Title :
A linear bound for sliding-block decoder window size
Author :
Ashley, Jonathan J.
Author_Institution :
IBM Almaden Res. Center, San Jose, CA, USA
fDate :
5/1/1988 12:00:00 AM
Abstract :
The author gives an upper bound on the necessary length of a sliding-block decoder window for finite-state codes from arbitrary n -ary data into any constrained system Σ with capacity at least log(n) presented by a graph G with memory m and anticipation a. Specifically, it is shown that the ACH code construction algorithm can be used to construct a code with a sliding-block decoder at rate t:t and with window length m+a+2t, where t is upper-bounded by a linear function of the number of states of G. It is demonstrated that this is the best one can do in the sense that any general upper bound on the decoder window length for finite-state codes into systems Σ with finite memory must grow at least linearly with the number of states of the graph G presenting Σ
Keywords :
decoding; ACH code construction algorithm; arbitrary n-ary data; capacity; constrained system; directed graphs; finite memory; finite-state codes; linear bound; sliding-block decoder window size; state splitting; upper bound; window length; Automata; Communication channels; Constraint theory; Decoding; Helium; Interference constraints; Intersymbol interference; Magnetic recording; Timing; Upper bound;
Journal_Title :
Information Theory, IEEE Transactions on
