Relaying in Diffusion-Based Molecular Communication

TL;DR

This paper introduces molecular relaying techniques in diffusion-based molecular communication to extend communication range and improve reliability, demonstrating that multi-type relaying outperforms single-type and decode-and-forward enhances M-ary signaling.

Contribution

It proposes and analyzes molecular relaying strategies, including sense-and-forward and decode-and-forward, to enhance the performance of biological molecular communication systems.

Findings

Sense and forward relaying increases communication range or effective bacteria count.

Multi-type relaying outperforms single-type relaying.

Decode and forward relaying significantly improves M-ary communication reliability.

Abstract

Molecular communication between biological entities is a new paradigm in communications. Recently, we studied molecular communication between two nodes formed from synthetic bacteria. Due to high randomness in behavior of bacteria, we used a population of them in each node. The reliability of such communication systems depends on both the maximum concentration of molecules that a transmitter node is able to produce at the receiver node as well as the number of bacteria in each nodes. This maximum concentration of molecules falls with distance which makes the communication to the far nodes nearly impossible. In order to alleviate this problem, in this paper, we propose to use a molecular relaying node. The relay node can resend the message either by the different or the same type of molecules as the original signal from the transmitter. We study two scenarios of relaying. In the first scenario, the relay node simply senses the received concentration and forwards it to the receiver. We show that this sense and forward scenario, depending on the type of molecules used for relaying, results in either increasing the range of concentration of molecules at the receiver or increasing the effective number of bacteria in the receiver node. For both cases of sense and forward relaying, we obtain the resulting improvement in channel capacity. We conclude that multi-type molecular relaying outperforms the single-type relaying. In the second scenario, we study the decode and forward relaying for the M-ary signaling scheme. We show that this relaying strategy increases the reliability of M-ary communication significantly.