# Body-resonance: transmission line-like wireless links enabling high-speed wearable communication

**Authors:** Samyadip Sarkar, Qi Huang, Sarthak Antal, Mayukh Nath, Shreyas Sen

PMC · DOI: 10.1038/s44172-025-00533-z · 2025-12-20

## TL;DR

A new high-speed, low-power communication method for wearables uses the human body's transmission-line behavior to enable faster data transfer.

## Contribution

Body-Resonance Human Body Communication enhances channel capacity by exploiting the body's transmission-line behavior in the near-intermediate field.

## Key findings

- Body-Resonance achieves 20 dB higher channel gain and wider bandwidth than electro-quasistatic methods.
- It supports data rates of hundreds of Mbps, enabling applications like HD streaming and distributed computing.
- Experimental results show low-loss, wideband body channels that are more than 10X less leaky than antenna-based wireless.

## Abstract

Seamless interaction between humans and Artificial Intelligence-empowered, battery-operated, miniaturized devices is reshaping wearable technology by forming an anthropomorphic artificial nervous system that demands high-speed, low-power connectivity. Besides being radiative, radio frequency links suffer absorption losses in non-line-of-sight scenarios and consume more than tens of milliwatts of power. Electro-quasistatic human body communication provides non-radiative links with  ~100X better energy efficiency and  ~30X superior signal confinement over radio wave-based wireless. However, it is limited by  ~60–70 dB path loss, limited bandwidth, and data rates ≤30 Mbps, insufficient for applications such as High definition streaming, and distributed computing at wearable sensor nodes. To overcome these challenges, we propose Body-Resonance Human Body Communication, which leverages the human body’s transmission-line behavior in the near-intermediate field to enhance channel capacity by up to 30X. It achieves approximately 20 dB higher channel gain and a wider bandwidth compared to electro-quasistatic regime, supporting data rates of hundreds of Mbps. Experimental results validate low-loss (~40–50 dB), wideband body channels that are more than 10X less leaky than antenna-based wireless links. Body Resonance can potentially open up the possibilities of immersive augmented/virtual reality and cooperative on-body computing by enabling energy-efficient, high-speed wearable networks across healthcare, defense, and consumer electronics.

Conventional body-coupled wireless communication links for wearables rely on electro-quasistatic conduction, treating the human body as a wire. Samyadip Sarkar and colleagues demonstrate leveraging fields beyond electro -quasistatic frequencies unveils the human body’s transmission-line behaviour that enhances wearable-to-wearable communication channel capacity.

## Full-text entities

- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12764851/full.md

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Source: https://tomesphere.com/paper/PMC12764851