DocumentCode
927933
Title
The dependence of electromagnetic far-field absorption on body tissue composition in the frequency range from 300 MHz to 6 GHz
Author
Christ, Andreas ; Klingenböck, Anja ; Samaras, Theodoros ; Goiceanu, Cristian ; Kuster, Niels
Author_Institution
Found. for Res. on Inf. Technol. in Soc., Swiss Fed. Inst. of Technol., Zurich, Switzerland
Volume
54
Issue
5
fYear
2006
fDate
5/1/2006 12:00:00 AM
Firstpage
2188
Lastpage
2195
Abstract
The dielectric parameters of the tissue simulating liquids to assess the exposure from mobile phones were determined in a previous study considering the tissue distribution of the exposed regions of the head using a planar layered model and the transmission-line method. Currently, the standards for the compliance testing of wireless devices are being extended to more general exposure situations. This paper uses the same methods considering different locations of the body and the respective variations of the tissue structures and dimensions. The analysis of tissue compositions shows a significant increase of 2.2-4.7 dB of the peak spatial specific absorption rate (SAR) in comparison to the values assessed with current standard liquids. This increase is due to standing-wave effects in tissues with low water content. For a certain distance between the antenna and the body (approximately λ/3 for a λ/2 dipole), these standing-wave effects dominate the coupling mechanism, leading to a higher average SAR in layered tissue. The observations were validated using finite-difference time-domain simulations of an anatomical high-resolution human model. Nevertheless, a sound conservative exposure assessment applying phantoms filled with homogeneous standardized liquids is possible if a distance and frequency-dependent scaling factor is applied.
Keywords
biological effects of fields; biological effects of microwaves; biological tissues; electromagnetic wave absorption; finite difference time-domain analysis; mobile handsets; 300 to 6000 MHz; body tissue composition; body-worn devices; electromagnetic far-field absorption; finite-difference time-domain simulations; human anatomy; mobile phones; specific absorption rate; standing-wave effects; wireless device compliance testing; Biological system modeling; Dielectric liquids; Dipole antennas; Electromagnetic wave absorption; Finite difference methods; Frequency; Mobile handsets; Specific absorption rate; Testing; Transmission lines; Body-worn devices; human anatomy; specific absorption rate (SAR);
fLanguage
English
Journal_Title
Microwave Theory and Techniques, IEEE Transactions on
Publisher
ieee
ISSN
0018-9480
Type
jour
DOI
10.1109/TMTT.2006.872789
Filename
1629062
Link To Document