Low-cost limit of classical communication with restricted quantum measurements

TL;DR

This paper develops a low-cost approximation framework for classical communication using quantum states, revealing bounds and enhancements in photon information efficiency for optical communication with coherent states.

Contribution

It introduces a systematic low-cost approximation method for analyzing quantum measurement schemes and demonstrates superadditivity in optical communication with practical measurement designs.

Findings

Photon information efficiency bounded by 2 nats per photon at low cost

Two- and three-symbol measurement schemes outperform individual measurements by ~3%

Framework enables scalable superadditive measurement design

Abstract

We consider a communication scenario where classical information is encoded in an ensemble of quantum states that admit a power series expansion in a cost parameter and with the vanishing cost converge to a single zero-cost state. For a given measurement scheme, we derive an approximate expression for mutual information in the leading order of the cost parameter. The general results are applied to selected problems in optical communication, where coherent states of light are used as input symbols and the cost is quantified as the average number of photons per symbol. We show that for an arbitrary individual measurement on phase shift keyed (PSK) symbols, the photon information efficiency is upper bounded by 2 nats of information per photon in the low-cost limit, which coincides with the conventional homodyne detection bound. The presented low-cost approximation facilitates a systematic analysis of few-symbol measurements that exhibit superadditivity of accessible information. For the binary PSK alphabet of coherent states, we present designs for two- and three-symbol measurement schemes based on linear optics, homodyning, and single photon detection that offer respectively 2.49% and 3.40% enhancement relative to individual measurements. We also show how designs for scalable superadditive measurement schemes emerge from the introduced low-cost formalism.