Talk:Order of integration

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1. In the article it reads "all stationary processes are I(0), but not all I(0) processes are stationary" without any citation.

Please give an example of non-stationary I(0) series?

2. In the article, the definition of "Order of integration" is reported as "the minimum number of differences required to obtain a covariance stationary series".

In most of the books, the definition of "Order of integration" is "the number of differences making the series stationary".
When "order of integration" is viewed as "the number of differences making the series stationary", then does the stationarity in "...making the series stationary" also include trend-stationarity?

3. Yt = a + bt + Vt (Vt: white noice) is a trend-stationary series. What is the order of integration of a trend-stationary series (in fact, they are non-stationary as everybody knows).Alexyflemming (talk) 11:42, 16 April 2014 (UTC)[reply]

Answers?Alexyflemming (talk) 12:15, 16 April 2014 (UTC)[reply]

4. In the article, "In particular, if a series is integrated of order 0, then ${\displaystyle (1-L)^{0}X_{t}=X_{t}}$ is stationary." This maybe not be true. The process ${\displaystyle X_{2t}=\epsilon _{2t}-\theta \epsilon _{2t-1}}$ is always stationary, and when ${\displaystyle \theta \neq 1}$, it is also an ${\displaystyle I(0)}$ process; see page 35 in Johasen (1995).

5. The definition of order integration maybe not be correct. "A stochastic process ${\displaystyle Y_{t}}$ which satisfies that ${\displaystyle Y_{t}-E[Y_{t}]=\sum _{i=0}^{\infty }C_{t}\epsilon _{t-i}}$ is called ${\displaystyle I(0)}$ if ${\displaystyle C=\sum _{i=0}^{\infty }C_{i}\neq 0}$." See Defintion 3.2 in Johasen (1995). "A stochastic process ${\displaystyle X_{t}}$ is called integrated of order ${\displaystyle d}$, ${\displaystyle I(d)}$, ${\displaystyle d=0,1,2,\ldots }$ if ${\displaystyle \Delta ^{d}(X_{t}-E(X_{t}))}$ is ${\displaystyle I(0)}$." See Defintion 3.3 in Johasen (1995).

Intutions[edit]

• As far as I guess, in the definition of order of integration "the number of differences making the series stationary", the stationarity also includes trend-stationarity! Because, there are very sources using the phrase "trend-stationary I(0)". I do not think that they mean Yt=Vt (a=0, b=0, a+b*t=0+0t=0; this way of obvious trend-stationary). Even the really trend-stationary (Yt = a + b*t + Vt; a<>0, b<>0) is termed as I(0)! Alexyflemming (talk) 07:45, 17 April 2014 (UTC)[reply]

• Some sources requires Yt in the def'n of prder of integration to be "non-deterministic". Alexyflemming (talk) 11:03, 20 April 2014 (UTC)[reply]

• Since, trend is not necessarily linear (there are polynomial (quadratic, cubic,..), exponential, other trends as well).
  

The quadratic trend cannot be made "mean stationary" with only 1 differencing, it requires 2 times differencing.

• Since there is no universally accepted def'n of trend, speaking about it is rather cumbersome. Alexyflemming (talk) 11:03, 20 April 2014 (UTC)[reply]