Understanding the Role of Magnetic and Magneto-Quasistatic Fields in Human Body Communication

Nath, Mayukh; Ulvog, Alfred Krister; Weigand, Scott; Sen, Shreyas

doi:10.1109/tbme.2022.3174959

Cited by 6 publications

(1 citation statement)

References 16 publications

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“…The gain between any two devices is influenced by various factors, including the channel characteristics and the output and input impedances of the transmitter and receiver [ 24 ]. For the NF-IBCC system, the channel characteristics are determined by the forward path, return path 1, and return path 2.…”

Section: Retrieval and Analysis Of Core Parameters Based On The Trans...mentioning

confidence: 99%

The Retrieval and Effect of Core Parameters for Near-Field Inter-Body Coupling Communication

Zhang

Song

Zhou

et al. 2023

Sensors

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The potential of the Internet of Body (IoB) to support healthcare systems in the future lies in its ability to enable proactive wellness screening through the early detection and prevention of diseases. One promising technology for facilitating IoB applications is near-field inter-body coupling communication (NF-IBCC), which features lower power consumption and higher data security when compared to conventional radio frequency (RF) communication. However, designing efficient transceivers requires a profound understanding of the channel characteristics of NF-IBCC, which remain unclear due to significant differences in the magnitude and passband characteristics of existing research. In response to this problem, this paper clarifies the physical mechanisms of the differences in the magnitude and passband characteristics of NF-IBCC channel characteristics in existing research work through the core parameters that determine the gain of the NF-IBCC system. The core parameters of NF-IBCC are extracted through the combination of transfer functions, finite element simulations, and physical experiments. The core parameters include the inter-body coupling capacitance (CH), the load impedance (ZL), and the capacitance (Cair), coupled by two floating transceiver grounds. The results illustrate that CH, and particularly Cair, primarily determine the gain magnitude. Moreover, ZL mainly determines the passband characteristics of the NF-IBCC system gain. Based on these findings, we propose a simplified equivalent circuit model containing only core parameters, which can accurately capture the gain characteristics of the NF-IBCC system and help to concisely describe the channel characteristics of the system. This work lays a theoretical foundation for developing efficient and reliable NF-IBCC systems that can support IoB for early disease detection and prevention in healthcare applications. The potential benefits of IoB and NF-IBCC technology can, thus, be fully realized by developing optimized transceiver designs based on a comprehensive understanding of the channel characteristics.

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Section: Retrieval and Analysis Of Core Parameters Based On The Trans...mentioning

confidence: 99%

The Retrieval and Effect of Core Parameters for Near-Field Inter-Body Coupling Communication

Zhang

Song

Zhou

et al. 2023

Sensors

View full text Add to dashboard Cite

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Material Property Based Analysis of Human Body Communication in Body Resonance Regime

Sarkar,

Chowdhury,

Huang

et al. 2024

2024 IEEE MTT-S International Microwave Biomedical Conference (IMBioC)

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Field-Circuit Combination Method for Solving the Detuning Problem of Magnetic Resonance Human Body Communication

Huang,

Wei,

Chen

et al. 2024

IEEE J. Electromagn. RF Microw. Med. Biol.

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Understanding the Role of Magnetic and Magneto-Quasistatic Fields in Human Body Communication

Cited by 6 publications

References 16 publications

The Retrieval and Effect of Core Parameters for Near-Field Inter-Body Coupling Communication

The Retrieval and Effect of Core Parameters for Near-Field Inter-Body Coupling Communication

Material Property Based Analysis of Human Body Communication in Body Resonance Regime

Field-Circuit Combination Method for Solving the Detuning Problem of Magnetic Resonance Human Body Communication

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