Bandwidth-sharing game

A bandwidth-sharing game is a type of resource allocation game designed to model the real-world allocation of bandwidth to many users in a network. The game is popular in game theory because the conclusions can be applied to real-life networks.^{[citation needed]}

The game[edit]

The game involves $n$ players. Each player $i$ has utility $U_{i}(x)$ for $x$ units of bandwidth. Player $i$ pays $w_{i}$ for $x$ units of bandwidth and receives net utility of $U_{i}(x)-w_{i}$ . The total amount of bandwidth available is $B$ .

Regarding $U_{i}(x)$ , we assume

$U_{i}(x)\geq 0;$
$U_{i}(x)$ is increasing and concave;
$U(x)$ is continuous.

The game arises from trying to find a price $p$ so that every player individually optimizes their own welfare. This implies every player must individually find ${\underset {x}{\operatorname {arg\,max} }}\,U_{i}(x)-px$ . Solving for the maximum yields $U_{i}^{'}(x)=p$ .

Problem[edit]

With this maximum condition, the game then becomes a matter of finding a price that satisfies an equilibrium. Such a price is called a market clearing price.

Possible solution[edit]

A popular idea to find the price is a method called fair sharing.^[1] In this game, every player $i$ is asked for the amount they are willing to pay for the given resource denoted by $w_{i}$ . The resource is then distributed in $x_{i}$ amounts by the formula $x_{i}={\frac {w_{i}B}{\sum _{j}w_{j}}}$ . This method yields an effective price $p={\frac {\sum _{j}w_{j}}{B}}$ . This price can proven to be market clearing; thus, the distribution $x_{1},...,x_{n}$ is optimal. The proof is as so:

Proof[edit]

We have ${\underset {x_{i}}{\operatorname {arg\,max} }}\,U_{i}(x_{i})-w_{i}$ $={\underset {w_{i}}{\operatorname {arg\,max} }}\,U_{i}\left({\frac {w_{i}B}{\sum _{j}w_{j}}}\right)-w_{i}$ . Hence,

U_{i}^{'}\left({\frac {w_{i}B}{\sum _{j}w_{j}}}\right)\left({\frac {B}{\sum _{j}w_{j}}}-{\frac {w_{i}B}{(\sum _{j}w_{j})^{2}}}\right)-1=0

from which we conclude

U_{i}^{'}(x_{i})\left({\frac {1}{p}}-{\frac {1}{p}}\left({\frac {x_{i}}{B}}\right)\right)-1=0

and thus $U_{i}^{'}(x_{i})\left(1-{\frac {x_{i}}{B}}\right)=p.$

Comparing this result to the equilibrium condition above, we see that when ${\frac {x_{i}}{B}}$ is very small, the two conditions equal each other and thus, the fair sharing game is almost optimal.

References[edit]

^ Shah, D.; Tsitsiklis, J. N.; Zhong, Y. (2014). "Qualitative properties of α-fair policies in bandwidth-sharing networks". The Annals of Applied Probability. 24 (1): 76–113. arXiv:1104.2340. doi:10.1214/12-AAP915. ISSN 1050-5164. S2CID 3731511.

[1] Shah, D.; Tsitsiklis, J. N.; Zhong, Y. (2014). "Qualitative properties of α-fair policies in bandwidth-sharing networks". The Annals of Applied Probability. 24 (1): 76–113. arXiv:1104.2340. doi:10.1214/12-AAP915. ISSN 1050-5164. S2CID 3731511.

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