Performance limits of a quantum receiver for detecting phase-modulated communication signals

TL;DR

This paper evaluates the performance of quantum sensors in detecting phase-modulated signals, comparing quantum and classical limits, and explores how quantum protocols can enhance data recovery in noisy conditions.

Contribution

It introduces a generalized cumulant expansion for modeling noisy quantum receivers and compares quantum demodulation protocols, highlighting potential capacity advantages over classical systems.

Findings

Quantum sensors can surpass classical antenna limits under certain conditions.

Quantum protocols enable high-fidelity data recovery despite noise.

Analysis focused on NV-diamond quantum sensors.

Abstract

Quantum sensors are an ideal candidate for detecting weak electromagnetic signals because of their exceptional sensitivity and compact form factor. In this work, we analyze the performance of a quantum-sensor-based receive chain for demodulating information encoded in phase-modulated electromagnetic waves. We introduce a generalized cumulant expansion to model a noisy quantum receiver and use it to compare the performance of various quantum demodulation protocols. Employing bit error probability (BEP) and channel capacity as quantitative performance metrics, we compare the capabilities of ensembles of quantum sensors - both unentangled and entangled - using Binary Phase-Shift Keying (BPSK) as a representative example of phase modulation. We identify conditions when the channel capacity of an ensemble of quantum sensors may surpass the limits of a classical electrically small antenna. Additionally, we discuss modifications to the quantum protocol that enables high-fidelity data recovery even in the presence of sensor noise and channel distortions. Finally, we explore practical performance limits of such a quantum receive chain, with a focus on NV-diamond as the quantum sensor platform.