Title :
Signal propagation and noisy circuits
Author :
Evans, William S. ; Schulman, Leonard J.
Author_Institution :
Dept. of Comput. Sci., Arizona Univ., Tucson, AZ, USA
fDate :
11/1/1999 12:00:00 AM
Abstract :
The information carried by a signal decays when the signal is corrupted by random noise. This occurs when a message is transmitted over a noisy channel, as well as when a noisy component performs computation. We first study this signal decay in the context of communication and obtain a tight bound on the rate at which information decreases as a signal crosses a noisy channel. We then use this information theoretic result to obtain depth lower bounds in the noisy circuit model of computation defined by von Neumann. In this model, each component fails (produces 1 instead of 0 or vice-versa) independently with a fixed probability, and yet the output of the circuit is required to be correct with high probability. Von Neumann showed how to construct circuits in this model that reliably compute a function and are no more than a constant factor deeper than noiseless circuits for the function. We provide a lower bound on the multiplicative increase in circuit depth necessary for reliable computation, and an upper bound on the maximum level of noise at which reliable computation is possible
Keywords :
circuit complexity; circuit noise; information theory; logic circuits; random noise; telecommunication channels; circuit depth; communication; depth lower bounds; information theoretic result; multiplicative increase; noisy channel; noisy circuit model; noisy circuits; random noise; reliable computation; signal propagation; von Neumann; Acoustic noise; Circuit noise; Communication channels; Computational modeling; Computer science; Context; Data processing; Mutual information; Random variables; Upper bound;
Journal_Title :
Information Theory, IEEE Transactions on
