Title :
Can Punctured Rate-1/2 Turbo Codes Achieve a Lower Error Floor than their Rate-1/3 Parent Codes?
Author :
Chatzigeorgiou, Joannis ; Rodrigues, Miguel R D ; Wassell, Ian J. ; Carrasco, Rolando
Author_Institution :
Comput. Lab., Cambridge Univ.
Abstract :
In this paper we concentrate on rate-1/3 systematic parallel concatenated convolutional codes and their rate-1/2 punctured child codes. Assuming maximum-likelihood decoding over an additive white Gaussian channel, we demonstrate that a rate-1/2 non-systematic child code can exhibit a lower error floor than that of its rate-1/3 parent code, if a particular condition is met. However, assuming iterative decoding, convergence of the non-systematic code towards low bit-error rates is problematic. To alleviate this problem, we propose rate-1/2 partially-systematic codes that can still achieve a lower error floor than that of their rate-1/3 parent codes. Results obtained from extrinsic information transfer charts and simulations support our conclusion
Keywords :
AWGN channels; concatenated codes; convolutional codes; error statistics; iterative decoding; maximum likelihood decoding; turbo codes; additive white Gaussian channel; bit-error rates; iterative decoding; maximum-likelihood decoding; punctured child codes; punctured rate-1/2 turbo codes; rate-1/3 parent codes; systematic parallel concatenated convolutional codes; AWGN; Concatenated codes; Convergence; Convolutional codes; Error probability; Information theory; Iterative decoding; Maximum likelihood decoding; Parity check codes; Turbo codes;
Conference_Titel :
Information Theory Workshop, 2006. ITW '06 Chengdu. IEEE
Conference_Location :
Chengdu
Print_ISBN :
1-4244-0067-8
Electronic_ISBN :
1-4244-0068-6
DOI :
10.1109/ITW2.2006.323763
