Attaining the quantum limit of passive imaging

TL;DR

This paper demonstrates a structured optical receiver that achieves the quantum limit in passive imaging, distinguishing between one or two closely spaced incoherent sources with minimal error, matching the quantum Chernoff bound.

Contribution

The authors design a mode-resolved receiver that attains the quantum Chernoff bound, providing the first explicit realization reaching the quantum limit in this imaging problem.

Findings

The mode-resolved receiver achieves the quantum Chernoff bound.

Classical focal plane array performance is significantly below the quantum limit.

Explicit structured receiver matches the theoretical quantum bound.

Abstract

We consider the problem, where a camera is tasked with determining one of two hypotheses: first with an incoherently-radiating quasi-monochromatic point source and the second with two identical closely spaced point sources. We are given that the total number of photons collected over an integration time is assumed to be the same under either hypothesis. For the one-source hypothesis, the source is taken to be on-axis along the line of sight and for the two-source hypothesis, we give ourselves the prior knowledge of the angular separation of the sources, and they are assumed to be identical and located symmetrically off-axis. This problem was studied by Helstrom in 1973, who evaluated the probability of error achievable using a sub-optimal optical measurement, with an unspecified structured realization. In this paper, we evaluate the quantum Chernoff bound, a lower bound on the minimum probability of error achievable by any physically-realizable receiver, which is exponentially tight in the regime that the integration time is high. We give an explicit structured receiver that separates three orthogonal spatial modes of the aperture field followed by quantum-noise-limited time-resolved photon measurement and show that this achieves the quantum Chernoff bound. In other words, the classical Chernoff bound of our mode-resolved detector exactly matches the quantum Chernoff bound for this problem. Finally, we evaluate the classical Chernoff bound on the error probability achievable using an ideal focal plane array---a signal shot-noise limited continuum photon-detection receiver with infinitely many infinitesimally-tiny pixels---and quantify its performance gap with the quantum limit.