Incremental redundancy: A comparison of a sphere-packing analysis and convolutional codes

Author

Chen, Tsung-Yi ; Seshadri, Nambi ; Wesel, Richard D.

Author_Institution

Dept. of Electr. Eng., Univ. of California, Los Angeles, Los Angeles, CA, USA

fYear

2011

fDate

6-11 Feb. 2011

Firstpage

1

Lastpage

5

Abstract

Theoretical analysis has long indicated that feedback improves the error exponent but not the capacity of memoryless Gaussian channels. Chen et al. demonstrated that a modified incremental redundancy scheme can use noiseless feedback to help short convolutional codes deliver the bit-error-rate performance of a long blocklength turbo code, but with much lower latency. This paper presents a code-independent analysis based on sphere-packing that approximates the throughput-vs.-latency achievable region possible with feedback and incremental redundancy for a specified AWGN SNR. Simulation results indicate that tail-biting convolutional codes employing feedback and incremental redundancy perform close to the sphere-packing approximation until the throughput reaches the limit of the system´s ability to approach the channel capacity.

Keywords

AWGN channels; channel capacity; channel coding; convolutional codes; feedback; memoryless systems; redundancy; turbo codes; AWGN SNR; bit-error-rate performance; blocklength turbo code; channel capacity; code-independent analysis; error exponent; memoryless Gaussian channels; modified incremental redundancy scheme; noiseless feedback; sphere-packing analysis; sphere-packing approximation; tail-biting convolutional codes; theoretical analysis; Approximation methods; Automatic repeat request; Convolutional codes; Decoding; Noise; Redundancy; Throughput;

fLanguage

English

Publisher

ieee

Conference_Titel

Information Theory and Applications Workshop (ITA), 2011

Conference_Location

La Jolla, CA

Print_ISBN

978-1-4577-0360-7

Type

conf

DOI

10.1109/ITA.2011.5743564

Filename

5743564