Advancement of Signal Processing and its Applications (e-ISSN: 3048-8907)

Embedded radio wire assumes a fundamental part in biomedical applications so it has a becoming fascinating in the as of late. The embedded receiving wire should be incredibly limited while keeping the Particular Ingestion Rate (SAR) inside the human body as little as could really be expected. The greater part of the proposed plans for embedded radio wire have a little effectiveness and high SAR for little receiving wire size. In this paper, a capacitive stacked dipole receiving wire is proposed for embedded applications like gastrointestinal containers. The proposed radio wire is a dipole radio wire stacked with a roundabout plate, the circle goes about as capacitor so; the actual length of the receiving wire can be diminished while keeping the electrical length equivalent to the length of half frequency dipole receiving wire. The proposed radio wire has been mimicked inside a model comparable to the human body muscle tissue at the clinical embedded correspondence administration (MICS) band (401-405 MHz). The radio wire has an all-out size of 79 mm3, radiation effectiveness of 5.5 % and the 1g found the middle value of SAR is 0.9 W/kg for 1 W input power at the MICS recurrence band. Additionally the detuning impact because of progress of the electrical properties of the human body tissues is still inside the radio wire data transfer capacity. The proposed receiving wire can be planned at the other recurrence groups for biomedical applications, for example, Remote Clinical Media transmission Administrations (WMTS) (1395-1405 MHz) and Modern, Logical, and Clinical (ISM) (2400-2480 MHz). The range of the roundabout circle can be utilized to lessen the actual length of the radio wire.

González-Valenzuela, S., Chen, M., & Leung, V. C. (2011). Mobility support for health monitoring at home using wearable sensors. IEEE Transactions on Information Technology in Biomedicine, 15(4), 539-549.

Gao, Y., Zheng, Y., Diao, S., Toh, W. D., Ang, C. W., Je, M., & Heng, C. H. (2010). Low-power ultrawideband wireless telemetry transceiver for medical sensor applications. IEEE Transactions on Biomedical Engineering, 58(3), 768-772.

Wheeler, H. A. (1947). Fundamental limitations of small antennas. Proceedings of the IRE, 35(12), 1479-1484.

Harrington, R. F. (1960). Effect of antenna size on gain, bandwidth, and efficiency. Journal of Research of the National Bureau of Standards-D. Radio Propagation, 64(1).

Karlsson, A. (2004). Physical limitations of antennas in a lossy medium. IEEE Transactions on Antennas and Propagation, 52(8), 2027-2033.

Davis, W. A., Yang, T., Caswell, E. D., & Stutzman, W. L. (2011). Fundamental limits on antenna size: a new limit. IET microwaves, antennas & propagation, 5(11), 1297-1302.

IEEE Standards Coordinating Committee 34. (2003). IEEE recommended practice for determining the peak spatial-average specific absorption rate (SAR) in the human head from wireless communications devices: measurement techniques. Institute of Electrical and Electronic Engineers.

VDe Santis, V., Feliziani, M., & Maradei, F. (2010). Safety Assessment of UWB Radio Systems for Body Area Network by the ${rm FD}^{2}{rm TD} $ Method. IEEE Transactions on Magnetics, 46(8), 3245-3248.

Vidal, N., Curto, S., Lopez-Villegas,

J. M., Sieiro, J., & Ramos, F. M. (2012, March). Detuning effects on implantable antenna at various human positions. In 2012 6th European Conference on Antennas and Propagation (EUCAP) (pp. 1231-1234). IEEE.

Mahfouz, A. M., Ibrahim, A. A. Y., & Haraz, O. M. (2018, March). Triple-band electrically coupled loop antenna (ECLA) for biomedical implantation purposes. In 2018 35th National Radio Science Conference (NRSC) (pp. 475-480). IEEE.