Theoretical Guarantees for Sparse Graph Signal Recovery

Gal Morgenstern; Tirza Routtenberg

doi:10.1109/LSP.2024.3514800

Theoretical Guarantees for Sparse Graph Signal Recovery

Gal Morgenstern, Tirza Routtenberg

Ben-Gurion University of the Negev

Research output: Contribution to journal › Article › peer-review

Abstract

Sparse graph signals have recently been utilized in graph signal processing (GSP) for tasks such as graph signal reconstruction, blind deconvolution, and sampling. In addition, sparse graph signals can be used to model real-world network applications across various domains, such as social, biological, and power systems. Despite the extensive use of sparse graph signals, limited attention has been paid to the derivation of theoretical guarantees on their recovery. In this paper, we present a novel theoretical analysis of the problem of recovering a node-domain sparse graph signal from the output of a first-order graph filter. The graph filter we study is the Laplacian matrix, and we derive upper and lower bounds on its mutual coherence. Our results establish a connection between the recovery performance and the minimal graph nodal degree. The proposed bounds are evaluated via simulations on the Erdőos-Rényi graph.

Original language	American English
Pages (from-to)	266-270
Number of pages	5
Journal	IEEE Signal Processing Letters
Volume	32
DOIs	https://doi.org/10.1109/LSP.2024.3514800
State	Published - 1 Jan 2025

Keywords

Graph signal processing
graph signals
Laplacian matrix
mutual coherence
sparse recovery
graph signal processing (GSP)

All Science Journal Classification (ASJC) codes

Signal Processing
Electrical and Electronic Engineering
Applied Mathematics

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10.1109/LSP.2024.3514800

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title = "Theoretical Guarantees for Sparse Graph Signal Recovery",

abstract = "Sparse graph signals have recently been utilized in graph signal processing (GSP) for tasks such as graph signal reconstruction, blind deconvolution, and sampling. In addition, sparse graph signals can be used to model real-world network applications across various domains, such as social, biological, and power systems. Despite the extensive use of sparse graph signals, limited attention has been paid to the derivation of theoretical guarantees on their recovery. In this paper, we present a novel theoretical analysis of the problem of recovering a node-domain sparse graph signal from the output of a first-order graph filter. The graph filter we study is the Laplacian matrix, and we derive upper and lower bounds on its mutual coherence. Our results establish a connection between the recovery performance and the minimal graph nodal degree. The proposed bounds are evaluated via simulations on the Erd{\H o}os-R{\'e}nyi graph.",

keywords = "Graph signal processing, graph signals, Laplacian matrix, mutual coherence, sparse recovery, graph signal processing (GSP)",

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doi = "10.1109/LSP.2024.3514800",

language = "American English",

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T1 - Theoretical Guarantees for Sparse Graph Signal Recovery

AU - Morgenstern, Gal

AU - Routtenberg, Tirza

PY - 2025/1/1

Y1 - 2025/1/1

N2 - Sparse graph signals have recently been utilized in graph signal processing (GSP) for tasks such as graph signal reconstruction, blind deconvolution, and sampling. In addition, sparse graph signals can be used to model real-world network applications across various domains, such as social, biological, and power systems. Despite the extensive use of sparse graph signals, limited attention has been paid to the derivation of theoretical guarantees on their recovery. In this paper, we present a novel theoretical analysis of the problem of recovering a node-domain sparse graph signal from the output of a first-order graph filter. The graph filter we study is the Laplacian matrix, and we derive upper and lower bounds on its mutual coherence. Our results establish a connection between the recovery performance and the minimal graph nodal degree. The proposed bounds are evaluated via simulations on the Erdőos-Rényi graph.

AB - Sparse graph signals have recently been utilized in graph signal processing (GSP) for tasks such as graph signal reconstruction, blind deconvolution, and sampling. In addition, sparse graph signals can be used to model real-world network applications across various domains, such as social, biological, and power systems. Despite the extensive use of sparse graph signals, limited attention has been paid to the derivation of theoretical guarantees on their recovery. In this paper, we present a novel theoretical analysis of the problem of recovering a node-domain sparse graph signal from the output of a first-order graph filter. The graph filter we study is the Laplacian matrix, and we derive upper and lower bounds on its mutual coherence. Our results establish a connection between the recovery performance and the minimal graph nodal degree. The proposed bounds are evaluated via simulations on the Erdőos-Rényi graph.

KW - Graph signal processing

KW - graph signals

KW - Laplacian matrix

KW - mutual coherence

KW - sparse recovery

KW - graph signal processing (GSP)

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U2 - 10.1109/LSP.2024.3514800

DO - 10.1109/LSP.2024.3514800

M3 - Article

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VL - 32

SP - 266

EP - 270

JO - IEEE Signal Processing Letters

JF - IEEE Signal Processing Letters

ER -

Theoretical Guarantees for Sparse Graph Signal Recovery

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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