Title :
Constrained Turbo Block Convolutional Codes for 100 G and Beyond Optical Transmissions
Author :
Sang Ik Han ; Fonseka, John P. ; Dowling, Eric M.
Author_Institution :
Dept. of Electr. Eng., Univ. of Texas at Dallas, Richardson, TX, USA
Abstract :
Constrained turbo block convolutional (CTBC) codes are developed for 100 G and beyond optical transmissions. The CTBC codes developed herein each fit within one optical transport network (OTN) frame. The CTBC codes involve a simple outer block code that is serially concatenated with a simple inner recursive convolutional code using a constrained interleaver that simultaneously delivers a high interleaver gain and a high minimum Hamming distance. Codes with 11.1 dB net coding gain (NCG) at 12.5% overhead (OH), 11.3 dB NCG at 15% OH, 11.6 dB NCG at 20% OH, and 11.9 dB NCG at 23.4% OH are reported. Compared with other codes that have been previously proposed for OTN applications, CTBC codes have much lower encoding/decoding complexity, improved NCG/OH tradeoffs, and avoid negative error floor effects.
Keywords :
Hamming codes; block codes; concatenated codes; convolutional codes; decoding; interleaved codes; optical fibre networks; turbo codes; Hamming distance; constrained interleaver; constrained turbo block convolutional codes; encoding-decoding complexity; interleaver gain; net coding gain; optical transmission; optical transport network frame; simple inner recursive convolutional code; simple outer block code; Complexity theory; Convolutional codes; Decoding; Forward error correction; Iterative decoding; Magnetohydrodynamics; 100 G and beyond transmissions; FEC design; Optical transport network; forward error correcting codes;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2311998
