Impact of Body Mass Index on Ultrawideband MIMO BAN Channels-Measurements and Statistical Model

• Published in: IEEE transactions on wireless communications Vol. 17; no. 9; pp. 6067 - 6081
• Main Authors: Sangodoyin, Seun, Molisch, Andreas F.
• Format: Journal Article
• Language: English
• Published: New York IEEE 01.09.2018; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Anechoic chambers; Body area network; Body area networks; Body mass index; Body size; Categories; Channels; Decay rate; Electronic devices; Frequency measurement; Human subjects; Indoor environments; MIMO communication; Narrowband; Numerical models; Parameters; Propagation; Size measurement; Sounding; statistical channel modeling; Statistical models; Ultrawideband; ultrawideband (UWB); Wireless communication; Wireless communications; Wireless networks; wireless propagation measurements
• ISSN: 1536-1276; 1558-2248
• DOI: 10.1109/TWC.2018.2854582

Wireless body area networks (BANs) have many important applications such as wearable communication devices and Internet of Things. Wireless propagation in on-body channels has been measured and modeled in the past. However, a crucial element that is usually ignored is the impact of the body size of the user-a 50-kg person obviously creates a different on-body channel than a 150-kg person. The status-quo "one-size-fits-all" approach to channel characterization in BAN is thus incomplete. In this paper, we provide a detailed description of a propagation measurement campaign that employs a self-developed <inline-formula> <tex-math notation="LaTeX">4 \times 4 </tex-math></inline-formula> ultrawideband multiple-input-multiple-output array channel sounding system to perform BAN channel sounding both in an anechoic chamber and indoor laboratory environments. A total of 60 human subjects were investigated in our work. These human subjects had widely varying body mass index (BMI) values, which were grouped into three different categories, i.e., 20 per BMI category. Various propagation properties such as path gain, frequency-decay factor, shadowing gain, rms delay spread, amplitude fading, and spatial correlation are extracted for each on-body channel under consideration. A comparison of statistics among the BMI categories reveals considerable differences, emphasizing the fact that the aforementioned propagation properties are BMI dependent. Parameters such as path gain showed a monotonic decrease across the BMI categories with values ranging from 1-2 to almost 13 dB in some channels. This paper proposes a propagation channel model for the BMI-dependent parameters and validates that it can reproduce the measured channel capacities.