pp.test: Phillips-Perron Test
In debinqiu/aTSA: Alternative Time Series Analysis
Description
Usage
Arguments
Details
Value
Note
Author(s)
References
See Also
Examples
Description
Performs the Phillips-Perron test for the null hypothesis of a unit root of
a univariate time series x (equivalently, x is a non-stationary time series).
Usage
1
Arguments
x
a numeric vector or univariate time series.
type
the type of Phillips-Perron test. The default is Z_rho.
lag.short
a logical value indicating whether the parameter of lag to calculate the
statistic is a short or long term. The default is a short term.
output
a logical value indicating to print the results in R console. The default
is TRUE.
Details
Compared with the Augmented Dickey-Fuller test, Phillips-Perron test makes
correction to the test statistics and is robust to the unspecified autocorrelation
and heteroscedasticity in the errors. There are two types of test statistics,
Z_{ρ} and Z_{τ}, which have the same asymptotic distributions
as Augmented Dickey-Fuller test statistic, ADF. The calculations of each type
of the Phillips-Perron test can be see in the reference below. If the
lag.short = TRUE, we use the default number of Newey-West lags
floor(4*(length(x)/100)^0.25),
otherwise floor(12*(length(x)/100)^0.25) to calculate the test statistics.
In order to calculate the test statistic, we consider
three types of linear regression models. The first type (type1) is the one
with no drift and linear trend with respect to time:
x[t] = ρ*x[t-1] + e[t],
where e[t] is an error term.
The second type (type2) is the one with drift but no linear trend:
x[t] = μ + ρ*x[t-1] + e[t].
The third type (type3) is the one with both drift and linear trend:
x[t] = μ + α*t + ρ*x[t-1] + e[t].
The p.value is calculated by the interpolation of test statistics from the critical values
tables (Table 10.A.1 for Z_rho and 10.A.2 for Z_tau in Fuller (1996))
with a given sample size n = length(x).
Value
A matrix for test results with three columns (lag,Z_rho
or Z_tau, p.value) and three rows (type1, type2, type3).
Each row is the test results (including lag parameter, test statistic and p.value) for
each type of linear equation.
Note
Missing values are removed.
Author(s)
Debin Qiu
References
Phillips, P. C. B.; Perron, P. (1988). Testing for a Unit Root in Time Series Regression.
Biometrika, 75 (2): 335-346.
Fuller, W. A. (1996). Introduction to statistical time series, second ed., Wiley, New York.
See Also
adf.test, kpss.test, stationary.test
Examples
1
2
3
4
5
6
debinqiu/aTSA documentation built on May 15, 2019, 1:54 a.m.
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Description Usage Arguments Details Value Note Author(s) References See Also Examples
Description
Performs the Phillips-Perron test for the null hypothesis of a unit root of
a univariate time series x (equivalently, x is a non-stationary time series).
Usage
1 |
Arguments
x |
a numeric vector or univariate time series. |
type |
the type of Phillips-Perron test. The default is |
lag.short |
a logical value indicating whether the parameter of lag to calculate the statistic is a short or long term. The default is a short term. |
output |
a logical value indicating to print the results in R console. The default
is |
Details
Compared with the Augmented Dickey-Fuller test, Phillips-Perron test makes
correction to the test statistics and is robust to the unspecified autocorrelation
and heteroscedasticity in the errors. There are two types of test statistics,
Z_{ρ} and Z_{τ}, which have the same asymptotic distributions
as Augmented Dickey-Fuller test statistic, ADF. The calculations of each type
of the Phillips-Perron test can be see in the reference below. If the
lag.short = TRUE, we use the default number of Newey-West lags
floor(4*(length(x)/100)^0.25),
otherwise floor(12*(length(x)/100)^0.25) to calculate the test statistics.
In order to calculate the test statistic, we consider
three types of linear regression models. The first type (type1) is the one
with no drift and linear trend with respect to time:
x[t] = ρ*x[t-1] + e[t],
where e[t] is an error term.
The second type (type2) is the one with drift but no linear trend:
x[t] = μ + ρ*x[t-1] + e[t].
The third type (type3) is the one with both drift and linear trend:
x[t] = μ + α*t + ρ*x[t-1] + e[t].
The p.value is calculated by the interpolation of test statistics from the critical values
tables (Table 10.A.1 for Z_rho and 10.A.2 for Z_tau in Fuller (1996))
with a given sample size n = length(x).
Value
A matrix for test results with three columns (lag,Z_rho
or Z_tau, p.value) and three rows (type1, type2, type3).
Each row is the test results (including lag parameter, test statistic and p.value) for
each type of linear equation.
Note
Missing values are removed.
Author(s)
Debin Qiu
References
Phillips, P. C. B.; Perron, P. (1988). Testing for a Unit Root in Time Series Regression. Biometrika, 75 (2): 335-346.
Fuller, W. A. (1996). Introduction to statistical time series, second ed., Wiley, New York.
See Also
adf.test, kpss.test, stationary.test
Examples
1 2 3 4 5 6 |
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