Title :
Staircase Codes With 6% to 33% Overhead
Author :
Zhang, Lei M. ; Kschischang, Frank R.
Author_Institution :
Edward S. Rogers Sr. Dept. of Electr. & Comput. Eng., Univ. of Toronto, Toronto, ON, Canada
Abstract :
We design staircase codes with overheads between 6.25% and 33.3% for high-speed optical transport networks. Using a reduced-complexity simulation of staircase coded transmission over the BSC, we select code candidates from within a limited parameter space. Software simulations of coded BSC transmission are performed with algebraic component code decoders. The net coding gain of the best code designs are competitive with the best known hard-decision decodable codes over the entire range of overheads. At 20% overhead, staircase codes are within 0.92 dB of BSC capacity at a bit error-rate of 10-15. Decoding complexity and latency of the new staircase codes are also significantly reduced from existing hard-decision decodable schemes.
Keywords :
codes; decoding; high-speed optical techniques; optical fibre networks; telecommunication standards; -complexity simulation; BSC; algebraic component code decoders; bit error-rate; decoding complexity; hard-decision decodable codes; high-speed optical transport networks; net coding gain; overheads; staircase codes; Adaptive optics; Complexity theory; Decoding; Encoding; Forward error correction; High-speed optical techniques; Iterative decoding; Fiber-optic communications; forward error-correction (FEC); high-speed optical transport network; staircase codes; syndrome decoder;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2014.2316732
