Title :
Binomial logic: extending stochastic computing to high-bandwidth signals
Author :
Kuehnel, Richard
Author_Institution :
Yakima Training Center, Yakima Res. Station, WA, USA
Abstract :
Stochastic logic, also known as stochastic computing, provides very low computation hardware area, fault tolerance, and efficient hardware implementations for high clock rates. It has long been defined as the processing of signals encoded as Bernoulli random sequences. This assumed definition has created its most notable restriction: the requirement to sample much faster than the Nyquist rate, severely limiting the allowable signal bandwidth. We demonstrate that stochastic logic can be extended beyond Bernoulli sequences to include binomial (N, p) representations where N > 1. By expanding the definition of stochastic computing we create a new design methodology that enables the engineer to obtain greater signal bandwidth by increasing the circuit size.
Keywords :
fault tolerant computing; logic programming; random processes; sequences; signal representation; signal sampling; stochastic programming; Bernoulli random sequences; Nyquist rate; binomial logic; binomial representations; circuit size; design methodology; efficient hardware implementation; fault tolerance; high clock rates; high-bandwidth signals; low computation hardware area; signal bandwidth; signal processing; signal sampling; single-pole filter; stochastic computing; stochastic logic; Bandwidth; Clocks; Design methodology; Fault tolerance; Hardware; Limiting; Logic; Random sequences; Signal processing; Stochastic processes;
Conference_Titel :
Signals, Systems and Computers, 2002. Conference Record of the Thirty-Sixth Asilomar Conference on
Conference_Location :
Pacific Grove, CA, USA
Print_ISBN :
0-7803-7576-9
DOI :
10.1109/ACSSC.2002.1196952
