Published April 20, 2026 | Version v1

Quantum Optical Integrated Sensing and Communication with Homodyne BPSK Detection

Authors/Creators

  • 1. University of Cyprus
  • 2. IRIDA, ECE, UCY

Description

In this letter, we propose a quantum integrated sensing and communication scheme for a quantum optical link using binary phase-shift keying modulation and homodyne detection. The link operates over a phase-insensitive Gaussian channel with an unknown deterministic phase rotation, where the homodyne receiver jointly carries out symbol detection and phase estimation. We formulate a design problem that minimizes the bit-error rate subject to a Fisher information-based constraint on estimation accuracy. To solve it, we develop an iterative algorithm composed of an inner expectation-maximization loop for joint detection and estimation and an outer loop that adaptively retunes the local oscillator phase. Numerical results confirm the effectiveness of the proposed approach and demonstrate a fundamental trade-off between communication reliability and sensing accuracy.

Notes

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Files

Quantum Optical Integrated Sensing and Communication with Homodyne BPSK Detection.pdf

Additional details

Funding

European Research Council
PoC QUARTO 101241675
European Commission
iSEE-6G - Integrated SEnsing, Energy and communication for 6G networks 101139291