Abstract
We address channel characterization and modeling for medical wireless body-area networks (WBANs) based on the optical wireless technology. We focus on the intra-WBAN communication links, i.e., between a set of medical sensors and a coordination node, placed on the patient’s body. We consider a realistic mobility model, e.g., inside a hospital room, which takes into account the effect of shadowing due to body parts movements and the variations of the underlying channels. To take into account the global and local user mobility, we consider a dynamic model based on a three-dimensional animation of a walk cycle, as well as walk trajectories based on an improved random way-point mobility model. Then, Monte Carlo ray-tracing simulations are performed to obtain the channel impulse responses for different link configurations at different instants of the walk scenarios. We then derive first-and second-order statistics of the channel parameters such as the channel DC gain, delay spread, and coherence time, and furthermore, propose best fit statistical models to describe the distribution of these parameters for a general scenario.
Highlights
T HE GLOBAL increase in life expectancy and the increase of chronic and cardiovascular diseases have resulted in a growing interest in developing medical telemonitoring and telecare systems [1]–[4]
To the best of the authors’ knowledge, there is no reported work on optical wireless body-area networks (WBANs) channel modeling that considers the effects of mobility and shadowing due to the body parts as well as a realistic body movement inside an indoor environment, which is the main contribution of this paper
Monte Carlo ray-tracing (MCRT)-based simulations were done using the Opticstudio software to obtain the channel impulse response (CIR) for a set of sensors nodes (SNs) and coordinator node (CN) configurations at different instants of the walk scenario
Summary
T HE GLOBAL increase in life expectancy and the increase of chronic and cardiovascular diseases have resulted in a growing interest in developing medical telemonitoring and telecare systems [1]–[4]. To the best of the authors’ knowledge, there is no reported work on optical WBAN channel modeling that considers the effects of mobility and shadowing due to the body parts as well as a realistic body movement inside an indoor environment, which is the main contribution of this paper.
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