On Symmetrized Pearson's Type Test for Normality of Autoregression: Power under Local Alternatives

We consider a stationary linear AR($p$) model with observations subject to gross errors (outliers). The autoregression parameters as well as the distribution function (d.f.) $G$ of innovations are unknown. The distribution of outliers $\Pi$ is unknown and arbitrary, their intensity is $\gamma n^{-1/2}$ with an unknown $\gamma$, $n$ is the sample size. We test the hypothesis for normality of innovations $\mathbf{H}_\Phi \colon G \in \{\Phi(x/\theta),\,\theta>0\},$ $\Phi(x)$ is the d.f. $\mathbf{N}(0,1)$. Our test is the special symmetrized Pearson's type test. We find the power of this test under local alternatives $\mathbf{H}_{1n}(\rho)\colon G(x)=A_n(x):=(1-\rho n^{-1/2})\Phi(x/\theta_0)+\rho n^{-1/2}H(x),$ $\rho\geq 0,\,\theta_0$ is the unknown (under $\mathbf{H}_\Phi$) variance of innovations. First of all we estimate the autoregression parameters and then using the residuals from the estimated autoregression we construct a kind of empirical distribution function (r.e.d.f.), which is a counterpart of the (inaccessible) e.d.f. of the autoregression innovations. After this we construct the symmetrized variant r.e.d.f. Our test statistic is the functional from symmetrized r.e.d.f. We obtain a stochastic expansion of this symmetrized r.e.d.f. under $\mathbf{H}_{1n}(\rho)$ , which enables us to investigate our test. We establish qualitative robustness of this test in terms of uniform equicontinuity of the limiting power (as functions of $\gamma,\rho$ and $\Pi$) with respect to $\gamma$ in a neighborhood of $\gamma=0$.