Performance evaluation of the maximum complex correntropy criterion with adaptive kernel width update

The complex correntropy is a recently defined similarity measure that extends the advantages of conventional correntropy to complex-valued data. As in the real-valued case, the maximum complex correntropy criterion (MCCC) employs a free parameter called kernel width, which affects the convergence ra...

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Bibliographic Details
Published in:EURASIP journal on advances in signal processing 2019-11, Vol.2019 (1), p.1-10, Article 53
Main Authors: Aquino, Manoel B. L., F. Guimarães, João P., Linhares, Leandro L. S., Fontes, Aluísio I. R., Martins, Allan M.
Format: Article
Language:English
Subjects:
Adaptive algorithms
Adaptive filter
Adaptive kernel width
Algorithms
Analysis
Complex-valued data
Computer simulation
Convergence
Criteria
Engineering
Kernels
Maximum complex correntropy criterion (MCCC)
Parameters
Performance enhancement
Performance evaluation
Quantum Information Technology
Signal,Image and Speech Processing
Spintronics
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Summary:The complex correntropy is a recently defined similarity measure that extends the advantages of conventional correntropy to complex-valued data. As in the real-valued case, the maximum complex correntropy criterion (MCCC) employs a free parameter called kernel width, which affects the convergence rate, robustness, and steady-state performance of the method. However, determining the optimal value for such parameter is not always a trivial task. Within this context, several works have introduced adaptive kernel width algorithms to deal with this free parameter, but such solutions must be updated to manipulate complex-valued data. This work reviews and updates the most recent adaptive kernel width algorithms so that they become capable of dealing with complex-valued data using the complex correntropy. Besides that, a novel gradient-based solution is introduced to the Gaussian kernel and its respective convergence analysis. Simulations compare the performance of adaptive kernel width algorithms with different fixed kernel sizes in an impulsive noise environment. The results show that the iterative kernel adjustment improves the performance of the gradient solution for complex-valued data.
ISSN:1687-6180
1687-6172
1687-6180
DOI:10.1186/s13634-019-0652-2