Iterative Coded Pulse-Position-Modulation for Deep-Space Optical Communications

Author

Barsoum, M.F. ; Moision, B. ; Fitz, Michael P.

Author_Institution

California Inst. of Technol., Pasadena

fYear

2007

fDate

2-6 Sept. 2007

Firstpage

66

Lastpage

71

Abstract

This paper presents and compares two iterative coded modulation techniques for deep-space optical communications using pulse-position modulation (PPM). The first code, denoted by SCPPM, consists of the serial concatenation of an outer convolutional code, an interleaver, a bit accumulator, and PPM. The second code, denoted by LDPC-PPM, consists of the serial concatenation of an LDPC code and PPM. We employ Extrinsic Information Transfer (EXIT) charts for their analysis and design. Under conditions typical of a communications link from Mars to Earth, SCPPM is 1 dB away from capacity, while LDPC-PPM is 1.4 dB away from capacity, at a Bit Error Rate (BER) of approximately 10^-5. However, LDPC-PPM lends itself naturally to low latency parallel processing in contrast to SCPPM.

Keywords

concatenated codes; convolutional codes; error statistics; interleaved codes; iterative methods; modulation coding; optical communication; optical links; optical modulation; pulse position modulation; space communication links; BER; LDPC-PPM; PPM; bit accumulator; bit error rate; communications link; deep-space optical communications; extrinsic information transfer; interleaver; iterative coded pulse-position-modulation; outer convolutional code; parallel processing; serial concatenation; Bit error rate; Convolutional codes; Earth; Information analysis; Mars; Modulation coding; Optical fiber communication; Optical pulses; Parity check codes; Pulse modulation;

fLanguage

English

Publisher

ieee

Conference_Titel

Information Theory Workshop, 2007. ITW '07. IEEE

Conference_Location

Tahoe City, CA

Print_ISBN

1-4244-1564-0

Electronic_ISBN

1-4244-1564-0

Type

conf

DOI

10.1109/ITW.2007.4313051

Filename

4313051