Extreme Compressed Sensing of Poisson Rates from Multiple Measurements

TL;DR

This paper introduces SPoRe, a novel compressed sensing algorithm tailored for sparse Poisson signals in microfluidics, demonstrating superior performance in low-measurement, high-noise scenarios with theoretical guarantees.

Contribution

The paper presents the first MMV compressed sensing method specifically designed for Poisson-distributed signals, leveraging their structure for improved recovery.

Findings

SPoRe outperforms existing CS algorithms in Poisson signal recovery.

High performance achieved even with one-dimensional measurements and high noise.

Theoretical analysis confirms identifiability and system performance insights.

Abstract

Compressed sensing (CS) is a signal processing technique that enables the efficient recovery of a sparse high-dimensional signal from low-dimensional measurements. In the multiple measurement vector (MMV) framework, a set of signals with the same support must be recovered from their corresponding measurements. Here, we present the first exploration of the MMV problem where signals are independently drawn from a sparse, multivariate Poisson distribution. We are primarily motivated by a suite of biosensing applications of microfluidics where analytes (such as whole cells or biomarkers) are captured in small volume partitions according to a Poisson distribution. We recover the sparse parameter vector of Poisson rates through maximum likelihood estimation with our novel Sparse Poisson Recovery (SPoRe) algorithm. SPoRe uses batch stochastic gradient ascent enabled by Monte Carlo approximations of otherwise intractable gradients. By uniquely leveraging the Poisson structure, SPoRe substantially outperforms a comprehensive set of existing and custom baseline CS algorithms. Notably, SPoRe can exhibit high performance even with one-dimensional measurements and high noise levels. This resource efficiency is not only unprecedented in the field of CS but is also particularly potent for applications in microfluidics in which the number of resolvable measurements per partition is often severely limited. We prove the identifiability property of the Poisson model under such lax conditions, analytically develop insights into system performance, and confirm these insights in simulated experiments. Our findings encourage a new approach to biosensing and are generalizable to other applications featuring spatial and temporal Poisson signals.