TY - JOUR
T1 - Towards a median signal detector through the total Bregman divergence and its robustness analysis
AU - Ono, Yusuke
AU - Peng, Linyu
N1 - Funding Information:
The authors thank Prof. Sergey Yurish for the kind invitation and for the hospitality during the ASPAI’2021 Conference, in which part of the work was presented [34] . The authors would also like to thank Xiaoqiang Hua and Hiroki Sato for helpful discussions and to the referees for the constructive comments. This work was partially supported by Japan Society for the Promotion of Science KAKENHI (No. JP20K14365 ), Japan Science and Technology Agency CREST (No. JPMJCR1914 ), and the Fukuzawa Fund of Keio University.
Publisher Copyright:
© 2022
PY - 2022/12
Y1 - 2022/12
N2 - A novel family of geometric signal detectors are proposed through medians of the total Bregman divergence (TBD), which are shown advantageous over the conventional methods and their mean counterparts. By interpreting the observation data as Hermitian positive-definite matrices, their mean or median play an essential role in signal detection. As is difficult to be solved analytically, we propose numerical solutions through Riemannian gradient descent algorithms or fixed-point algorithms. Beside detection performance, robustness of a detector to outliers is also of vital importance, which can often be analyzed via the influence functions. Introducing an orthogonal basis for Hermitian matrices, we are able to compute the corresponding influence functions analytically and exactly by solving a linear system, which is transformed from the governing matrix equation. Numerical simulations show that the TBD medians are more robust than their mean counterparts.
AB - A novel family of geometric signal detectors are proposed through medians of the total Bregman divergence (TBD), which are shown advantageous over the conventional methods and their mean counterparts. By interpreting the observation data as Hermitian positive-definite matrices, their mean or median play an essential role in signal detection. As is difficult to be solved analytically, we propose numerical solutions through Riemannian gradient descent algorithms or fixed-point algorithms. Beside detection performance, robustness of a detector to outliers is also of vital importance, which can often be analyzed via the influence functions. Introducing an orthogonal basis for Hermitian matrices, we are able to compute the corresponding influence functions analytically and exactly by solving a linear system, which is transformed from the governing matrix equation. Numerical simulations show that the TBD medians are more robust than their mean counterparts.
KW - Geometric median
KW - matrix-CFAR
KW - nonhomogeneous clutter
KW - robustness analysis
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U2 - 10.1016/j.sigpro.2022.108728
DO - 10.1016/j.sigpro.2022.108728
M3 - Article
AN - SCOPUS:85136115092
SN - 0165-1684
VL - 201
JO - Signal Processing
JF - Signal Processing
M1 - 108728
ER -