End-to-end interstellar communication system design for power efficiency

TL;DR

This paper develops a power-efficient design for interstellar communication systems, establishing fundamental limits and proposing practical principles that maximize information rate relative to power, with implications for SETI signal detection.

Contribution

It introduces a set of five design principles for power-efficient interstellar communication that approach fundamental limits and differ from current SETI signal characteristics.

Findings

Fundamental limit to reliable communication is noise-limited.

Power-efficient signals have wide bandwidth and sparse energy distribution.

Detection strategies can be adapted for these power-efficient signals.

Abstract

Radio communication over interstellar distances is studied, accounting for noise, dispersion, scattering and motion. Large transmitted powers suggest maximizing power efficiency (ratio of information rate to average signal power) as opposed to restricting bandwidth. The fundamental limit to reliable communication is determined, and is not affected by carrier frequency, dispersion, scattering, or motion. The available efficiency is limited by noise alone, and the available information rate is limited by noise and available average power. A set of five design principles (well within our own technological capability) can asymptotically approach the fundamental limit; no other civilization can achieve greater efficiency. Bandwidth can be expanded in a way that avoids invoking impairment by dispersion or scattering. The resulting power-efficient signals have characteristics very different from current SETI targets, with wide bandwidth relative to the information rate and a sparse distribution of energy in both time and frequency. Information-free beacons achieving the lowest average power consistent with a given receiver observation time are studied. They need not have wide bandwidth, but do distribute energy more sparsely in time as average power is reduced. The discovery of both beacons and information-bearing signals is analyzed, and most closely resembles approaches that have been employed in optical SETI. No processing is needed to account for impairments other than noise. A direct statistical tradeoff between a larger number of observations and a lower average power (including due to lower information rate) is established. The "false alarms" in current searches are characteristic signatures of these signals. Joint searches for beacons and information-bearing signals require straightforward modifications to current SETI pattern recognition approaches.