Title :
Trellis complexity versus the coding gain of lattices. II
Author :
Tarakh, V. ; Blake, Ian F.
Author_Institution :
Dept. of Electr. & Comput. Eng., Waterloo Univ., Ont., Canada
fDate :
11/1/1996 12:00:00 AM
Abstract :
For pt.I see ibid., vol. 42, no.6, p.1796-1802, 1996. Every rational lattice has a finite trellis diagram which can be employed for maximum-likelihood decoding over the additive white Gaussian noise channel via the Viterbi algorithm. For an arbitrary rational lattice L with gain γ, the average number of states (respectively, branches) in any given trellis diagram of L is bounded below by a function of γ. It is proved that this function grows exponentially in γ. In the reverse direction, it is proved that given ∈>0, for arbitrarily large values of γ, there exist lattices of gain γ with an average number of branches and states less than exp(γ(1+∈)). Trellis diagrams of block codes obtained from truncated convolutional codes are employed to show that, inside the trellis model, the problem of decoding lattices is not much harder than exponential
Keywords :
Gaussian channels; Viterbi decoding; block codes; convolutional codes; encoding; maximum likelihood decoding; Viterbi algorithm; additive white Gaussian noise channel; block codes; branches; coding gain; finite trellis diagram; lattice decoding; maximum-likelihood decoding; rational lattice; states; trellis complexity; truncated convolutional codes; Additive white noise; Application software; Block codes; Councils; Differential equations; Information theory; Laboratories; Lattices; Maximum likelihood decoding; Viterbi algorithm;
Journal_Title :
Information Theory, IEEE Transactions on
