Kernel Adaptive Filtering Over Complex Networks

This brief is concerned with the problem of kernel adaptive filtering for a complex network. First, a coupled kernel least mean square (KLMS) algorithm is developed for each node to uncover its nonlinear measurement function by using a series of input-output data. Subsequently, an upper bound is derived for the step-size of the coupled KLMS algorithm to guarantee the mean square convergence. It is shown that the upper bound is dependent on the coupling weights of the complex network. Especially, an optimal step size is obtained to achieve the fastest convergence speed and a suboptimal step size is presented for the purpose of practical implementations. Besides, a coupled kernel recursive least square (KRLS) algorithm is further proposed to improve the filtering performance. Finally, simulations are provided to verify the validity of the theoretical results.

Automated summary

This paper focuses on the problem of kernel adaptive filtering for a complex network. It proposes a coupled KLMS algorithm and a coupled KRLS algorithm to improve the filtering performance. The validity and convergence of the algorithms are demonstrated through theoretical analysis and simulation.