Abstract
In this paper we have worked out on some the complex modeling aspects such as Multi Scale modeling, MATLAB Sugar based modeling and have shown the complexities involved in the analysis of Nano RFID (Radio Frequency Identification) systems. We have shown the modeling and simulation and demonstrated some novel ideas and library development for Nano RFID. Multi scale modeling plays a very important role in nanotech enabled devices properties of which cannot be explained sometimes by abstraction level theories. Reliability and packaging still remains one the major hindrances in practical implementation of Nano RFID based devices. And to work on them modeling and simulation will play a very important role. CNTs is the future low power material that will replace CMOS and its integration with CMOS, MEMS circuitry will play an important role in realizing the true power in Nano RFID systems. RFID based on innovations in nanotechnology has been shown. MEMS modeling of Antenna, sensors and its integration in the circuitry has been shown. Thus incorporating this we can design a Nano-RFID which can be used in areas like human implantation and complex banking applications. We have proposed modeling of RFID using the concept of multi scale modeling to accurately predict its properties. Also we give the modeling of MEMS devices that are proposed recently that can see possible application in RFID. We have also covered the applications and the advantages of Nano RFID in various areas. RF MEMS has been matured and its devices are being successfully commercialized but taking it to limits of nano domains and integration with singly chip RFID needs a novel approach which is being proposed. We have modeled MEMS based transponder and shown the distribution for multi scale modeling for Nano RFID.
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References
Cabrera, M., Burgelman, J.-C., Boden, M., da Costa, O., Rodríguez, C.: eHealth in 2010: Realising a Knowledge-based Approach to Healthcare in the EU Challenges for the Ambient Care System. European Commission Joint Research Centre (April 2004), http://www.stop-project.eu/portals/1/publications/eur22770en.pdf
Nano Technology Business Research Report: A study of business’ understanding of and attitudes towards nanotechnology. Dandolopartners (July 11, 2005), http://www.innovation.gov.au/Industry/Nanotechnology/Documents/FinalBusReportJuly20051021103038.pdf
Cavalcanti, A., Shirinzadeh, B., Freitas Jr., R.A., Kretly, L.C.: Medical Nanorobot Architecture Based on Nanobioelectronics. Recent Patents on Nanotechnology 1(1) (Feburary 2007), http://www.bentham.org/nanotec/samples/nanotec1-1/Cavalcanti.pdf
Ausen, D., Westvik, R., Svagård, I., Österlund, L., Gustafson, I., Vikholm-Lundin, I., Winquist, F., Lading, L., Gran, J.: Foresight Biomedical Sensors. Nordic Innovation Centre (NICe) project number: 04247 (September 2007), http://www.sintef.no/project/FOBIS/FOBIS_final%20report_web.pdf
Cui, Y.: Antenna Design for On-the-body Sensors. M.Sc. Thesis. MIC - Department of Micro and Nanotechnology Technical University of Denmark (Feburary 2006), http://www.nanotech.dtu.dk/upload/institutter/mic/forskning/mems-appliedsensors/publications/master_thesis/2006%20ying%20cui.pdf
Opinion on the ethical aspects of ICT implants in the human body: No. 20. The European Group on Ethics in Science and New Technologies to the European Commission (March 16, 2005), http://ec.europa.eu/european_group_ethics/docs/avis20compl_en.pdf
Radio frequency identification (RFID) at HP. White paper, Hewlett-Packard Development Company (2004), http://h71028.www7.hp.com/ERC/downloads/5982-4290EN.pdf
Meingast, M., King, J., Mulligan, D.K.: Security and Privacy Risks of Embedded RFID in Everyday Things: the e-Passport and Beyond. Journal of Communications 2(7) (December 2007), http://www.academypublisher.com/jcm/vol02/no07/jcm02073648.pdf
Srivastava, L.: Ubiquitous Network Societies: The Case of Radio Frequency Identification. International Telecommunication Union (2005), http://www.itu.int/osg/spu/ni/ubiquitous/Papers/RFID%20background%20paper.pdf
European Policy Outlook RFID. European Commission, Brussels, Federal Ministry of Economics and Technology (BMWi) (July 2007), http://www.iot-visitthefuture.eu/fileadmin/documents/roleofeuropeancommision/European_Policy_Outlock_RFID.pdf
Curty, J.-P., Joehl, N., Dehollain, C., Declercq, M.J.: Remotely powered addressable UHF RFID integrated system. IEEE Journal of Solid-State Circuits 40(11), 2193–2202 (2005)
Shameli, A., Safarian, A., Rofougaran, A., Rofougaran, M., Castaneda, J., De Flaviis, F.: A UHF Near-Field RFID System With Fully Integrated Transponder. IEEE Transactions on Microwave Theory and Techniques. Part 2, 56(5), 1267–1277 (2008)
Jiang, B., Smith, J.R., Philipose, M., Roy, S., Sundara-Rajan, K., Mamishev, A.V.: Energy Scavenging for Inductively Coupled Passive RFID Systems. IEEE Transactions on Instrumentation and Measurement 56(1), 118–125 (2007)
Kaya, T., Koser, H.: A New Batteryless Active RFID System: Smart RFID. In: 1st Annual RFID Eurasia, 2007, September 2007, pp. 1–4 (2007), doi:10.1109/RFIDEURASIA.2007.4368151
Lu, H.M., Goldsmith, C., Cauller, L., Lee, J.-B.: MEMS-Based Inductively Coupled RFID Transponder for Implantable Wireless Sensor Applications. IEEE Transactions on Magnetics 43(6), 2412–2414 (2007)
Jiang, B., Fishkin, K.P., Roy, S., Philipose, M.: Unobtrusive long-range detection of passive RFID tag motion. IEEE Transactions on Instrumentation and Measurement 55(1), 187–196 (2006)
Sasaki, S., Seki, T., Imanaka, K., Kimata, M., Toriyama, T., Miyano, T., Sugiyama, S.: Batteryless-Wireless MEMS Sensor System with a 3D Loop Antenna. In: IEEE Sensors, October 2007, pp. 252–255 (2007), doi:10.1109/ICSENS.2007.4388384
Finkenzeller, K.: RFID Handbook. Wiley, Hoboken (1999)
Chen, C., Xu, D., Kong, E.S.-W., Zhang, Y.: Multichannel Carbon-Nanotube FETs and Complementary Logic Gates With Nanowelded Contacts. IEEE Electron Device Letters 27(10), 852–855 (2006)
Keshavarzi, A., Raychowdhury, A., Kurtin, J., Roy, K., De, V.: Carbon Nanotube Field-Effect Transistors for High-Performance Digital Circuits— Transient Analysis, Parasitics, and Scalability. IEEE Transactions on Electron Devices 53(11), 2718–2726 (2006)
Wong, B., Mittal, A., Cao, Y., Starr, G.W.: NANO-CMOS Circuit and Physical Design. IEEE Wiley-IEEE Press, ISBN: 978-0-471-46610-9
Cho, T.S., Lee, K.-j., Kong, J., Chandrakasan, A.P.: The design of a low power carbon nanotube chemical sensor system. In: Proc. 45th ACM/IEEE Design Automation Conference, 2008. DAC 2008, June 8-13, pp. 84–89 (2008)
RF MEMS Theory, Design, and Technology Gabriel M. Rebeiz
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Pathak, R., Joshi, S. (2009). Multi-scale Modeling and Analysis of Nano-RFID Systems on HPC Setup. In: Ranka, S., et al. Contemporary Computing. IC3 2009. Communications in Computer and Information Science, vol 40. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-03547-0_61
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DOI: https://doi.org/10.1007/978-3-642-03547-0_61
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