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Bibliographic Details
Main Authors: Scherer, Maike, Brand, Lukas, Wolf, Louis, Dieck, Teena tom, Schäfer, Maximilian, Lotter, Sebastian, Burkovski, Andreas, Sticht, Heinrich, Schober, Robert, Castiglione, Kathrin
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.00831
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author Scherer, Maike
Brand, Lukas
Wolf, Louis
Dieck, Teena tom
Schäfer, Maximilian
Lotter, Sebastian
Burkovski, Andreas
Sticht, Heinrich
Schober, Robert
Castiglione, Kathrin
author_facet Scherer, Maike
Brand, Lukas
Wolf, Louis
Dieck, Teena tom
Schäfer, Maximilian
Lotter, Sebastian
Burkovski, Andreas
Sticht, Heinrich
Schober, Robert
Castiglione, Kathrin
contents We present a fluid-based experimental molecular communication (MC) testbed which uses media modulation. Motivated by the natural human cardiovascular system, the testbed operates in a closed-loop 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. GFPDs in solution are filled into the testbed prior to the start of information transmission and remain there for an entire experiment. For information transmission, an optical transmitter (TX) and an optical eraser (EX), which are located outside the tube, are used to write and erase the information encoded in the state of the GFPDs, respectively. At the receiver (RX), the state of the GFPDs is read out by fluorescence detection. In our testbed, due to the closed-loop setup, we observe new forms of inter-symbol interferences (ISI), which do not occur in short experiments and open-loop systems. For the testbed, we developed a communication scheme, which includes blind transmission start detection, symbol-by-symbol synchronization, and adaptive threshold detection. We comprehensively analyze our MC experiments using different performance metrics. Moreover, we experimentally demonstrate the error-free transmission of 5370 bit at a data rate of 36 $\textrm{bit}\, \textrm{min}^{\boldsymbol{-1}}$ using 8-ary modulation and the error-free binary transmission of around 90000 bit at a data rate of 12 $\textrm{bit}\, \textrm{min}^{\boldsymbol{-1}}$. For the latter experiment, data was transmitted for a period of 125 hours. All signals recorded and parts of the evaluation code are publicly available on Zenodo and Github, respectively.
format Preprint
id arxiv_https___arxiv_org_abs_2502_00831
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Closed-Loop Long-Term Experimental Molecular Communication System
Scherer, Maike
Brand, Lukas
Wolf, Louis
Dieck, Teena tom
Schäfer, Maximilian
Lotter, Sebastian
Burkovski, Andreas
Sticht, Heinrich
Schober, Robert
Castiglione, Kathrin
Emerging Technologies
We present a fluid-based experimental molecular communication (MC) testbed which uses media modulation. Motivated by the natural human cardiovascular system, the testbed operates in a closed-loop 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. GFPDs in solution are filled into the testbed prior to the start of information transmission and remain there for an entire experiment. For information transmission, an optical transmitter (TX) and an optical eraser (EX), which are located outside the tube, are used to write and erase the information encoded in the state of the GFPDs, respectively. At the receiver (RX), the state of the GFPDs is read out by fluorescence detection. In our testbed, due to the closed-loop setup, we observe new forms of inter-symbol interferences (ISI), which do not occur in short experiments and open-loop systems. For the testbed, we developed a communication scheme, which includes blind transmission start detection, symbol-by-symbol synchronization, and adaptive threshold detection. We comprehensively analyze our MC experiments using different performance metrics. Moreover, we experimentally demonstrate the error-free transmission of 5370 bit at a data rate of 36 $\textrm{bit}\, \textrm{min}^{\boldsymbol{-1}}$ using 8-ary modulation and the error-free binary transmission of around 90000 bit at a data rate of 12 $\textrm{bit}\, \textrm{min}^{\boldsymbol{-1}}$. For the latter experiment, data was transmitted for a period of 125 hours. All signals recorded and parts of the evaluation code are publicly available on Zenodo and Github, respectively.
title Closed-Loop Long-Term Experimental Molecular Communication System
topic Emerging Technologies
url https://arxiv.org/abs/2502.00831