Zero-Error Capacity of a Class of Timing Channels

Abstract

We analyze the problem of zero-error communication through timing channels that can be interpreted as discrete-time queues with bounded waiting times. The channel model includes the following assumptions: 1) Time is slotted, 2) at most N "particles" are sent in each time slot, 3) every particle is delayed in the channel for a number of slots chosen randomly from the set \0, 1, …, K\ , and 4) the particles are identical. It is shown that the zero-error capacity of this channel is r , where r is the unique positive real root of the polynomial xK+1 - xK - N . Capacity-achieving codes are explicitly constructed, and a linear-time decoding algorithm for these codes devised. In the particular case N = 1 , K = 1 , the capacity is equal to φ , where φ = (1 + 5) / 2 is the golden ratio, and the constructed codes give another interpretation of the Fibonacci sequence.