Anytime reliability of spatially coupled codes

Md Noor-A-Rahim; Khoa D. Nguyen; Gottfried Lechner

doi:10.1109/TCOMM.2015.2406697

Anytime reliability of spatially coupled codes

Md Noor-A-Rahim
, Khoa D. Nguyen
, Gottfried Lechner

University of South Australia

Research output: Contribution to journal › Article › peer-review

Abstract

Anytime transmission was previously shown to be necessary and sufficient for tracking and controlling an unstable plant over a noisy channel. In this paper, we propose an efficient channel coding scheme for anytime transmission. We design this coding scheme based on spatially coupled codes and investigate its performance over binary erasure channels (BEC) and binary input additive white Gaussian noise (BIAWGN) channels. Through density evolution analysis, we asymptotically show the desired anytime properties of the proposed code. For the BEC, we derive the corresponding delay-exponent and numerically predict the finite-length performance of the proposed anytime code. We also propose adaptive window decoding techniques to ensure low complexity anytime receivers.

Original language	English
Article number	7047734
Pages (from-to)	1069-1080
Number of pages	12
Journal	IEEE Transactions on Communications
Volume	63
Issue number	4
DOIs	https://doi.org/10.1109/TCOMM.2015.2406697
Publication status	Published - 1 Apr 2015
Externally published	Yes

Keywords

anytime codes
anytime reliability
AWGN
BEC
channel
Spatially coupled LDPC codes

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10.1109/TCOMM.2015.2406697

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title = "Anytime reliability of spatially coupled codes",

abstract = "Anytime transmission was previously shown to be necessary and sufficient for tracking and controlling an unstable plant over a noisy channel. In this paper, we propose an efficient channel coding scheme for anytime transmission. We design this coding scheme based on spatially coupled codes and investigate its performance over binary erasure channels (BEC) and binary input additive white Gaussian noise (BIAWGN) channels. Through density evolution analysis, we asymptotically show the desired anytime properties of the proposed code. For the BEC, we derive the corresponding delay-exponent and numerically predict the finite-length performance of the proposed anytime code. We also propose adaptive window decoding techniques to ensure low complexity anytime receivers.",

keywords = "anytime codes, anytime reliability, AWGN, BEC, channel, Spatially coupled LDPC codes",

author = "Md Noor-A-Rahim and Nguyen, \{Khoa D.\} and Gottfried Lechner",

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AU - Nguyen, Khoa D.

AU - Lechner, Gottfried

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N2 - Anytime transmission was previously shown to be necessary and sufficient for tracking and controlling an unstable plant over a noisy channel. In this paper, we propose an efficient channel coding scheme for anytime transmission. We design this coding scheme based on spatially coupled codes and investigate its performance over binary erasure channels (BEC) and binary input additive white Gaussian noise (BIAWGN) channels. Through density evolution analysis, we asymptotically show the desired anytime properties of the proposed code. For the BEC, we derive the corresponding delay-exponent and numerically predict the finite-length performance of the proposed anytime code. We also propose adaptive window decoding techniques to ensure low complexity anytime receivers.

AB - Anytime transmission was previously shown to be necessary and sufficient for tracking and controlling an unstable plant over a noisy channel. In this paper, we propose an efficient channel coding scheme for anytime transmission. We design this coding scheme based on spatially coupled codes and investigate its performance over binary erasure channels (BEC) and binary input additive white Gaussian noise (BIAWGN) channels. Through density evolution analysis, we asymptotically show the desired anytime properties of the proposed code. For the BEC, we derive the corresponding delay-exponent and numerically predict the finite-length performance of the proposed anytime code. We also propose adaptive window decoding techniques to ensure low complexity anytime receivers.

KW - anytime codes

KW - anytime reliability

KW - AWGN

KW - BEC

KW - channel

KW - Spatially coupled LDPC codes

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JO - IEEE Transactions on Communications

JF - IEEE Transactions on Communications

IS - 4

M1 - 7047734

ER -

Anytime reliability of spatially coupled codes

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Keywords

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