Molecular Arithmetic Coding (MAC) for Internet of Bio-Nano Things (IoBNT)

Molecular Communication (MC) has emerged as a promising paradigm employing molecules to transfer information at the nano-scale. Unlike MC channel coding, MC source coding has remained mostly an unexplored area of research. In a recent paper, prefix source coding was introduced into the field, through an MC-adapted version of the Huffman Coding. In the context of MC source coding, this paper proposes the Molecular Arithmetic Coding (MAC) whose algorithmic implementation and code-structure is non-arbitrarily different than that of the widely-known classical arithmetic coding. MAC is designed to mitigate Inter-Symbol Interference (ISI) for alphabets with known symbol probabilities through, in a highly efficient way, avoiding consecutive 1-bits. However, due to bit precision limitations any arithmetic coding method faces, without any assumption made on the structure of the symbol alphabet, unique-decodability of MAC is not guaranteed. Accordingly, a uniquely-decodable new coding scheme named Molecular Arithmetic with Prefix Coding (MAPC) is also introduced. Across multiple alphabets, we show that MAPC provides a better compression performance compared to the optimal MC-adapted prefix coding. Simulation results of an exemplary alphabet demonstrates the superior symbol and word error rate performance of MAPC compared to the optimal MC-adapted prefix coding and to the uncoded BCSK schemes.