Robust Inference for Change Points in High Dimension
Abstract
This paper proposes a new test for a change point in the mean of high-dimensional data based on the spatial sign and self-normalization. The test is easy to implement with no tuning parameters, robust to heavy-tailedness and theoretically justified with both fixed- and sequential asymptotics under both null and alternatives, where is the sample size. We demonstrate that the fixed- asymptotics provide a better approximation to the finite sample distribution and thus should be preferred in both testing and testing-based estimation. To estimate the number and locations when multiple change-points are present, we propose to combine the p-value under the fixed- asymptotics with the seeded binary segmentation (SBS) algorithm. Through numerical experiments, we show that the spatial sign based procedures are robust with respect to the heavy-tailedness and strong coordinate-wise dependence, whereas their non-robust counterparts proposed in Wang et al. (2022) appear to under-perform. A real data example is also provided to illustrate the robustness and broad applicability of the proposed test and its corresponding estimation algorithm.
Cite
@article{arxiv.2206.02738,
title = {Robust Inference for Change Points in High Dimension},
author = {Feiyu Jiang and Runmin Wang and Xiaofeng Shao},
journal= {arXiv preprint arXiv:2206.02738},
year = {2022}
}