opinion through against an actual consensus of several other active editors. The dissenter's reverts will usually be re-reverted quickly. In the short run it will be a matter of who hits the three-revert limit first. Here numbers matter. In the longer run the loner tends to tire of the game before all the defenders of the consensus do -- and if he fails to tire quickly enough, eventually someone will summon an admin to apply her discretion (three reverts a day is a limit, not a right) to shut down the troublemaker. –Henning Makholm 07:16, 15 February 2009 (UTC)

That's very informative. Thank you. I wonder what other rules actually have sanctions attached. I also wonder if there is a 'super set' of editors. You know, the ones who really make the decicisions when the children are done banging their drums and making noise. Glkanter (talk) 07:43, 15 February 2009 (UTC)

Answered on User talk:Glkanter (welcome template, links to relevant guidelines). –Henning Makholm 08:58, 15 February 2009 (UTC)

Rather than argue about unconditional/conditional issues we could agree, for the moment at least, to continue what is already done in the article. This is what I have done in my changes to the lead.

I think it is agreed by all that if we consider the overall probability of getting a car of players who swap compared with players who stick there is no conditional issue. All that is needed is to talk in terms of players who swap and players who stick (in other words we consider players to be either stickers or swappers). I think it is generally accepted that, for any reasonable interpretation of the problem, stickers have a 1/3 chance of getting a car and swappers a 2/3 chance and that no conditional probability is required to show this.

The two problems with this approach that I see are firstly that I do not believe that it is actually necessary, and secondly that it detracts from the true nature of the problem as a game show in which the player is presented with a choice after a particular action of the host. This makes an overall probability solution justifiably less convincing to some, nevertheless it may suit others.

However, by being careful with our wording it might be possible to present a very simple and clear solution that is acceptable to all. As far as I am concerned the overall solution already given is fine in principle, it just needs improving in terms of words and pictures. Martin Hogbin (talk) 10:21, 15 February 2009 (UTC)

It seems attractive to speak in terms of stickers and swappers. But thus it apply to the situation? Considers for a moment the situation that the host opened both other doors. Would you still speak of stickers and swappers having probability 1/3 resp/ 2/3 of winning the car? Nijdam (talk) 13:35, 15 February 2009 (UTC)

No, that is why I said, 'for any reasonable interpretation of the problem'. Note also that this approach is already used in the article in the lead section. Martin Hogbin (talk) 14:58, 15 February 2009 (UTC)

As far as I can tell, where we may be headed here (rare in math articles) is to treat this as a case where different sources (not different editors!) have different opinions and scrupulously follow WP:NPOV. It is not within Wikipedia's purview to take sides. This would suggest a longer solution section, structured like:

Various published sources treat the Monty Hall problem in different ways and present different solutions.

An easily understood simple solution (need a specific high quality reference) is ...

vos Savant's solution (reference Parade) is ...

A rigorous mathematical solution (reference both Morgan et al. and Gillman) is ...

A solution based on Bayes theorem is ... (and we'd move the Bayes solution back to the expanded Solution section).

These should probably flow from easiest to understand to harder to understand, and say what the sources say (without adding our own editorial spin). The question then becomes how many solutions are worth including and what sources would we use. -- Rick Block (talk) 17:26, 15 February 2009 (UTC)

I think I agree with this general strategy, but we should be careful not to imply a disagreement that isn't there. In particular we should scrupulously stress that these approaches are all valid and all lead to the same result. Otherwise a less mathematically sophisticated reader can easily get the impression that we're reporting on an ongoing academic dispute about who is right and who is wrong. (That is what we would do with similar language in the humanities, for example). I suggest language like

The answer, under the stated assumptions, is that the player doubles his chance of winning the car if he switches doors.

There are various ways to see this. Though they are all mathematically valid (and lead to the same end result), different people may find different explanations more compelling.

vos Savant's solution (reference Parade) is ...

A rigorous mathematical solution (reference both Morgan et al. and Gillman) is ...

A solution based on Bayes theorem is ... (and we'd move the Bayes solution back to the expanded Solution section).

I don't think it is possible to order the solutions by ease of understanding consistently -- every solution that is worth presenting is so because there is somebody for whom this solution is easiest. A better metric might be to start with the solution that we think most readers will find easiest. –Henning Makholm 17:53, 15 February 2009 (UTC)

(edit conflict) I'm late to this party, and the preceding discussion is very long and sprawling. Let me just dump my opinion, more or less from first principles, on what seems to be the matter:

The classical problem, as stated, is one where the plain and orthodox way to turn it into a mathematical question is to ask about a conditional probability. Calculating this conditional probability in the most by-the-book, pedestrian, not-trying-to-be-smart way will yield the correct answer. On the other hand, a mathematically mature reader will be able to see that because of symmetry, the same correct answer can be arrived at with considerably less calculation by imagining that the player makes his choice to swap or not swap in advance; then all one has to do is calculate an old-fashioned non-conditional probability. All of the foregoing is fact, and hopefully not in dispute; otherwise we're worse off than it seems.

Now, different readers will have different trouble with those facts, and we must try to satisfy all of them, even if that means that some readers need to read explanations that are not directly relevant to the understanding which that particular reader finds easiest. The choice between the two approaches is a trade-off between knowing more theory (conditional probabilities), or using less theory but applying more problem-specific cleverness (invoking symmetry). What one prefers is subjective, and not something that is objectively inherent in the problem.

The sticker-swapper argument is both popular and extremely attractive to readers who are capable of seeing that it is a valid approach, so it would be a bad encyclopedia that did not present it at least somewhere. On the other hand, seeing that it is valid is not entirely trivial, and there will be other readers who are more easily convinced by a straightforward conditional probability. So this must also be presented.

However, finding the right answer is not the end-all. The more curious reader will also want to investigate not only what is right, but also how he managed to be wrong when he initially thought it would be 50/50. And in order to discuss that -- an interesting and now famous perceptional problem that this article must address -- I cannot see how that can be discussed without the machinery of conditional probabilities.

What we then have to decide, from an editorial viewpoint, it not whether to present one or the other raw solution to the original problem, but merely which one to present first. Personally I would gravitate towards starting with the conditional probabilities, the one that requires less ad-hoc cleverness, but reasonable arguments for the opposite order can also be made. In the end I think it is more important the both explanations are good than which order they appear in.

Now have I misunderstood everything? –Henning Makholm 17:29, 15 February 2009 (UTC)

I couldn't have summarized things better. Nijdam (talk) 17:37, 15 February 2009 (UTC)

I do not agree with everything said especially that about conditional/unconditional and Morgan, but as I suggested, let us have a truce on that. I do not think the changes required need be that dramatic. The overall probability solution was already there in the lead, I just expanded it a bit. I would like to expand it some more and add pictures, but that would mean moving it to the solutions section. There are no references at present but I am not sure that there is a rule which says that if you add pictures you must add more references. On the other hand, I am sure that we can find some, even Morgan agree about the overall probability.

I agree with the concept of different sources having different opinions, particularly as I do not like the Morgan paper. I think we should not say that it is a rigorous solution or that it is a better solution than others unless that view can be sourced. If not, we should say something strictly factual like 'a solution published in a peer reviewed journal'. I agree with Henning's point that we should not suggest that there is any doubt about the answer, the doubt is really about the question. In a way that was my original point. Martin Hogbin (talk) 18:53, 15 February 2009 (UTC)

The policies say to resolve a dispute, 3rd party input from subject matter experts may help.

So, Rick and I have solicited this input.

Now, I've been criticized for mis-representing that feedback.

So, absent an edit to this talk page from the subject matter expert, how does one incorporate their contributions into the larger discussion?

I think one expert has unambiguously defended my proof. I think another has said he doesn't know what Morgan's problem with the unconditional solution is, so he'll research it further.

But I don't want to put words in people's mouths. I don't need to. It's out there in the edits.

As far as I can tell, the only tool available to me is to cut and paste quotes and links into new edits.

How do I incorporate those views expressed into this discussion, so as to build a consensus? Glkanter (talk) 15:08, 15 February 2009 (UTC)

None of these people are saying what you think they're saying. And yes, I read their comments. They're certainly not backing your proposed revisions to the article either. If you truly believe they are supporting your changes, ask them to come here and support your proposed removal of the "wrong" explanations. --C S (talk) 16:05, 15 February 2009 (UTC)

The feeling I got from discussing this page with subject matter experts is that they see it as a black hole, which they wish to fervently avoid. Please go to this page to determine for yourself the validity of this statement. http://en.wikipedia.org/wiki/Wikipedia_talk:WikiProject_Mathematics

I believe, then, that any efforts to encourage them to post on this page would be counter-productive.

Nobody has answered my question. 3rd party subject matter experts HAVE made comments, suggestions and opinions. How do we incorporate those into this discussion?

We've referred to Boris. I think he has a doctorate in Mathematics. Here's his page. Read the last section. I think it's reasonable to conclude that he's agreeing with me. But you decide! http://en.wikipedia.org/wiki/User_talk:Tsirel Glkanter (talk) 19:24, 15 February 2009 (UTC)

As I said, I already read that. And nobody disagrees with what you and Boris wrote in that section anyway. Everyone here (including Rick) agrees that is the solution to the "unconditional" MHP. So you see here how you don't even understand what is going on here. --C S (talk) 19:48, 15 February 2009 (UTC)

If Boris agrees with me, and my point is that the unconditional solution satisfies the Monty Hall Problem, then how is the 'equal goat door constraint' and Morgan still necessary for proper understanding of the problem? You know, like in the Solution section where it says the unconditional solution just provided does not address the actual problem? And then the rest of the article goes off on the the conditional solution? So does any 'two answer article' avoid saying the unconditional solution is inadequate?

You don't know me. This is the only point I have been discussing since October. Glkanter (talk) 20:05, 15 February 2009 (UTC)

Ok, I didn't want to get into this, but since you keep thinking Boris is somehow in perfect agreement with what you're saying, let me make a comment here. First, you'll note that Boris didn't regard your "proof" as a proof, only as a solution, and indeed he comments it is even "too concise". This is not a pedantic distinction because it actually is relevant to your queries. A solution is just an answer. If you say the probability is such and such, and it's correct, then you gave the correct solution. Your reasoning might be bogus, or only partly bogus, or somewhat confused, or even correct. Correct reasoning, and enough spelled out to be an explanation to someone else, that is what makes a proof.

If you truly understood the problem well, you would have no problem understanding Rick Block's comments above. The crux of the matter is that there are different ways to interpret a problem like Monty Hall; one distinction is what's been called conditional vs unconditional in the above discussions. If you interpret the problem in a conditional manner, i.e. assume particular choices of doors, the host's behavior on how he chooses between two goat doors becomes important (assuming he always opens a door and always shows a goat). This choice is not actually important when you consider what you've been calling the "unconditional" problem. If you don't understand this, then I don't think you can say you really understand the problem.

The point about the unconditional solution not addressing the problem: it's a common mistake to read the problem as conditional, but then give the unconditional solution. That's just wrong. It happens that numerically the answers are the same if you assume the host chooses between two goat doors with equal probability, but that's hardly correct mathematical reasoning. Now, as alluded to before on Boris' talk page, a mathematician worth his salt would be able to use the symmetry of the host's choosing to realize that the conditional probability should work out to be the same as the unconditional probability. But there is something going on here, some reasoning based on the symmetry of the situation. --C S (talk) 20:43, 15 February 2009 (UTC)

Thank you, Dr., for the thoughtful response. I appreciate your efforts to help me better understand the inadequacies of the unconditional solution. And your right. It's over my head. I do not see where the Monty Hall Problem as told via Marilyn vos Savant has to be a conditional problem. Glkanter (talk) 20:58, 15 February 2009 (UTC)

CS, thank you for helping us out here. You say, as many others, that the problem should be read as conditional. Can you please simply explain why? Preferably at the arguments page, on which I ask this question. Thanks in advance. Heptalogos (talk) 21:30, 15 February 2009 (UTC)

Ok, I gotta get going soon (but if you respond, I'll try to respond later too). Looking over some of my responses above, I see I've been short-tempered, for which I apologize. But it was partly due to having read the whole page (I know you keep thinking I haven't read the above, but I did), and being peeved at, I think, rather unfair treatment of Rick Block.

Actually, I don't believe this material is over any reasonably intelligent adult's head. So let's give it a go. Let's address why people might think Marilyn's statement is conditional. By the way, I hope I haven't given the impression that I think the problem must be understood as conditional. As for Marilyn's exact statement, I think it's ambiguous enough on several fronts, and there's no reason to state with absolute confidence it should be conditional.

Marilyn's wording:

Suppose you're on a game show, and you're given the choice of three doors: Behind one door is a car; behind the others, goats. You pick a door, say No. 1, and the host, who knows what's behind the doors, opens another door, say No. 3, which has a goat. He then says to you, "Do you want to pick door No. 2?" Is it to your advantage to switch your choice?

Note there is a lot of stuff being left out here. Let's just be naive here, taking nothing for granted. First, we have no idea what the host is up to. Why did he even offer a switch? Is it because you picked the car? Or does he always offer a switch? Now, since we can't expect to really ever understand the mind of Monty, most people assume something like, Monty is fair and always offers the switch. And he always shows a goat, not a car, as that would make the game silly. These might be considered pretty reasonable assumptions, none of which were explained by Marilyn. But how does he decide which door to open if he can choose between two goat doors?

At this point, you might decide, why should it matter how he chooses? And here's where the conditionality assumption starts coming in. The question, as stated, seems to be asking what you would do in this situation that you picked door 1, Monty showed door 3 had a goat, and you are offered to switch to door 2. As stated above, you can assume he always shows a goat and offers the switch, but that in this instance he opened that particular door instead of door 2. So if Marilyn was asking what would you do in this situation, you really need to know how he is choosing doors. Let's say that he always likes to open door 2 when there isn't a car behind it. You would be sure to win if you switch: probability of getting a car is 1.

Now the way Marilyn stated the problem, she said, "...say No. 1..." So a reasonable interpretation would be that these door numbers don't matter, since people often say "...say" to mean "for instance" and not to specify an exact instance. On the other hand, she didn't have to mention the door numbers, so a straightforward reading would be to assume that any information given in the problem is actually necessary. The funny thing is that in most types of problems it wouldn't be necessary to make this distinction. But in probability problems, it's really important. Did Marilyn intend these door numbers to be useful, or were they just extraneous bits she didn't think to edit out? Of course, to further confuse the situation, remember Marilyn never specified the host's choosing between two goat doors. If you assume the unconditional problem, this information is not necessary, since as you pointed out, you only had a 1/3 chance to begin with of getting the car, so if you can switch, you should. On the other hand, a reasonable person might assume that Monty picks either door with equal probability. And with that, you can indeed solve the conditional problem. Amusingly, you end up with the same answer either way. But that only further confuses things for people. --C S (talk) 21:52, 15 February 2009 (UTC)

Conditional probabilities are for morons! We know from optimal control that the closes way between two points is a straight line. The unconditional solution is located on that line. The conditional solution is not on that line. Occam's razor forever!! !--92.41.77.75 (talk) 22:09, 15 February 2009 (UTC)

CS, thanks for the explanation. It's all very obvious what you say, and actually that's not what I was looking for. That's why I referred to the Arguments page; here's where I ask the common rule for a problem to be conditional. Most of us are discussing the Krauss and Wang (2003:10) statement of the problem anyway, so there need not to be much discussion about what was meant by Marilyn. Even if so, it's another discussion outside maths. My question is what exactly makes the Krauss and Wang statement a conditional problem, following which rule. Heptalogos (talk) 22:25, 15 February 2009 (UTC)

I'm trying to eat my humble pie quietly, but I just gotta ask, what do you mean when you say: "By the way, I hope I haven't given the impression that I think the problem must be understood as conditional."? I'm afraid that is what I think you're saying. I've admitted defeat here precisely because I thought you said that it must be. And I'm not arrogant enough to argue math with a math PHD. Glkanter (talk) 00:16, 16 February 2009 (UTC)

This may help me understand. You wrote: "If you assume the unconditional problem, this information is not necessary, since as you pointed out, you only had a 1/3 chance to begin with of getting the car, so if you can switch, you should." What is it about the conditional problem that makes that statement not applicable to it's solution as well?. Monty's motivation, behaviour and actions don't affect that 1/3 chance, do they? —Preceding unsigned comment added by Glkanter (talk • contribs) 01:26, 16 February 2009 (UTC)

Glkanter, please try to understand what is meant. CS is not sure about Marilyn's problem to be conditional or not, because information is missing. But he thinks the Krauss and Wang 2003:10 statement (or similar) of the problem is conditional. Heptalogos (talk) 11:03, 16 February 2009 (UTC)

Thanks for your thoughts. As you can see by my question, I'm trying to demonstrate that, imho, the unconditional solution also solves any conditional statement of the Monty Hall Problem. Glkanter (talk) 14:09, 16 February 2009 (UTC)

I think an emphais on the unconditional solution for the Monty Hall Problem artcile is appropriate.

This would mean de-emphasising dramatically much of the remainder of the existing article. Glkanter (talk) 17:08, 16 February 2009 (UTC)

File:MontyXXX.jpg--Pello-500 (talk) 14:56, 16 February 2009 (UTC)

What is the difference in content between this and the former "Suggested Unconditional Solution"? Heptalogos (talk) 16:45, 16 February 2009 (UTC)

Well as a picture it lookes nice, but what is the connection with the problem? What if the car is behind door 1? And the problem states: the player has picked door 1 and the host has opened door 3, which shows a goat. Nijdam (talk) 17:04, 16 February 2009 (UTC)

Whether we include this content or not, I think it's completely unacceptable for this to be presented as an image. -- Rick Block (talk) 17:19, 16 February 2009 (UTC)

fair enough. As long as the point is made I dont care about if it is a table or picture. Maybe someone could please help me to improve layout? (It is harder than it looks.) A table would be nice! --Pello-500 (talk) 19:30, 16 February 2009 (UTC)

Have you considered wording it to be an overall probability calculation as discussed above. I do not like the use of door numbers in the solution, it makes a better case for a conditional solution. Martin Hogbin (talk) 20:35, 16 February 2009 (UTC)

You choose a door
You choose a door with a goat		You choose a door with a goat		You choose a door with a car
You Stick	You Change	You Stick	You Change	You Stick	You change
You get a goat	You get a car	You get a goat	You get car	You get a car	You get a goat

If we were to put a simple unconditional solution this might be a better choice, taken from the 'Curious Incident...'

We can assume that the two goats and the car is located as follows:

Door 1	Door 2	Door 3
Goat	Goat	Car

We now have two opions: Not Switch or Switch

Not Switch			Switch
Pick	Show	Outcome	Pick	Show	Outcome
1	2	lose	1	2	win
2	1	lose	2	1	win
3	2 or 1	win	3	2 or 1	lose

If we do not switch the probability of winning is 1/3			If we switch the probability of winning is 2/3

We should therefore choose to switch doors if we want to increase our probability of winning the car

I know that I favour a simple solution but we do need to recognize that this is a featured article and we should tread carefully. The last few changes make the page much worse in my opinion and should be reverted. Let is try to reach a consensus on how to proceed. before we make such dramatic changes. Martin Hogbin (talk) 23:13, 16 February 2009 (UTC)

Leaving out the door numbers in the wording of the problem, essentially changes the problem and takes away not only its charm, but also changes it to a form it never was intended to. I.e. it no longer would be equivalent to the three prisoners problem, from which it seemes to be derived, but especially it no longer reflects what happens in the Monty Hall show. Nijdam (talk) 00:31, 17 February 2009 (UTC)

It's been 24 hours since I posted this:

This may help me understand. You wrote: "If you assume the unconditional problem, this information is not necessary, since as you pointed out, you only had a 1/3 chance to begin with of getting the car, so if you can switch, you should." What is it about the conditional problem that makes that statement not applicable to it's solution as well?. Monty's motivation, behaviour and actions don't affect that 1/3 chance, do they?

They certainly could do. Take the most extreme case, Monty shows you you have originally chosen a car. The chances you have a car are now 1. Martin Hogbin (talk) 18:36, 17 February 2009 (UTC)

I suppose. It seems to me that would violate the 'Monty always shows a goat from the two un-selected doors' premise, making it a different puzzle. Is that what 'conditions' are? New premises, or the removal of old premises? I sure don't know, and have never claimed to. Glkanter (talk) 19:58, 17 February 2009 (UTC)

If someone will disprove this, in notation similar to what I am using, I will leave this page forever.

In the following scenarios, the parenthesis represent that Monty is choosing exclusively among the two un-selected doors.

In the 'Combined Doors' Solution, the underlying formula is 1/3 + (1/3 +1/3) just prior to Monty revealing a goat behind one of the unselected doors.

Then Monty reveals a goat, and the formula becomes 1/3 + (2/3 + 0). The 1/3 represented by the door Monty just opened becomes a 0, and the 1/3 is distributed evenly over the remaining doors within the parenthesis, of which there is now just one.

As it remains a premise in the conditional statement of the problem that Monty will reveal a goat behind one of the two un-selected doors (or else it's a different problem), the underlying formula after that action will look the same as the unconditional one, 1/3 + (2/3 + 0).

Since the 'Monty always reveals a goat from the un-selected two doors' constraint exists in both the conditional and unconditional statement of the problem, the 1/3 that gets 'freed up' must stay inside the parenthesis. The 1/3 on the left of the plus sign, which represents the player's original selection, has not changed, and could not change, as long as this premise exists.

So I conclude that the unconditional solution I have previously offered satisfies the conditional problem as well. Glkanter (talk) 12:37, 18 February 2009 (UTC)

applicable to it's solution as well?. Monty's motivation, behaviour and actions don't affect that 1/3 chance, do they?

They certainly could do. Take the most extreme case, Monty shows you you have originally chosen a car. The chances you have a car are now 1. Martin Hogbin (talk) 18:36, 17 February 2009 (UTC)

I suppose. It seems to me that would violate the 'Monty always shows a goat from the two un-selected doors' premise, making it a different puzzle. Is that what 'conditions' are? New premises, or the removal of old premises? I sure don't know, and have never claimed to. Glkanter (talk) 19:58, 17 February 2009 (UTC)

If someone will disprove this, in notation similar to what I am using, I will leave this page forever.

In the following scenarios, the parenthesis represent that Monty is choosing exclusively among the two un-selected doors.

In the 'Combined Doors' Solution, the underlying formula is 1/3 + (1/3 +1/3) just prior to Monty revealing a goat behind one of the unselected doors.

Then Monty_{random goat} reveals a goat showing no preference between two goats if he has the chance, and the formula becomes

[1/3*1/2 + (1/3 + 0)]_{Door 3} + [1/3*(1-1/2) + (0 + 1/3)]_{Door 2}

where the two major terms reflect the probability split according to the door this Monty opens. The 1/3 represented by the door the player chose splits into two 1/3*1/2 (equals 1/6) terms, 1/2 being the probability the player finds herself in each case. The 1/3 represented by the door Monty just opened becomes a 0 in one of the "by door" terms and remains 1/3 in the other by-door term. This reflects the image shown in the Solution section in this version of the article.

If we scale either of these terms up to 1 (i.e. make it the "what happened" case) we get 1/3 + (2/3 + 0). So, what's the problem you may ask?

The problem is the unconditional solution says nothing about how Monty picks between two goats if he gets the chance, that is when the player initially selects the car. As the only premise in the unconditional statement of the problem is that Monty will reveal a goat behind one of the two un-selected doors he should be free to change the probability of his selection between two goats if he'd like. You seem to object to the Monty_leftmost we've previously discussed because in some cases he shows you where the car is with certainty. How about Monty_{1/3 favor door 2}, who has a slight distaste for Door 2 and instead of choosing randomly between two goats opens Door 2 with a 1/3 chance and Door 3 with a 2/3 chance - but only if the player initially picks the car.

When this Monty reveals a goat the formula becomes

[1/3*1/3 + (1/3 + 0)]_{Door 3} + [1/3*(1-1/3) + (0 + 1/3)]_{Door 2}

If we scale these terms up to 1 (i.e. make each the "what happened" case) we get 1/4 + (3/4 + 0) in the door 2 case (to do this scaling we divide by 4/9 - because there's a 4/9 chance of this being the case), and 2/5 + (3/5 + 0) in the door 3 case (dividing by 5/9).

In general, the conditional formula becomes

[1/3*p + (1/3 + 0)]_{Door 3} + [1/3*(1-p) + (0 + 1/3)]_{Door 2}

Which scales up evenly to 1/3 + (2/3 + 0) only if p is 1/2.

Now look at the picture. What this is saying that the unconditional solution works regardless of how we split the 1/3 probability (now in the middle) representing the case where the player initially selects the car (the outer 1/3 probabilities are fixed). The conditional solution pays attention to this split. -- Rick Block (talk) 14:56, 18 February 2009 (UTC)

Thank you Rick. My only 'objection' to the 'left-most door' variant is that is looks to me like a new constraint. So, your new example does as well. I'm not clear on this, is the contestant aware of Monty's bias in either example?

So maybe, I've been missing the point. Do I understand correctly that you use the 'left-most door' variant to show me that there are MHP variations that result in a 2/3 overall probability, but are not 'properly' solved using the unconditional solution?

Since like most people here, I've only read 1 page of Morgan, I can't be sure what they put forth. But I'm starting (continuing, really) to wonder if the 'left-most door' variant really does work out to 2/3 overall. Using the unconditional MHP that has been proven, I think the overall probability lies somewhere between 2/3 & 100%. The 100% for those times when Monty 'tells' me where the car is, and 2/3 for when I revert to 'always switch'. This would result in an overall probability higher than 2/3. Glkanter (talk) 12:42, 19 February 2009 (UTC)

The left-most door variant is used as an extreme example showing the effect the host preference for one goat door over another (not mentioned in the Parade version of the problem) can have on the conditional probability. Both Morgan and Gillman show the conditional probability of winning by switching (assuming the host always opens a door showing a goat and always offers the chance to switch) is 1 / (1 + p) where p is the preference the host has for one "goat" door over another. This preference is not mentioned (hence, is unconstrained - which is not the same as "should be assumed to be random") in the Parade version of the problem (which is the version Morgan and Gillman address), but is in the K&R problem statement. In the K&R version the constraint that says If both remaining doors have goats behind them, he chooses one randomly. means for this statement of the problem p is 1/2. Morgan and Gillman also both show the unconditional probability, regardless of p, is 2/3. The conditional probability, 1 / (1 + p), lies between 1/2 and 1 (not 2/3 and 1) because p can range from 0 to 1.

Look at the figure again. The p we're talking about corresponds to the position of the vertical line that is shown in the exact middle of the figure (the line that splits the "car hidden behind door 1" case into the two subcases where the host opens door 2 and host opens door 3). If p is 1/2, this line is in the dead middle of the figure and and the subcases each have probability 1/6. If we don't constrain what p is (e.g. the Parade version) we can draw the line anywhere we'd like within the "player picked the car" case. These subcases always have probabilities 1/3*p and 1/3*(1-p). With me so far?

The line we're talking about extends all the way to the bottom of the figure, so when we move it right and left we're also changing how often a player sees the host open door 2 (or door 3). In the "leftmost" variant, we've moved this line all the way to the right (if the player initially picks the car, the host always opens door 2). We're not changing anything in the top 4 rows of the figure, but we now have a case where if the host opens door 2 (which only happens 1/3 of the time) a player who switches wins with certainty and if the host opens door 3 (which happens 2/3 of the time) a player who switches wins only 50% of the time. Even in this extreme case, 2/3 of all players who switch win (if 1/3 win 100% and 2/3 win 50% then 2/3 win overall).

Why all this is important is because the unconditional solution ignores everything below the top 4 rows of the figure. In the problem as stated, we know which door the host has opened, so we need to be looking at the bottom part of the figure. In the Parade version we don't know p, so we don't know where the vertical line (shown in the middle) actually is. For the K&R version of the problem, we've fixed the bottom part to look exactly like the figure that's shown (and the probability of winning by switching is 2/3). The unconditional solution is not sensitive to where this line is - so it's not answering the question that's asked. -- Rick Block (talk) 16:45, 19 February 2009 (UTC)

Minor addendum: since we don't know p in the Parade version, the answer to the conditional question is that the probability of winning by switching is 1 / (1 + p) (i.e. some number between .5 and 1). Even assuming the host always opens a door and always shows a goat, this version of the problem doesn't give us enough information to say the conditional probability of winning by switching is 2/3. In the K&R version, we do end up with 2/3 as the conditional probability but this is because 1 / (1 + 1/2) is 2/3 - not because the unconditional probability is 2/3 (which is what an unconditional solution says). -- Rick Block (talk) 19:47, 19 February 2009 (UTC)

Well, the Parade version does not ask for probabilities; it merely asks for advice. Knowing just that p is between 0 and 1, we can conclude that switching never hurts but may help. Therefore you should switch! –Henning Makholm (talk) 20:05, 19 February 2009 (UTC)

Haven't heard a peep back yet.

So, it's over. You know it, and I know it. And I was right. From my very first post.

Rick Block, I commend you, sir. You were led, badly, by someone who you trusted, with good reasons. You were always, always considerate and professional. I hope someday you and I are on the same team.

C S, you are garbage.

I posted some fun stuff on my talk page. Check it out! http://en.wikipedia.org/wiki/User_talk:Glkanter —Preceding unsigned comment added by Glkanter (talk • contribs) 03:08, 17 February 2009 (UTC)

So, now that it has been proven that the alleged conditional statements of the MHP can be solved using the unconditional solution, there really is no 'conditional problem'. Just so much noise. Because Monty can't change the past, so it's still a 1/3 chance I picked the car.

Let's focus on improving the Wikipedia reader's experience with this article. —Preceding unsigned comment added by Glkanter (talk • contribs) 01:39, 17 February 2009 (UTC) Glkanter (talk) 03:10, 17 February 2009 (UTC)

Nobody has commented because you're still wrong, but you won't apparently listen to anyone. What you're engaging in is called Wikipedia:Disruptive editing. If you don't stop, you will eventually be blocked from further editing. I've changed your comment slightly. -- Rick Block (talk) 03:00, 17 February 2009 (UTC)

C S, you are garbage.. Very well, I just logged on and was about to continue on my exposition above. But forget it. I have much better things to do with my time than explain why your solution to a completely different problem does not apply. Don't bother making any edits to the article. Any further comment you make here irrelevant to discussion of improvement of the article will be deleted per talk page guidelines. Continued insistence on doing so will be reported as disruption to the proper authorities. You've been given a lot of latitude, but no longer. --C S (talk) 11:22, 17 February 2009 (UTC)

So, just how DOES Monty change that original 1/3? Without some conditional time machine, or what not. Glkanter (talk) 13:05, 17 February 2009 (UTC)

Please do the card experiment suggested above. Keep track of which card the dealer discards and wins by switching in each case. Do this about 90 times. Post your results here. Imagine you're going to do this the 91st time and you've seen the dealer discard the two of hearts. What are your chances of winning by switching? -- Rick Block (talk) 14:48, 17 February 2009 (UTC)

Firstly Glkanter, you have agreed above that it is possible for Monty to change the odds for an individual player. He could do it by telling them what they have chosen, as suggested above. The odds would then change from 1/3 to 0 or 1 depending on which the player held. It goes back to the old adage, probability is a state of knowledge. The question you then need to ask is could he do this within the rules of the game, and the answer is yes, if the rules do not force him to choose a goat door randomly when he has a choice. Martin Hogbin (talk) 22:24, 18 February 2009 (UTC)

If Monty 'may' tell a player where the car is, then you're getting into game theory, not the MHP via MvS. I agree 100% that the probability is a state of knowledge. So let's agree then, on what the contestant knows. Does Monty discuss his technique with anybody? If he does, then it's a new premise to a different puzzle. And if he does essentially tell me exactly where the car is sometimes, (I think the 'left-most door' variant does this), then it follows, to me at least, that my overall probability should rise above the less-informed 2/3. Rick and I briefly debated whether its 1/2 or 2/3 for the times when Monty does not 'tell' me where it is. Because its 100% when he does 'tell' me.

Rick Block, I will endevor to study the reasoning you put forth regarding my Combined Doors question. Thank you. Glkanter (talk) 02:03, 19 February 2009 (UTC)

I can't follow y'all's heated arguments too good, but I tried to add a bit to make it clear that the assertion that the probability of getting a car is still 1/3 after Monty opens a door depends on some unstated assumptions about whether he always does this or not. The logic did not follow without this, and Martin took it out, so I just put a bit to say it depends on some assumptions. Feel free to further clarify, but don't go backwards to the condition of stating a "deduction" that doesn't follow. Dicklyon (talk) 02:27, 17 February 2009 (UTC)

The statement you are referring to is worded to refer to overall probabilities. That is to say if we have a large number of players then, on average, those who stick will win 1/3 of the time and those who swap will win 2/3 of the time. This is true for all reasonable interpretations of the problem regardless of how the host chooses which goat door to open. It is even true if the host tells the players where the goat is (after the players initial choice), to take an extreme example. I think this bit should be worded to make the overall aspect clearer, have some pictures, and be moved out of the lead to the solutions section, which I propose to do some time. Martin Hogbin (talk) 18:22, 17 February 2009 (UTC)

I don't think so, Martin. If the host's policy is to open a door only when he knows that you've chosen the car, you'll always lose by switching. If his policy is to open a door only when he knows you've chosen a goat, you'll always win by switching. If he opens a door with some probability that depends on his knowledge of what you've chosen, it can be anywhere in between. So your probability of getting a car by switching can be anywhere from 0 to 1, depending on what policy the host is using. Without stating your assumption that the host always opens a door, you conclusions do not follow. Dicklyon (talk) 20:30, 17 February 2009 (UTC)

My statement of overall probability always holds, see Morgan et al. The host always opens a door, it says so in the question. This is not disputed by anyone except you. Martin Hogbin (talk) 22:40, 17 February 2009 (UTC)

Indeed does the host opens a door, but Dicklyon is right in so far,that it might be the door with the car. And suppose he shows you a goat when you picked the car and otherwise shows the car. Well you have of course an overall probability of 1/3 to win the car if you stick, but no chance at all if you switch. Nijdam (talk) 23:27, 17 February 2009 (UTC)

It's very clear that he doesn't open the door with the car; in some versions he could, but that's not part of the problem as stated in Parade magazine.

The ambiguity in the Parade magazine statement is precisely and only in the fact that it does NOT say that he always opens a door. To repeat, it says "Suppose you're on a game show, and you're given the choice of three doors: Behind one door is a car; behind the others, goats. You pick a door, say No. 1, and the host, who knows what's behind the doors, opens another door, say No. 3, which has a goat. He then says to you, "Do you want to pick door No. 2?" Is it to your advantage to switch your choice? (Whitaker 1990)" That is, YOU picked a door, and he open a door for YOU, and now what shoule YOU do? If you know he always does this, you should switch. If you don't, and you think he's trying to trick you into giving up your car, you should not switch. You can't make a probability problem out of it until you say what your probabilistic model of the host is. If he ALWAYS does it, it's a trivial problem; why are you guys trying to make it more than that? Dicklyon (talk) 00:36, 18 February 2009 (UTC)

Martin, are you saying that the statement in the article that "There are certain ambiguities in this formulation of the problem: it is unclear whether or not the host would always open another door..." is not agreed to by you and others? Dicklyon (talk) 00:41, 18 February 2009 (UTC)

There seem to be two things going on here. Most of the article is specifically about the fully explicit, Krauss and Wang version of the problem stated in the "Problem" section of the article (which doesn't have any of the ambiguities present in the Parade version). What Martin is talking about is whether the problem should be interpreted as a conditional problem, see #Conditional or unconditional, once again, above. The abbreviated solution in the lead is an unconditional solution. -- Rick Block (talk) 01:37, 18 February 2009 (UTC)

OK, but then two questions about Martin's behavior: why does he revert the clarification about what his deductions are based on? And why does he care whether it's treated as "conditional" or otherwise if the answers are the same? Dicklyon (talk) 04:11, 18 February 2009 (UTC)

The section in the lead is an overall probability (I have added 'on average' to make this clearer) that holds for any reasonable interpretation of the problem, which is that Monty always opens a door to reveal a goat, which is what it says in the question. It is generally agreed here, and supported by Morgan, that possibilities such as Monty does not open a door and Monty opens a door to reveal a car are not relevant and result in a different question.

There is an ongoing discussion about whether Monty opens a goat door randomly (when he has a choice) or whether he chooses on some other basis (which could affect the probabilities for an individual player), however, it is agreed by all that this does not affect the overall probability, that is to say the average result for a large number of players who enter the game. I agree that the current statement may not yet make that clear enough but I intend to move it, clarify it, and add some diagrams some time. Mentioning some unspecified assumptions does not clarify anything, hopefully with the agreement of all here. Martin Hogbin (talk) 09:29, 18 February 2009 (UTC)

OK, I get you now. Still, one ca say "under certain assumptions" initially, and then clarify the minor point later. One can also point out that the strategy of always switching is optimal, and give the same results, whether or not the host chooses at random. Dicklyon (talk) 15:50, 18 February 2009 (UTC)

I just realized that a whole new crew of interested editors are joining the fray.

It's been happening for 4 years now, and will continue, with no reason for abating.

So, I'll eventually be gone, but someone new will take my place.

Why not try to reduce the 'heat' before it starts?

What would help is if the Math guys would, in writing, present the consensus 'house' line on the issue. Put it on the talk page. Not like the old banner that was torn down. Something that would pro-actively indicate the other subject matter experts' opinions are in line with the emphasis of the article. —Preceding unsigned comment added by Glkanter (talk • contribs)

I've revised the new version of the initial solution a bit. I think rearranging the figure so the "host opens Door 3" and "host opens Door 2" cases are adjacent shows what's going on somewhat better. Actually, flipping these so the "host opens Door 2" cases are on the left might be even better (since Door 2 is shown on the left in the figure). -- Rick Block (talk) 05:14, 17 February 2009 (UTC)

Any mileage in this? It does not rely on host action but does trick the reader.

Initially you have a 1/3 chance of picking a car and a 2/3 chance of picking a goat. After Monty has opened a door revealing a goat you will always get the opposite of your original choice if you switch. Martin Hogbin (talk) 19:18, 17 February 2009 (UTC)

That's true, simple, and really all there is to it, as long as Monty's policy is always to open a door. Why do you object to my edits that make that assumption explicit? Dicklyon (talk) 20:25, 17 February 2009 (UTC)

You are misunderstanding the conditional issue. Monty always opens a door to reveal a goat, it says so in the question. Martin Hogbin (talk) 22:35, 17 February 2009 (UTC)

In the parade version it doesn't say that; that's worth clarifying. But you're right that I don't understand the stuff around "the conditional issue". Can you point me at a source to clarify? Dicklyon (talk) 04:14, 18 February 2009 (UTC)

Lemme know what you find out. Glkanter (talk) 04:40, 18 February 2009 (UTC)

Dicklyon - did you read the section I referred you to above? It is a summary of two rigorous mathematical treatments of the problem (the Morgan et al. and Gillman references in the article) - both published shortly after the controversy raised by the original Parade columns in 1990-1991. -- Rick Block (talk) 04:48, 18 February 2009 (UTC)

Dick please read the sources referred to before making any more changes to the article. You agree that you do not understand the stuff around the conditional issue; the place to clarify that understanding is here on the discussion page, not in the article. I, and no doubt may others, will be happy to discuss the issue with you. Perhaps we could start with you saying what you think the 'certain conditions' are that you keep adding to the article. Martin Hogbin (talk) 09:07, 18 February 2009 (UTC)

I've read enough, including the summary above, to know what you guys are going on about; if you have free copies of the sources available, or can email me a fair-use copy, I'll read more. I don't think think this mess should present a fundamental stumbling block in getting to a sensible article, so I'll look more at what you guys are trying to do about it. Dicklyon (talk) 15:53, 18 February 2009 (UTC)

As far as I know, like many academic sources neither of these are available online for free (the fee is not huge, but there is a fee). Both should be available at pretty much any university library, including online using university facilities. The Morgan et al. paper is available here (the first page is shown). -- Rick Block (talk) 17:33, 18 February 2009 (UTC)

The paragraph under discussion was intended to follow on from the previous one, where it says, 'in the usual interpretation of the problem ', and to make clear that it referred to the overall solution. I still think it should be moved from the lead to the solutions section as a 'simple' overall explanation. Martin Hogbin (talk) 22:11, 18 February 2009 (UTC)

I only briefly comment on what I over and over read. Namely, that sticking to your (initial) choice, should logically lead to sticking to your chances, i.e. dealing with unaltered probabilities. I guess many of the people defending the "unconditional" solution think along this line, and never even thought it can be otherwise. But they should! Sticking to your choice is one thing, chances do not change, but situations do, and hence new probabilities have to be calculated: conditional ones of course, given the new situaton. Nijdam (talk) 22:37, 18 February 2009 (UTC)

That's right; if you always stick, unconditionally, your chances remain 1/3. But under some conditions, if you know the host's policy, then your chances conditioned on what he does may change. For example, if he always opens the left-most door with a goat, then under some conditions you can compute your prob of winning by sticking, given the new info, to be either 1/2 or 0; it's still 1/3 overall, and if you already know that switching is the best strategy it won't change your overall chances of winning by doing so, or your chances of winning by sticking. Dicklyon (talk) 03:52, 19 February 2009 (UTC)

The point is after he opens a door your chances are always conditioned on his policy. If you don't know his policy, you don't know what your chances are (they're somewhere between 0 and 1/2). Or, if you don't know his policy, you might say chuck it, I don't have any way to know exactly so I might as well just go with the unconditional probability, which is the same as assuming the host picks randomly between goats if given the chance. Either one of these are defensible answers and indicate you probably know what you're doing - meaning if we change the problem slightly (forgetful Monty, Monty always opens the leftmost door, Monty opens the leftmost door with probability p) you'll probably still get the right answer. If you don't understand your chances are conditioned on his policy, you probably won't get the right answer for these variants and won't understand why. -- Rick Block (talk) 04:30, 19 February 2009 (UTC)

I insert a comment here. I wouldn't speak of "conditioned" on the policy of the host, but "depending". The probabilities involved after the revalation of the goat are always conditional. Nijdam (talk) 10:33, 19 February 2009 (UTC)

Sure. But it's enough to know that he always opens a door and offers a switch; with that, you can get 2/3 on average, and you can't beat that unless he has a policy like only opening another door when your first guess is wrong. I don't buy your argument that it requires a more complicated analysis to correctly arrive at the 2/3. Dicklyon (talk) 06:20, 19 February 2009 (UTC)

Dick, please note what I said above which is that the paragraph you keep changing follows on from the previous one, where it says, 'in the usual interpretation of the problem'. The usual interpretation is that Monty always offers the switch and always reveals a goat. Under these conditions the overall (I think that is the term used by Morgan) probability of winning is 2/3 for players who switch. When you write, 'Players who unconditionally switch...', you are misunderstanding the terminology. The condition being discussed here is the condition that Monty opens a door to reveal a goat, it is not the condition that the player decides to switch. My statement, 'Players who switch always get the opposite of their original choice...', is correct so long as Monty opens a door to reveal a goat, which is part of the 'usual interpretation'.

The place to discuss this, however, is here. This is a featured article and the best way forward is not to keep changing the article itself while you learn about the subject but to discuss the wording here first to reach a consensus. Although I made some recent changes to the paragraph these were only clarification of what was already there; that text had previously been in the article, unchallenged for some considerable time. By all means argue your case here but please do not try to make points by changing the article. Martin Hogbin (talk) 09:30, 19 February 2009 (UTC)

Martin, thanks for explaining what that paragraph was intended to be about. Since "the usual interpretation" appears in the previous paragraph, we need to make clear that the paragraph about "simple probability" was intended to be interpreted in that context. The best way may be to merge those paragraphs into one; otherwise, we need to add a clarification. If you'll fix that, I'll leave it alone. Dicklyon (talk) 15:47, 19 February 2009 (UTC)

If you know that he always opens a door (showing a goat) and always offers a switch, you can get 2/3 "on average" - but on average is not the question that's asked (at least according to both Morgan and Gillman). The terminology used by Morgan is "unconditional" (not "overall" and not "average"). In their conclusion they say "The unconditional problem is of interest too, for it evaluates the proportion of winners out of all games with the player following a switch strategy." They express this is a composite probability:

P(W_s) = P(W_s | D3) P(D3) + P(W_s | D2) P(D2)

The meat of their paper (the entire paper is only slightly more than 3 pages) is about P(W_s | D3), which is the probability of winning by switching given that the host has opened Door 3. Lest anyone be confused we could clearly refer to the doors of interest as the "picked door" and the "opened door" rather than Door 1 and Door 3 - and doing this clearly does not change the problem at all. If you know the conditional probabilities you can compute the unconditional, but not vice versa. -- Rick Block (talk) 14:57, 19 February 2009 (UTC)

Section moved to Talk:Monty Hall problem/Arguments#Decision Tree. -- Rick Block (talk) 14:20, 20 February 2009 (UTC)

Section moved to /Arguments#"Choice" vs. "Guess". -- Rick Block (talk) 14:41, 24 February 2009 (UTC)