Encrypt Data with Electromagnetic Waves Using Printable Structures and Materials
Main Article Content
Abstract
In this paper, the authors have analyzed the problem of data encryption by electromagnetic waves, the approach and the challenges that need to be solved, studied the selection of suitable materials to give a new structure design to address printable structure. It will help reducing costs, as well as simplifying production in large quantities. The structure uses a polyimide substrate and conductive ink with a fabrication method of common inkjet technology. The structure is designed based on dipole antenna array for each frequency set. Data is encoded on the basis of determining the feedback power at predetermined frequencies in the range of 3GHz to 9GHz via RCS factor. CST Microwave Studio software is used to design and simulate structures with the ability to encode 5 data bits per frequency set. Encryption structure has a simple design, allowing to improve the data encryption with a small size.
Keywords
Chipless RFID, wireless sensor, radar cross section, frequency coding
Article Details
References
[1] Gang Zhao, Luyu Lin, Yawen Chen, Shan Liu, Jie Chu, Zhuoran Luo, Barcode character defect detection method based on Tesseract-OCR. 3rd IEEE International Conference on Computer and Communications (ICCC) (2017).
[2] G. SriHarsha Vardhan, Naveen Sivadasan, Ashudeb Dutta, QR-code based chipless RFID system for unique identification. IEEE International Conference on RFID Technology and Applications (RFID-TA) (2016).
[3] Sudhanshu Gakhar, Joseph Feldkamp, Mark Perkins, Rensheng Sun, C. J Reddy, Engineering RFID systems through Electromagnetic Modeling. IEEE International Conference on RFID (2008).
[4] Ali Hashemi, Amir Hossein Sarhaddi, Hossein Emami, A Review on Chipless Tag Design. Majlesi Journal of Electrical Engineering (2013).
[5] Ang Yu, Osamudiamie Idubore, Mihai Dimian, Radar cross section calculation for subsurface objects. IEEE Radar Conference (RadarConf) (2016).
[6] Bassem R.Mahafza, Radar Systems Analysis and Design Using MATLAB, 3rd Edition. CRC Press (2010).
[7] Sigma-Aldrich. DGP-45HTG silverink datasheet. http://aaldirich.com/catalog/product/aldrich.
[8] M.Y. Ismail, M. Imam, Analysis of Design Optimization of Bandwidth and Loss Performance of Reflectarray Antennas Based on Material Properties. Modern Applied Science, Vol.4, No. 1 (2010).
[9] Pranavesh VS, Priyanka Jain, Study of effect of dielectric superstrate on resonance frequency of patch antenna and measurement of dielectric constant of superstrate. ICTICT (2016).
[10] Constantine A. Balanis, Antenna Theory: Analysis and Design, 3rd Edition. John Wiley & Sons, Inc. (2005).
[11] J. Lorenzo, A. Lazaro, R. Villarino, D. Girbau, Backscatter tag based on frequency selective surface for FMCW radar applications. 1st URSI Atlantic Radio Science Conference (URSI AT-RASC) (2015).
[2] G. SriHarsha Vardhan, Naveen Sivadasan, Ashudeb Dutta, QR-code based chipless RFID system for unique identification. IEEE International Conference on RFID Technology and Applications (RFID-TA) (2016).
[3] Sudhanshu Gakhar, Joseph Feldkamp, Mark Perkins, Rensheng Sun, C. J Reddy, Engineering RFID systems through Electromagnetic Modeling. IEEE International Conference on RFID (2008).
[4] Ali Hashemi, Amir Hossein Sarhaddi, Hossein Emami, A Review on Chipless Tag Design. Majlesi Journal of Electrical Engineering (2013).
[5] Ang Yu, Osamudiamie Idubore, Mihai Dimian, Radar cross section calculation for subsurface objects. IEEE Radar Conference (RadarConf) (2016).
[6] Bassem R.Mahafza, Radar Systems Analysis and Design Using MATLAB, 3rd Edition. CRC Press (2010).
[7] Sigma-Aldrich. DGP-45HTG silverink datasheet. http://aaldirich.com/catalog/product/aldrich.
[8] M.Y. Ismail, M. Imam, Analysis of Design Optimization of Bandwidth and Loss Performance of Reflectarray Antennas Based on Material Properties. Modern Applied Science, Vol.4, No. 1 (2010).
[9] Pranavesh VS, Priyanka Jain, Study of effect of dielectric superstrate on resonance frequency of patch antenna and measurement of dielectric constant of superstrate. ICTICT (2016).
[10] Constantine A. Balanis, Antenna Theory: Analysis and Design, 3rd Edition. John Wiley & Sons, Inc. (2005).
[11] J. Lorenzo, A. Lazaro, R. Villarino, D. Girbau, Backscatter tag based on frequency selective surface for FMCW radar applications. 1st URSI Atlantic Radio Science Conference (URSI AT-RASC) (2015).