Author :
Viterbi, Andrew J. ; Wolf, Jack K. ; Zehavi, Ephraim ; Padovani, Roberto
Abstract :
Since the early 1970s, for power-limited applications, the convolutional code constraint length K=7 and rate 1/2, optimum in the sense of maximum free distance and minimum number of bit errors caused by remerging paths at the free distance, has become the de facto standard for coded digital communication. This was reinforced when punctured versions of this code became the standard for rate 3/4 and 7/8 codes for moderately bandlimited channels. Methods are described for using the same K=7, rate 1/2 convolutional code with signal phase constellations of 8-PSK and 160PSK and quadrature amplitude constellations of 16-QASK, 64-QASK, and 256-QASK to achieve, respectively, 2 and 3, and 2, 4, and 6 b/s/Hz bandwidth efficiencies while providing power efficiency that in most cases is virtually equivalent to that of the best Ungerboeck codes for constraint length 7 or 64 states. This pragmatic approach to all coding applications permits the use of a single basic coder and decoder to achieve respectable coding (power) gains for bandwidth efficiencies from 1 b/s/Hz to 6 b/s/Hz.<>
Keywords :
amplitude modulation; encoding; error correction codes; phase shift keying; 16-QASK; 160PSK; 256-QASK; 64-QASK; 8-PSK; Ungerboeck codes; amplitude shift keying; bandlimited channels; bandwidth efficiency; coding; constraint length; convolutional code; digital communication; maximum free distance; minimum number of bit errors; phase shift keying; power efficiency; pragmatic approach; quadrature amplitude constellations; signal phase constellations; trellis-coded modulation; Amplitude shift keying; Bandwidth; Block codes; Convolution; Convolutional codes; Forward error correction; Information rates; Modulation coding; Quadrature phase shift keying; Transponders;
