Phillips–Perron Test
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A Phillips–Perron Test is a statistical testing of the null hypothesis that states a time series is integrated of order 1.
- See: Unit Root Test, Dickey–Fuller Test, Breusch–Godfrey Test, Ljung–Box Test, Durbin–Watson Test, Augmented Dickey–Fuller Test, Time Series Analysis.
References
2016
- (Wikipedia, 2016) ⇒ http://en.wikipedia.org/wiki/Phillips–Perron_test Retrieved 2016-08-07
- In statistics, the Phillips–Perron test (named after Peter C. B. Phillips and Pierre Perron) is a unit root test. That is, it is used in time series analysis to test the null hypothesis that a time series is integrated of order 1. It builds on the Dickey–Fuller test of the null hypothesis [math]\displaystyle{ \rho = 0 }[/math] in [math]\displaystyle{ \Delta y_{t}= \rho y_{t-1}+u_{t}\, }[/math], where [math]\displaystyle{ \Delta }[/math] is the first difference operator. Like the augmented Dickey–Fuller test, the Phillips–Perron test addresses the issue that the process generating data for [math]\displaystyle{ y_{t} }[/math] might have a higher order of autocorrelation than is admitted in the test equation — making [math]\displaystyle{ y_{t-1} }[/math] endogenous and thus invalidating the Dickey–Fuller t-test. Whilst the augmented Dickey–Fuller test addresses this issue by introducing lags of [math]\displaystyle{ \Delta y_{t} }[/math] as regressors in the test equation, the Phillips–Perron test makes a non-parametric correction to the t-test statistic. The test is robust with respect to unspecified autocorrelation and heteroscedasticity in the disturbance process of the test equation.
- Davidson and MacKinnon (2004) report that the Phillips–Perron test performs worse in finite samples than the augmented Dickey–Fuller test.