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I have one time series, let's say

694 281 479 646 282 317 790 591 573 605 423 639 873 420 626 849 596 486 578 457 465 518 272 549 437 445 596 396 259 390

Now, I want to forecast the following values by ARIMA Model, but ARIMA requires the time series to be stationarity, so before this, I have to identify the time series above matches the requirement or not, then fUnitRoots comes up.

I think http://cran.r-project.org/web/packages/fUnitRoots/fUnitRoots.pdf can offer some help, but there is no simple tutorial

I just want one small demo to show how to identify one time series, is there any one?

thanks in advance.

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2 Answers 2

up vote 4 down vote accepted

I will give example using urca package in R.

data(npext) # This is the data used by Nelson and Plosser (1982)
 year      cpi employmt gnpdefl nomgnp interest    indprod gnpperca realgnp wages realwag sp500 unemploy velocity  M
1 1860 3.295837       NA      NA     NA       NA -0.1053605       NA      NA    NA      NA    NA       NA       NA NA
2 1861 3.295837       NA      NA     NA       NA -0.1053605       NA      NA    NA      NA    NA       NA       NA NA
3 1862 3.401197       NA      NA     NA       NA -0.1053605       NA      NA    NA      NA    NA       NA       NA NA
4 1863 3.610918       NA      NA     NA       NA  0.0000000       NA      NA    NA      NA    NA       NA       NA NA
5 1864 3.871201       NA      NA     NA       NA  0.0000000       NA      NA    NA      NA    NA       NA       NA NA
6 1865 3.850148       NA      NA     NA       NA  0.0000000       NA      NA    NA      NA    NA       NA       NA NA

I will use ADF to perform the unit root test on industrial production index as an illustration. The lag is selected based on the SIC. I use trend as there is trend in the date .

# Augmented Dickey-Fuller Test Unit Root Test # 

Test regression trend 

lm(formula = z.diff ~ z.lag.1 + 1 + tt + z.diff.lag)

     Min       1Q   Median       3Q      Max 
-0.31644 -0.04813  0.00965  0.05252  0.20504 

             Estimate Std. Error t value Pr(>|t|)    
(Intercept)  0.052208   0.017273   3.022 0.003051 ** 
z.lag.1     -0.176575   0.049406  -3.574 0.000503 ***
tt           0.007185   0.002061   3.486 0.000680 ***
z.diff.lag   0.124320   0.089153   1.394 0.165695    
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1 

Residual standard error: 0.09252 on 123 degrees of freedom
Multiple R-squared: 0.09796,    Adjusted R-squared: 0.07596 
F-statistic: 4.452 on 3 and 123 DF,  p-value: 0.005255 

Value of test-statistic is: -3.574 11.1715 6.5748 

Critical values for test statistics: 
      1pct  5pct 10pct
tau3 -3.99 -3.43 -3.13
phi2  6.22  4.75  4.07
phi3  8.43  6.49  5.47

#Interpretation: BIC selects the lag 1 as optimal lag. The test statistics -3.574 is less than the critical value tau3 at 5 percent (-3.430). So, the null that there is an unit root is is rejected only at 5 percent.

Also, check the free forecasting book available here

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ok, thank you Metrics so much. I am a beginner, let me check it by typing them into R terminal. thank you. –  hylepo Apr 21 '13 at 15:59
@ hylepo: My answer assumes that you are familiar with the theoretical stuff on unit root tests. –  Metrics Apr 21 '13 at 16:39
thank you so much. i think i got some very useful information, based one which i could dig much more, thanks –  hylepo Apr 22 '13 at 7:48

You can, of course, carry out formal tests such as the ADF test, but I would suggest carrying out "informal tests" of stationarity as a first step.

Inspecting the data visually using plot() will help you identify whether or not the data is stationary.

The next step would be to investigate the autocorrelation function and partial autocorrelation function of the data. You can do this by calling both the acf() and pacf() functions. This will not only help you decide whether or not the data is stationary, but it will also help you identify tentative ARIMA models that can later be estimated and used for forecasting if they get the all clear after carrying out the necessary diagnostic checks.

You should, indeed, pay caution to the fact that there are only 30 observations in the data that you provided. This falls below the practical minimum level of about 50 observations necessary for forecasting using ARIMA models.

If it helps, a moment after I plotted the data, I was almost certain the data was probably stationary. The estimated acf and pacf seem to confirm this view. Sometimes informal tests like that suffice.

This little-book-of-r-for-time-series may help you further.

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hi, Graeme, thank you so much! so i can not do the forecasting by ARIMA because there is only 30 observations which is less than 50, right? and manually we can determine it should be stationary by the plot chart, but we should have one value to prove, to indicate the time series is stationary or not, right? thanks again. –  hylepo Apr 21 '13 at 15:51
There's no rule to say that you can't build ARIMA models and use them for forecasting since there are less than 50 obs. It's more so a case that if you choose to do it then you should proceed with caution and monitor the model as new data becomes available. Basically, stationarity means the data has constant mean and variance - sometimes detectable by looking at the plot (look at subsets of the data to see if the mean or variance changes with time). Comparing the estimated ACF and PACF to theoretical ones can detect stationarity too. This may provide enough evidence to claim stationarity. –  Graeme Walsh Apr 21 '13 at 22:26
A formal "value" is not necessary, nor is it sufficient to "prove" that a time-series is stationary (or non-stationary). In actual fact, some econometricians have advocated that formal tests of stationarity (that will give you a "value"), such as the traditional and augmented Dickey-Fuller tests, should be discarded! You may find Gujarati's Basic Econometrics Ch.21 helpful on this matter. Alan Pankratz's Forecasting with Univariate Box-Jenkins Models is, in my opinion, the next best thing to the original Box-Jenkins textbook. I'd advise that you consult a good textbook like any of these. –  Graeme Walsh Apr 21 '13 at 22:37
thank you for the provided very useful information, i am checking. –  hylepo Apr 22 '13 at 7:47

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