A New Construction Structure on MISO Coded Caching with Linear Subpacketization: Half-Sum Disjoint Packing

Abstract

In the (L,K,M,N) cache-aided multiple-input single-output (MISO) broadcast channel (BC) system, the server is equipped with L antennas and communicates with K single-antenna users through a wireless broadcast channel where the server has a library containing N files, and each user is equipped with a cache of size M files. Under the constraints of uncoded placement and one-shot linear delivery strategies, many schemes achieve the maximum sum Degree-of-Freedom (sum-DoF). However, for general parameters L, M, and N, their subpacketizations increase exponentially with the number of users. We aim to design a MISO coded caching scheme that achieves a large sum-DoF with low subpacketization F. An interesting combinatorial structure, called the multiple-antenna placement delivery array (MAPDA), can be used to generate MISO coded caching schemes under these two strategies; moreover, all existing schemes with these strategies can be represented by the corresponding MAPDAs. In this paper, we study the case with F=K (i.e., F grows linearly with K) by investigating MAPDAs. Specifically, based on the framework of Latin squares, we transform the design of MAPDA with F=K into the construction of a combinatorial structure called the L-half-sum disjoint packing (HSDP). It is worth noting that a 1-HSDP is exactly the concept of NHSDP, which is used to generate the shared-link coded caching scheme with F=K. By constructing L-HSDPs, we obtain a class of new schemes with F=K. Finally, theoretical and numerical analyses show that our L-HSDP schemes significantly reduce subpacketization compared to existing schemes with exponential subpacketization, while only slightly sacrificing sum-DoF, and achieve both a higher sum-DoF and lower subpacketization than the existing schemes with linear subpacketization.