Order-Optimal Rate of Caching and Coded Multicasting with Random Demands

We consider the canonical {\em shared link network} formed by a source node, hosting a library of $m$ information messages (files), connected via a noiseless common link to $n$ destination nodes (users), each with a cache of size M files. Users request files at random and independently, according to a given a-priori demand distribution $\qv$. A coding scheme for this network consists of a caching placement (i.e., a mapping of the library files into the user caches) and delivery scheme (i.e., a mapping for the library files and user demands into a common multicast codeword) such that, after the codeword transmission, all users can retrieve their requested file. The rate of the scheme is defined as the {\em average} codeword length normalized with respect to the length of one file, where expectation is taken over the random user demands. For the same shared link network, in the case of deterministic demands, the optimal min-max rate has been characterized within a uniform bound, independent of the network parameters. In particular, fractional caching (i.e., storing file segments) and using linear network coding has been shown to provide a min-max rate reduction proportional to 1/M with respect to standard schemes such as unicasting or "naive" uncoded multicasting. The case of random demands was previously considered by applying the same order-optimal min-max scheme separately within groups of files requested with similar probability. However, no order-optimal guarantee was provided for random demands under the average rate performance criterion. In this paper, we consider the random demand setting and provide general achievability and converse results. In particular, we consider a family of schemes that combine random fractional caching according to a probability distribution $\pv$ that depends on the demand distribution $\qv$, with a linear coded delivery scheme based on ...