On Approaching the Ultimate Limits of Photon-Efficient and Bandwidth-Efficient Optical Communication

TL;DR

This paper analyzes the fundamental limits of photon and bandwidth efficiency in optical communication, comparing known modulation schemes to quantum limits, and explores adaptive measurement strategies like the Dolinar receiver.

Contribution

It provides a detailed comparison of existing modulation schemes against the quantum limit and introduces adaptive measurement techniques for improved information efficiency.

Findings

Known structures fall short of maximum DIE by a factor increasing with PIE.

The capacity of the Dolinar receiver is derived and applied to OOK.

Adaptive Dolinar receiver does not outperform independent symbol measurements.

Abstract

It is well known that ideal free-space optical communication at the quantum limit can have unbounded photon information efficiency (PIE), measured in bits per photon. High PIE comes at a price of low dimensional information efficiency (DIE), measured in bits per spatio-temporal-polarization mode. If only temporal modes are used, then DIE translates directly to bandwidth efficiency. In this paper, the DIE vs. PIE tradeoffs for known modulations and receiver structures are compared to the ultimate quantum limit, and analytic approximations are found in the limit of high PIE. This analysis shows that known structures fall short of the maximum attainable DIE by a factor that increases linearly with PIE for high PIE. The capacity of the Dolinar receiver is derived for binary coherent-state modulations and computed for the case of on-off keying (OOK). The DIE vs. PIE tradeoff for this case is improved only slightly compared to OOK with photon counting. An adaptive rule is derived for an additive local oscillator that maximizes the mutual information between a receiver and a transmitter that selects from a set of coherent states. For binary phase-shift keying (BPSK), this is shown to be equivalent to the operation of the Dolinar receiver. The Dolinar receiver is extended to make adaptive measurements on a coded sequence of coherent state symbols. Information from previous measurements is used to adjust the a priori probabilities of the next symbols. The adaptive Dolinar receiver does not improve the DIE vs. PIE tradeoff compared to independent transmission and Dolinar reception of each symbol.