The benefit of a 1-bit jump-start, and the necessity of stochastic encoding, in jamming channels

Abstract

We consider the problem of communicating a message m in the presence of a malicious jamming adversary (Calvin), who can erase an arbitrary set of up to pn bits, out of n transmitted bits (x1,…,xn). The capacity of such a channel when Calvin is exactly causal, i.e. Calvin's decision of whether or not to erase bit xi depends on his observations (x1,…,xi) was recently characterized to be 1-2p. In this work we show two (perhaps) surprising phenomena. Firstly, we demonstrate via a novel code construction that if Calvin is delayed by even a single bit, i.e. Calvin's decision of whether or not to erase bit xi depends only on (x1,…,xi-1) (and is independent of the "current bit" xi) then the capacity increases to 1-p when the encoder is allowed to be stochastic. Secondly, we show via a novel jamming strategy for Calvin that, in the single-bit-delay setting, if the encoding is deterministic (i.e. the transmitted codeword is a deterministic function of the message m) then no rate asymptotically larger than 1-2p is possible with vanishing probability of error, hence stochastic encoding (using private randomness at the encoder) is essential to achieve the capacity of 1-p against a one-bit-delayed Calvin.