Abstract
This paper considers the problem of adaptive estimation of graph signals under the impulsive noise environment. The existing least mean squares (LMS) approach suffers from severe performance degradation under an impulsive environment that widely occurs in various practical applications. We present a novel adaptive estimation over graphs based on Welsch loss (WL-G) to handle the problems related to impulsive interference. The proposed WL-G algorithm can efficiently reconstruct graph signals from the observations with impulsive noises by formulating the reconstruction problem as an optimization based on Welsch loss. An analysis on the performance of the WL-G is presented to develop effective sampling strategies for graph signals. A novel graph sampling approach is also proposed and used in conjunction with the WL-G to tackle the time-varying case. The performance advantages of the proposed WL-G over the existing LMS regarding graph signal reconstruction under impulsive noise environment are demonstrated.
Highlights
We present an adaptive graph sampling (AGS) technique, which is used in conjunction with the WL-G to determine the signal support
We propose the WL-G algorithm for adaptive graph signal reconstruction with impulsive noise in this work
Different to existing least mean squares (LMS) methods, which are based on the least-squares criterion, the proposed WL-G leverages the use of Welsch loss to formulate its cost function
Summary
The area of graph signal processing (GSP) has received extensive attention [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18]. The objective of GSP is to use the tools in DSP to the irregular domain in which the relationship between the elements are characterized via the graph. Under this framework, a signal occurring at graph nodes is handled over the graph topology. Let A be the graph adjacency matrix whose ith entry is aij representing the edge weight from node i to node j.
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