Achievable Entanglement-Assisted Communication Rate using Phase-Modulated Two-Mode Squeezed Vacuum

TL;DR

This paper derives a non-asymptotic, closed-form achievable rate for entanglement-assisted classical communication over a lossy thermal-noise bosonic channel using phase-modulated Two-Mode Squeezed Vacuum, linking physical parameters with information-theoretic limits.

Contribution

It provides the first analytical bound for the von Neumann entropy of phase-modulated TMSV states, enabling practical rate calculations for quantum communication channels.

Findings

Achievable rate depends on mean signal and noise photon numbers and channel transmissivity.

As PSK modulation size increases, the state converges to a diagonal Fock basis state.

Derived bounds facilitate understanding of entanglement-assisted communication limits.

Abstract

We derive a closed-form achievable rate for entanglement-assisted classical communication over a lossy thermal-noise bosonic channel, where the entanglement is in the form of a Two-Mode Squeezed Vacuum (TMSV) modulation restricted to Phase Shift Keying (PSK). The achievable rate is non-asymptotic in terms of the mean signal photon number, mean noise photon number, and transmissivity defining the communication channel, which provides insights into the interplay of these physical parameters and bridges recent experimental demonstrations of entanglement-assisted communications with the coding theorems used in information-theoretic proofs. The key challenge we address is deriving an analytical bound for the von Neumann entropy of the non-Gaussian mixed state resulting from the phase modulation of one arm of a TMSV. Our approach hinges on two key observations: 1) as the size of the PSK modulation increases, the resulting mixed state converges in trace distance to a diagonal state in the Fock basis; 2) the Fock-basis representation of the diagonal state involves hypergeometric functions that can be appropriately bounded to offer a tractable lower bound for the Holevo information.