Miniaturized Compound Spiral Slot Antenna
- Miniaturized Compound Spiral Slot Antennas
- Miniaturized Compound Spiral Slot Antenna Tuner
- Miniaturized Compound Spiral Slot Antenna Booster
- Miniaturized Compound Spiral Slot Antenna Combo
The miniaturized spiral antenna operates from 350 MHz to 16 GHz, showing an ultrawideband behavior. With its use, it is determined that 98% of the harvested power comes from the mobile frequency bands. In particular, 82% of the total power belongs to 800 MHz and 900 MHz frequency bands. Slot spiral miniaturized antenna US9A1 (en). 2000-10-02: 2002-09-05: Mark Winebrand: Slot spiral miniaturized antenna WOA2 (en). 2000-10-02: 2002-04-11: Israel Aircraft Industries Ltd. Slot spiral miniaturized antenna US6413103B1 (en) 2000-11-28: 2002-07-02: Apple Computer, Inc.
Miniaturized Compound Spiral Slot Antennas
10.5120/14829-3074 |
Miniaturized Compound Spiral Slot Antenna Tuner
R Brinda and Sara S Preethy. Article: Miniaturized Antenna with Combination of Meander and Square Spiral Slots for Biomedical Applications. International Journal of Computer Applications 85(4):21-24, January 2014. Full text available. BibTeX
Abstract
The implantable medical devices (IMDs) are one of the most important advanced healthcare systems. Nowadays, the devices which are designed to monitor physiological data from inside the human body have great promises to provide major contributions to disease prevention, diagnosis and therapy thus reducing hospitalization terms and improving the patients' quality of life. It is recognized that modern wireless technology will play an important role in the biomedical application. Essential elements of implantable devices are antenna embedded in system contains Biosensors and interface circuits, which enable the exchange of data between implantable devices and external environment. In this paper, the implantable slot antenna which operates at MICS band (402-405 MHz) has been designed. This implantable antenna is a combination of meander slots and square spiral slots have been embedded for effective size reduction at a fixed frequency operation. Compared to traditional planar inverted-F antennas (PIFAs), the proposed antenna has advantages of good size reduction and also being easy to be optimized to the necessary resonance frequency. This design would fulfill the requirements of biocompatibility, miniaturization, patient safety, and high-quality communication with exterior equipment.
References
- P. Soontornpipit, C. M. Furse, and Y. C. Chung, 'Design of implantable microstrip antennas for communication with medical implants,' IEEE Trans. Microw. Theory Tech. , vol. 52, no. 8, pp. 1944–1951, Aug. 2004.
- T. F. Chien, C. -M. Cheng, H. -C. Yang, J. -W. Jiang and C. -H. Luo,'Development of nonsuperstrate Implantable low-profile CPW-fed ceramic antennas,' IEEE Antennas Wireless Propag. Lett, vol. 9, pp. 599–602, 2010.
- Changrong Liu, Yong-Xin Guo, Shaoqiu Xiao, 'A Hybrid Patch/Slot Implantable Antenna for Biotelemetry Devices,' Antennas Propag. Mag. IEEE, vol. 11, Jun. 2012.
- A. Kiourti and K. S. Nikita, 'Miniature Scalp Implantable Antennas for Telemetry in the MICS and ISM Bands: Design, Safety Considerations and Link Budget Analysis,' IEEE Trans. Antennas Propag.
- A. Kiourti and K. S. Nikita, 'A Review of Implantable Patch Antennas for Biomedical Telemetry: Challenges and Solutions,' Antennas Propag. Mag. IEEE, vol. 54, no. 3, pp. 210 – 228, Jun. 2012.
- C. -M. Lee, T. -C. Yo, C. -H. Luo, C. -H. Tu and Y. -Z. Juang, 'Compact broadband stacked implantable antenna for biotelemetry with medical devices. ' Electron. Lett. vol. 43, no. 12, pp. 660–662, Jun. 7, 2007.
- M. Meyers, P. Chen, A. Lin, and Y. Seki, 'Biological materials: Structure and mechanical properties,' Prog. Mater. Sci. , no. 53, pp. 201–206, 2008.
- T. Karacolak, A. Hood, and E. Topsakal, 'Design of a dual-band implantable antenna and development of skin mimicking gels for continuous glucose monitoring,' IEEE Trans. Microw. Theory Tech. , vol. 56, no. 4, pp. 1001–1008, Apr. 2008.
- T. Karacolak, R. Cooper, and E. Topsakal, 'Electrical properties of rat skin and design of implantable antennas for medical wireless telemetry,' IEEE Trans. Antennas Propag. , vol. 57, no. 9, pp. 2806–2812, Sep. 2009.
- W. -C. Liu, S. -H. Chen and C. -M. Wu, 'Bandwidth enhancement and size reduction of an implantable PIFA antenna for biotelemetry devices,' Microw. Opt. Technol. Lett. , vol. 51, pp. 755–757, Mar. 2009.
- W. Xia, K. Saito, M. Takahashi, and K. Ito, 'Performances of an implanted cavity slot antenna embedded in the human arm,' IEEE Trans. Antennas Propag. , vol. 57, no. 4, pp. 894–899, Apr. 2009.
- S. Stupp and P. Braun, 'Molecular Manipulation of Microstructures: Biomaterials, Ceramics, and Semiconductors,' Science, no. 277, pp. 1242–1248, 1997.
- T. Karacolak, R. Cooper, J. Butler, S. Fisher, and E. Topsakal, 'In vivo verification of implantable antennas using rats as model animal,' IEEE Antennas Wireless Propag. Lett. vol. 9, pp. 334–337, 2010.
- C. J. Sanchez Fernandez, O. Quevedo-Teruel, J. Requena-Carrión, L. Inclán-Sánchez, and E. Rajo-Iglesias, 'Dual-band microstrip patch antenna based on short-circuited ring and spiral resonators for implantable medical devices,' Microw. , Antennas Propag. , vol. 4, no. 8, pp. 1048–1055, 2010.
- A. Kiourti, M. Tsakalakis, and K. S. Nikita, 'Parametric Study and Design of Implantable PIFAs for Wireless Biotelemetry,' Proc. 2nd Icst Int. Conf. Wirel. Mob. Common. Health. Mobihealth 2012 Kos Isl. Greece, Oct. 2011.
- A. Kiourti, K. S. Nikita, and M. Christopoulou, 'Performance of a Novel Miniature Antenna Implanted in the Human Head for Wireless Biotelemetry,' IEEE Int. Symp. Antennas Propag. Spokane Wash. , Jul. 2011.
- P. D. Bradley, 'Wireless Medical Implant Technology - Recent Advances and Future Developments,' Esscirc 2011 Proc. , pp. 37 – 41, 2011.
- A. K. Skriverviky and F. Merli, 'Design strategies for implantable antennas,' Antennas Propag. Conf. Lapc 2011 Loughb. , pp. 1 – 5, Nov. 2011
- F. Merli, 'Implantable Antennas for Biomedical Applications,' Ecole Polytechnique Federale De Lausanne, 2011.
- IEEE, 'Standard for Safety Levels with Respect to Human Exposure to Radio Frequency Electromagnetic Fields, 3kHz to 300GHz,' 2005.
- A. Kumar, A. Srivastava, I. Galaev, and B. Mattiasson, 'Smart polymers: Physical forms and bioengineering applications,' Prog. Polym. Sci. , vol. 32, no. 10, pp. 1205– 1237, 2007.
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Miniaturized Compound Spiral Slot Antenna Booster
Abstract
Miniaturized Compound Spiral Slot Antenna Combo
The implantable medical devices (IMDs) are one of the most important advanced healthcare systems. Nowadays, the devices which are designed to monitor physiological data from inside the human body have great promises to provide major contributions to disease prevention, diagnosis and therapy thus reducing hospitalization terms and improving the patients ’ quality of life. It is recognized that modern wireless technology will play an important role in the biomedical application. Essential elements of implantable devices are antenna embedded in system contains Biosensors and interface circuits, which enable the exchange of data between implantable devices and external environment. In this paper, the implantable slot antenna which operates at MICS band (402-405 MHz) has been designed. This implantable antenna is a combination of meander slots and square spiral slots have been embedded for effective size reduction at a fixed frequency operation. Compared to traditional planar inverted-F antennas (PIFAs), the proposed antenna has advantages of good size reduction and also being easy to be optimized to the necessary resonance frequency. This design would fulfill the requirements of biocompatibility, miniaturization, patient safety, and high-quality communication with exterior equipment.