Bio-Physical Modeling of Galvanic Human Body Communication in Electro-Quasistatic Regime

Abstract Human Body Communication (HBC) is an alternative to radio wave-based Wireless Body Area Network (WBAN) because of its low-loss, wide bandwidth leading to enhanced energy efficiency. HBC also shows better performance in terms of physical security as most of the signal is confined within the body. To obtain optimum performance and usability, modeling of the body channel plays a vital role. Out of two HBC modalities, Galvanic HBC has the promise to provide lower loss compare to Capacitive HBC for shorter channel length. In this paper, we present the first lumped element based detailed model of Galvanic HBC channel which is used to explain the dependency of channel loss on the material property of skin, fat and muscle tissue layer along with electrode size, electrode separation, geometrical position of the electrodes and return path capacitance. The model considers the impedance of skin and muscle tissue layers and the effect of various coupling capacitances between the body and Tx/Rx electrodes to the Earth-ground. A 2D planner structure is simulated in HFSS to prove the validity of the proposed model. The effect of symmetry and asymmetry at the transmitter and receiver end are also explained using the model. The experimental results show that, due to the mismatch at the transmitter and receiver side, the loss increases gradually with channel length and saturates to a finite value as channel length becomes significantly longer compare to the transmitting or receiving electrode pair separation.