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1. HUMAN BODY MODEL CST MICROWAVE STUDIO SKIN
2. HUMAN BODY MODEL CST MICROWAVE STUDIO PATCH
3. HUMAN BODY MODEL CST MICROWAVE STUDIO CODE

H., and Sani, A., Alomainy, A., Yang Hao. The Challenge of Nonionizing Radiation: a Proposal for Legislation. Effects Of Nonionizing Radiation On The Central Nervous System, Behavior, And Blood: A Progress Report.

Health Effects of Artificial Electromagnetic Fields and Effective Solutions for the Problem (n.d): n. Electromagnetic Radiation and Human Health. Non-Ionizing Radiations – Sources, Biological Effects, Emissions and Exposures. Non-Ionizing Radiations–Sources, Biological Effects, Emissions and Exposures.

HUMAN BODY MODEL CST MICROWAVE STUDIO CODE

CST Microwave Studio is one of the EM modeling code which can be used for bio electromagnetic purpose. at ultra-wideband frequency which is expected to improve the understanding of radio propagation inside human body hence contribute to more advance and innovative medical implants.

HUMAN BODY MODEL CST MICROWAVE STUDIO SKIN

Hence, this paper present the non-ionizing electromagnetic radiation effect on electrical nerve fiber of human arm model with the presence of other human tissues such as fat, muscle, skin and etc. It can transmit digital data over a wide frequency spectrum with very low power and at very high data rates.

Ultra-wideband (UWB) is a wireless technology that potential applications in variety of medical areas such as implant wireless sensors, microwave hyperthermia, imaging and radar. The implant antenna with ultra-wideband (UWB) frequency will be used by inserting it into the nerve of human arm in term of homogenous model. The services provided by this type of application can cause either good or bad effects on human body depending on the power level, frequency and the way it being used. The use of non-ionizing electromagnetic radiation in various areas like medical application has arisen the electromagnetic radiation problem. In biomedical application, the process requires transmitting data, images and videos from inside the body taken by a radio system of a size of a pill seems to be the way. The collected medical data is then transmitted wirelessly to an external unit for processing, thereby enhancing the health monitoring, diagnosis, and therapy of the patients. In modern telemedicine systems the physiological data of patients can be measured with the aid of electronic sensors located on and inside the human body. Ultra-wideband antenna, radiation, nerve fiber, action potential signal Abstract Correia, Proceedings of EW’2012-18th European Wireless Conference, Poznan, 2012.Department of Telecommunication Electronics, Faculty of Electronic & Computer Engineering, Universiti Teknikal Malaysia Melaka (UTeM), Malaysia Correia, A wideband directional channel model for mobile communication systems, In Adaptive Antenna Arrays, S. Mackowiak, and L.M.Correia, Modelling the influence of body dynamics on the radiation pattern of wearable antennas in off-body radio channels, In Proceedings of 12th URSI Commission F Triennial Open Symposium on Radio Wave Propagation and Remote Sensing, Garmisch-Partenkirchen, Germany, 2011. Fernandes, Proceedings of ConfTele-Conference on Telecommunications, Peniche, 2007. Technical Report, Brooks Air Force, AL/OE-TR-1996-0037, San Antonio, 1996.Ĭ. Gabriel, Compilation of dielectric properties of body tissues at RF and microwave frequencies. Christ, et al., The virtual family-development of surface-based anatomical models of two adults and two children for dosimetric simulations, Physics in Medicine and Biology, Vol. Sadiku, Numerical Techniques in Electromagnetics. Pathak, Proceedings of Applications of Mathematics in Modern Optics, San Diego, 1982. Glassner, An Introduction to Ray Tracing. Balanis, Antenna Theory: Analysis and Design.

Sibille, Proceedings of URSI GASS 2011-30th General Assembly and Scientific Symposium of URSI, Istanbul, 2011.Ĭ.

HUMAN BODY MODEL CST MICROWAVE STUDIO PATCH

Hall, Statistical analysis and performance evaluation for on-body radio propagation with microstrip patch antennas, IEEE Transactions on Antennas and Propagation, Vol. Davenport, Proceedings of IET Seminar on Antennas and Propagation for Body-Centric Wireless Communications, London, 2007.Ī. Correia, Proceedings of PIMRC’2010-21st IEEE International Symposium on Personal, Indoor and Mobile Radio Communications, Istanbul, 2010.Ī.

Denidni, Statistical modeling of the “antenna–head” interaction, IEEE Antennas and Wireless Propagation Letters, Vol. Sibille, Proceedings of 29th URSI General Assembly, Chicago, 2008. Hall, Proceedings of IWAT’2007-International Workshop on Antenna Technology, Cambridge, 2007.Ī. Hao, Antennas and Propagation for Body-Centric Wireless Communications.