Efficient Sampling Allocation Strategies for General Graph-Filter-Based Signal Recovery
Abstract
Sensor placement plays a crucial role in graph signal recovery in underdetermined systems. In this paper, we present the graph-filtered regularized maximum likelihood (GFR-ML) estimator of graph signals, which integrates general graph filtering with regularization to enhance signal recovery performance under a limited number of sensors. Then, we investigate task-based sampling allocation aimed at minimizing the mean squared error (MSE) of the GFR-ML estimator by wisely choosing sensor placement. Since this MSE depends on the unknown graph signals to be estimated, we propose four cost functions for the optimization of the sampling allocation: the biased Cramr-Rao bound (bCRB), the worst-case MSE (WC-MSE), the Bayesian MSE (BMSE), and the worst-case BMSE (WC-BMSE), where the last two assume a Gaussian prior. We investigate the properties of these cost functions and develop two algorithms for their practical implementation: 1) the straightforward greedy algorithm; and 2) the alternating projection gradient descent (PGD) algorithm that reduces the computational complexity. Simulation results on synthetic and real-world datasets of the IEEE 118-bus power system and the Minnesota road network demonstrate that, in the tested scenarios, the proposed sampling allocation methods reduce the MSE by up to compared to the common sampling methods A-design, E-design, and LR-design. Thus, the proposed methods improve the estimation performance and reduce the required number of measurements in graph signal processing (GSP)-based signal recovery in the case of underdetermined systems.
Cite
@article{arxiv.2502.05583,
title = {Efficient Sampling Allocation Strategies for General Graph-Filter-Based Signal Recovery},
author = {Lital Dabush and Tirza Routtenberg},
journal= {arXiv preprint arXiv:2502.05583},
year = {2025}
}
Comments
This work has been submitted to the IEEE for possible publication