Title :
Stream-oriented turbo codes
Author :
Hall, Eric K. ; Wilson, Stephen G.
Author_Institution :
L-3 Commun., Salt Lake City, UT, USA
fDate :
7/1/2001 12:00:00 AM
Abstract :
This work considers the design and performance of a stream-oriented approach to turbo codes which avoids the need for data framing. The stream paradigm applies to both serial and parallel turbo codes using continuous, free-running constituent encoders along with continuous, periodic interleavers. A stream-oriented turbo code based on parallel concatenated convolutional codes (PCCC) is considered and interleaver design criteria are developed for both block and nonblock periodic interleavers. Specifically, several nonblock interleavers, including convolutional interleavers, are considered. Interleaver design rules are verified using simulations where it is shown that nonblock interleavers with small-to-moderate delay and small synchronization ambiguity can outperform block interleavers of comparable delay. For large-delay designs, nonblock interleavers are found which perform within 0.8 dB of the capacity limit with a synchronization ambiguity of N=11
Keywords :
convolutional codes; interleaved codes; iterative decoding; synchronisation; turbo codes; block periodic interleaver; capacity limit; continuous free-running constituent encoders; continuous periodic interleavers; convolutional interleavers; delay; interleaver design; iterative decoding; nonblock periodic interleaver; parallel concatenated convolutional codes; parallel turbo codes; performance; serial turbo codes; simulations; stream paradigm; stream-oriented turbo codes; synchronization ambiguity; Block codes; Channel coding; Circuits; Concatenated codes; Convolutional codes; Delay; Encoding; Interleaved codes; Iterative decoding; Turbo codes;
Journal_Title :
Information Theory, IEEE Transactions on
