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Robust recovery of bandlimited graph signals via randomized dynamical sampling

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arxiv 2109.14079 v2 pith:PW3KYIVZ submitted 2021-09-28 cs.IT cs.NAmath.ITmath.NAstat.CO

Robust recovery of bandlimited graph signals via randomized dynamical sampling

classification cs.IT cs.NAmath.ITmath.NAstat.CO
keywords samplingspace-timedynamicalsamplesbandlimitedrecoverygraphgraphs
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Heat diffusion processes have found wide applications in modelling dynamical systems over graphs. In this paper, we consider the recovery of a $k$-bandlimited graph signal that is an initial signal of a heat diffusion process from its space-time samples. We propose three random space-time sampling regimes, termed dynamical sampling techniques, that consist in selecting a small subset of space-time nodes at random according to some probability distribution. We show that the number of space-time samples required to ensure stable recovery for each regime depends on a parameter called the spectral graph weighted coherence, that depends on the interplay between the dynamics over the graphs and sampling probability distributions. In optimal scenarios, no more than $\mathcal{O}(k \log(k))$ space-time samples are sufficient to ensure accurate and stable recovery of all $k$-bandlimited signals. In any case, dynamical sampling typically requires much fewer spatial samples than the static case by leveraging the temporal information. Then, we propose a computationally efficient method to reconstruct $k$-bandlimited signals from their space-time samples. We prove that it yields accurate reconstructions and that it is also stable to noise. Finally, we test dynamical sampling techniques on a wide variety of graphs. The numerical results support our theoretical findings and demonstrate the efficiency.

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