TY - JOUR
T1 - Distributionally Robust Quickest Change Detection using Wasserstein Uncertainty Sets
AU - Xie, Liyan
AU - Liang, Yuchen
AU - Veeravalli, Venugopal V.
N1 - The work of Liyan Xie was partially supported by UDF01002142 and 2023SC0019 through the Chinese University of Hong Kong, Shenzhen. The work of Yuchen Liang and Venugopal V. Veeravalli was supported by the U.S. National Science Foundation under grant ECCS-2033900, and by the U.S. Army Research Laboratory under Cooperative Agreement W911NF-17-2-0196, through the University of Illinois at Urbana-Champaign.
PY - 2024
Y1 - 2024
N2 - The problem of quickest detection of a change in the distribution of streaming data is considered. It is assumed that the pre-change distribution is known, while the only information about the post-change is through a (small) set of labeled data. This post-change data is used in a data-driven minimax robust framework, where an uncertainty set for the post-change distribution is constructed. The robust change detection problem is studied in an asymptotic setting where the mean time to false alarm goes to infinity. It is shown that the least favorable distribution (LFD) is an exponentially tilted version of the pre-change density and can be obtained efficiently. A Cumulative Sum (CuSum) test based on the LFD, which is referred to as the distributionally robust (DR) CuSum test, is then shown to be asymptotically robust. The results are extended to the case with multiple post-change uncertainty sets and validated using synthetic and real data examples.
AB - The problem of quickest detection of a change in the distribution of streaming data is considered. It is assumed that the pre-change distribution is known, while the only information about the post-change is through a (small) set of labeled data. This post-change data is used in a data-driven minimax robust framework, where an uncertainty set for the post-change distribution is constructed. The robust change detection problem is studied in an asymptotic setting where the mean time to false alarm goes to infinity. It is shown that the least favorable distribution (LFD) is an exponentially tilted version of the pre-change density and can be obtained efficiently. A Cumulative Sum (CuSum) test based on the LFD, which is referred to as the distributionally robust (DR) CuSum test, is then shown to be asymptotically robust. The results are extended to the case with multiple post-change uncertainty sets and validated using synthetic and real data examples.
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M3 - Conference article
AN - SCOPUS:85194178527
SN - 2640-3498
VL - 238
SP - 1063
EP - 1071
JO - Proceedings of Machine Learning Research
JF - Proceedings of Machine Learning Research
T2 - 27th International Conference on Artificial Intelligence and Statistics, AISTATS 2024
Y2 - 2 May 2024 through 4 May 2024
ER -