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IEEE Transactions on Microwave Theory and Techniques
Volume 48 Number 11, November 2000

Table of Contents for this issue

Complete paper in PDF format

Appropriate Modeling of the Ear for Compliance Testing of Handheld MTE with SAR Safety Limits at 900/1800 MHz

Michael Burkhardt, Member, IEEE and Niels Kuster Member, IEEE

Page 1927.

Abstract:

A variety of phantoms simulating the human head have been used to test compliance of mobile telecommunications equipment with safety standards. Whereas numerical compliance procedures have mostly been performed using complex anatomical phantoms based on magnetic resonance imaging (MRI) data, experimental procedures have mainly relied on homogeneous phantoms, the ears of which have often been modeled as lossless spacers. Previous studies had indeed demonstrated that the absorption in the head tissue, except the outer ear, can be well represented by a homogeneous head of appropriate shape and material. The objectives of this paper were to fill the gap of the remaining open issues, namely: to evaluate the exposure in the ear region with respect to the spatial-peak specific absorption rate and to evaluate the most appropriate modeling of the ear for experimental evaluations such that it represents the maximum exposure of a reasonable cross section of cellular phone users. This paper is based on a detailed numerical phantom produced using high-resolution MRI scans. During scanning, the ear was naturally collapsed as it occurs when using a cellular phone. The results of this study lead to the conclusion that the spatial-peak absorption occurring in the inner and outer ear can be reliably modeled either by a lossless spacer of not thicker than 3-4 mm or by partially filling the simulated pinna with head tissue simulating media, whereas the minimum distance between the device and liquid should not be larger than 3 mm.

References

  1. "Evaluating compliance with FCC guidelines for human exposure to radio frequency electromagnetic fields", Fed. Commun. Commission, Washington, DC, 20 554 Tech. Rep. OET Bull. 65, 1997.
  2. "Considerations for evaluation of human exposure to Electromagnetic Fields (EMF's) from Mobile Telecommunication Equipment (MTE) in the frequency range 30 MHz-6 GHz", CENELEC, Brussels, Belgium, prES 59005, CLC/TC211 (SEC) 17, Mar. 1998.
  3. "Specific Absorption Rate (SAR) Estimation for Cellular Phone", ARIB STD-T56, Jan. 1998 .
  4. T. Schmid, O. Egger and N. Kuster, "Automated E -field scanning system for dosimetric assessments", IEEE Trans. Microwave Theory Tech., vol. 44, pp.  105-113, Jan.  1996.
  5. C. Gabriel, "Phantom models for antenna design and exposure assessment", in IEE Colloq. Design of Mobile Antennas for Optimal Performance in Presence of Biolog. Tissue, Jan. 1997.
  6. Q. Balzano, O. Garay and T. J. Manning, "Electromagnetic energy exposure of simulated users of portable cellular telephones", IEEE Trans. Veh. Technol., vol. 44, pp.  390-403, Aug.  1995.
  7. N. Kuster, R. Kästle and T. Schmid, "Dosimetric evaluation of handheld mobile communications equipment with known precision", IEICE Trans. Commun., vol. 80, no. 5, pp.  645-652, May  1997.
  8. N. Kuster and Q. Balzano, "Energy absorption mechanism by biological bodies in the near field of dipole antennas above 300 MHz", IEEE Trans. Veh. Technol., vol. 41, pp.  17-23, Feb.  1992.
  9. V. Hombach, K. Meier, M. Burkhardt, E. Kühn and N. Kuster, "The dependence of EM energy absorption upon human head modeling at 900 MHz", IEEE Trans. Microwave Theory Tech., vol. 44, pp.  1855-1863, Oct.  1996 .
  10. K. Meier, V. Hombach, R. Kästle, R. Y-S. Tay and N. Kuster, "The dependence of electromagnetic energy absorption upon human-head modeling at 1800 MHz", IEEE Trans. Microwave Theory Tech., vol. 45, pp.  2058-2062, Nov.  1997.
  11. F. Schoenborn, M. Burkhardt and N. Kuster, "Differences in energy absorption between heads of adults and children in the near field of sources", Health Phys., vol. 74, no. 2, pp.  160-168, 1998.
  12. P. J. Dimbylow and S. M. Mann, "SAR calculations in an anatomically realistic model of the head for mobile communication transceivers at 900 MHz and 1.8 GHz", Phys. Med. Biol., vol. 39, pp.  1537-1553, 1994.
  13. T. Hamada, S. Watanabe and M. Taki, "Effect of pinna on the local ears in a human head exposed to microwave", in 20th Annu. Bioelectromag. Soc. Meeting, Saint Petersburg, FL, June 1998, p.  99. 
  14. O. P. Gandhi, G. Lazzi and C. M. Furse, "Electromagnetic absorption in the human head and neck for mobile telephones at 835 and 1900 MHz", IEEE Trans. Microwave Theory Tech., vol. 44, pp.  1884-1897, Oct.  1996.
  15. M. Burkhardt and N. Kuster, "Artifacts at material boundaries of lossy dielectric bodies in FDTD simulations", in IEEE Antennas Propagat. Symp., Atlanta, GA, June 1998, p.  72. 
  16. A. Taflove, Computational Electromagnetics: The Finite-Difference Time-Domain Method, Norwood, MA: Artech House, 1995.
  17. "The MAFIA Collaboration, Mafia Version 3.x, User's Guide CST GmbH", CST, Darmstadt, Germany, 1994.
  18. T. Weiland, "Maxwell's grid equations", Frequenz , vol. 44, no. 1, pp.  9-16, 1990.
  19. N. Buechler, D. H. Roper, C. H. Durney and D. A. Christensen, "Modeling sources in the FDTD formulation and their use in quantifying source and boundary condition errors", IEEE Trans. Microwave Theory Tech., vol. 43, pp.  810-813, Apr.  1995.
  20. C. Gabriel, Dielectric Database, London: U.K.: Microwave Consultants Ltd., 1994.
  21. C. Gabriel, "Compilation of the Dielectric Properties of Body Tissues at RF and Microwave Frequencies", Brooks Air Force Base, Brooks AFB, TX, Tech. Rep. AL/OE-TR-1996-0037, 1996.