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Interstellar communication. I. Maximized data rate for lightweight space-probes

Published online by Cambridge University Press:  18 January 2018

Michael Hippke Open the ORCID record for Michael Hippke [Opens in a new window]
Michael Hippke*
Affiliation:
Sonneberg Observatory, Sternwartestr. 32, 96515 Sonneberg, Germany
*
Author for correspondence: Michael Hippke E-mail: hippke@ifda.eu
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Abstract

Recent technological advances could make interstellar travel possible, using ultra-lightweight sails pushed by lasers or solar photon pressure, at speeds of a few per cent the speed of light. Obtaining remote observational data from such probes is not trivial because of their minimal instrumentation (gram scale) and large distances (pc). We derive the optimal communication scheme to maximize the data rate between a remote probe and home-base. The framework requires coronagraphic suppression of the stellar background at the level of 10−9 within a few tenths of an arcsecond of the bright star. Our work includes models for the loss of photons from diffraction, technological limitations, interstellar extinction and atmospheric transmission. Major noise sources are atmospheric, zodiacal, stellar and instrumental. We examine the maximum capacity using the ‘Holevo bound’ which gives an upper limit to the amount of information (bits) that can be encoded through a quantum state (photons), which is a few bits per photon for optimistic signal and noise levels. This allows for data rates of the order of bits per second per Watt from a transmitter of size 1 m at a distance of α Centauri (1.3 pc) to an earth-based large receiving telescope (E-ELT, 39 m). The optimal wavelength for this distance is 300 nm (space-based receiver) to 400 nm (earth-based) and increases with distance, due to extinction, to a maximum of ≈ 3 μm to the centre of the Galaxy at 8 kpc.

Keywords

Atmospheric absorptionbreakthrough starshotinterstellar communicationinterstellar extinction
Type
Research Article
Information
International Journal of Astrobiology , Volume 18 , Issue 3 , June 2019 , pp. 267 - 279
Copyright
Copyright © Cambridge University Press 2018 

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