Empirical Output Distribution of Good Delay-Limited Codes for Quasi-Static Fading Channels

Abstract

This paper considers delay-limited communication over quasi-static fading channels under a long-term power constraint. A sequence of length-n delay-limited codes for a quasi-static fading channel is said to be capacity-achieving if the codes achieve the delay-limited capacity, which is defined to be the maximum rate achievable by delay-limited codes. The delay-limited capacity is sometimes referred to as the zero-outage capacity in wireless communications. The delay-limited capacity is the appropriate choice of performance measure for delay-sensitive applications such as voice and video over fading channels. It is shown that for any sequence of capacity-achieving delay-limited codes with vanishing error probabilities, the normalized relative entropy between the output distribution induced by the length-n code and the n-fold product of the capacity-achieving output distribution, denoted by 1nD(pYn\|pYn*), converges to zero. Additionally, we extend our convergence result to capacity-achieving delay-limited codes with non-vanishing error probabilities.