English

Closed Loop Molecular Communication Testbed: Setup, Interference Analysis, and Experimental Results

Emerging Technologies 2023-11-10 v2

Abstract

In this paper, we present a fluid-based experimental molecular communication (MC) testbed that, similar to the human cardiovascular system, operates in a closed circuit tube system. The proposed system is designed to be biocompatible, resource-efficient, and controllable from outside the tube. As signaling molecule, the testbed employs the green fluorescent protein variant "Dreiklang" (GFPD). GFPDs can be reversibly switched via light of different wavelengths between a bright fluorescent state and a less fluorescent state. Hence, this property allows for writing and erasing information encoded in the state of the GFPDs already present in the fluid via radiation from outside the tube. The concept of modulating the GFPDs existing in the channel at the transmitter for information transmission, instead of releasing new molecules, is a form of media modulation. In our testbed, due to the closed loop setup and the long experiment durations of up to 250 min, we observe new forms of inter-symbol interferences (ISI), which do not occur in short experiments and open loop systems. In particular, up to four different forms of ISI, namely channel ISI, inter-loop ISI, offset ISI, and permanent ISI, occur in the considered system. To mitigate inter-loop ISI and offset ISI, we propose a light based eraser unit. We experimentally demonstrate reliable information transmission in our testbed achieving error-free transmission of 500 bit at a data rate of 6 bit/min based on a sub-optimal low-complexity detection scheme.

Keywords

Cite

@article{arxiv.2310.15588,
  title  = {Closed Loop Molecular Communication Testbed: Setup, Interference Analysis, and Experimental Results},
  author = {Lukas Brand and Maike Scherer and Teena tom Dieck and Sebastian Lotter and Maximilian Schäfer and Andreas Burkovski and Heinrich Sticht and Kathrin Castiglione and Robert Schober},
  journal= {arXiv preprint arXiv:2310.15588},
  year   = {2023}
}

Comments

7 pages, 5 figures, 1 table. This work has been submitted for possible publication to the IEEE International Conference on Communications (ICC) 2024

R2 v1 2026-06-28T12:59:54.441Z