V. Aristov, A. Elsts. Human Body as a Signal Transmission Medium for Body-Coupled Communication: Galvanic-Mode Models. Electronics, 12(21), 4550 pp. MDPI, 2023.
Bibtex citation:
Bibtex citation:
@article{15583_2023,
author = {V. Aristov and A. Elsts},
title = {Human Body as a Signal Transmission Medium for Body-Coupled Communication: Galvanic-Mode Models},
journal = {Electronics},
volume = {12},
issue = {21},
pages = {4550},
publisher = {MDPI},
year = {2023}
}
author = {V. Aristov and A. Elsts},
title = {Human Body as a Signal Transmission Medium for Body-Coupled Communication: Galvanic-Mode Models},
journal = {Electronics},
volume = {12},
issue = {21},
pages = {4550},
publisher = {MDPI},
year = {2023}
}
Abstract: Signal propagation models play a fundamental role in radio frequency communication research. However, emerging communication methods, such as body-coupled communication (BCC), require the creation of new models. In this paper, we introduce mathematical models that approximate the human body as an electrical circuit, as well as linear regression- and random forest-based predictive models that infer the expected signal loss from its frequency, measurement point locations, and body parameters. The results demonstrate a close correspondence between the amplitude-frequency response (AFR) predicted by the electrical circuit models and the experimental data gathered from volunteers. The accuracy of our predictive models was assessed by using their root mean square errors (RMSE), ranging from 1.5 to 7 dB depending on the signal frequency within the 0.05 to 20 MHz range. These results allow researchers and engineers to simulate and forecast the expected signal loss within BCC systems during their design phase.
Quartile: Q2