Finite Field Multiple Access

In the past several decades, various techniques have been developed and used for multiple-access (MA) communications. With the new applications for 6G, it is desirable to find new resources, physical or virtual, to confront the fast development of MA communication systems. For binary source transmission, this paper proposes an element-pair (EP) coding scheme for supporting massive users with short packet traffic, which solves the finite blocklength (FBL) of multiuser reliability transmission problem. Each user is assigned a unique EP, and the collection of EPs assigned to the users possesses the unique sum-pattern mapping (USPM) structural property. We present methods for constructing symbol-wise EP codes with USPM structural property based on the prime field and extension field of prime field, respectively. Based on the orthogonal EP code constructed over GF($2^m$), we propose finite-field MA (FFMA) systems over a Gaussian multiple-access channel (GMAC), including both the sparse-form and diagonal-from structures. The proposed FFMA is then applied to network layer and forms network FFMA systems for pure digital networks, in which an EP is viewed as a virtual resource block (VRB). Simulation results show that the error performance of the proposed FFMA over a GMAC can approach the error performance as that of the single-user transmission.