Advanced Digital Organic Vehicle Security System

Authors

  • Arun Pratap Singh Rathod Department of Electronics & Communication Engineering, School of Engineering and Technology Graphic Era University, Dehradun 248002, Uttarakhand, India
  • Poornima Mittal Department of Electronics & Communication Engineering, School of Engineering and Technology Graphic Era University, Dehradun 248002, Uttarakhand, India
  • Brijesh Kumar Departemnt of Electronics and Communication Engineering M. M. M. University of Technology Gorakhpur-273010, Uttar Pradesh, India

Keywords:

Security system, Organic, OTFT, Digital interface, FPGA

Abstract

This paper is about presenting an economical and simple vehicle security system by which a vehicle can identify
its user and provide security against any unauthorized access to the vehicle. In this paper we have designed and
implemented a simple digital interface (DI) at the front end which when placed between car battery and ignition
system it makes the vehicle smart enough to identify its user with help of a security PIN. Further this vehicle
system utilizes organic transistors which itself are quite innovative and widely used as alternative to
conventional MOSFETs for cost efficient applications. Here too we have utilized them to make DI economical
in cost and robust in nature to overcome much troubled issue of modern times i.e. stealing of vehicles with or
without vehicle keys.

Downloads

Download data is not yet available.

References

Alrabady, A. I., & Mahmud, S. M. (2005). Analysis of attacks against the security of keyless-entry systems for

vehicles and suggestions for improved designs. IEEE Transactions on Vehicular Technology, 54(1), 41-50.

Bakhshi, A. K., & Bhalla, G. (2004). Electrically conducting polymers: Materials of the twenty first

century. Journal of Scientific and Industrial Research, 63, 715-728.

Ciletti, Michael D., Mano, M. Morris, (2007). Digital Design (1st Ed.). Pearson India.

Klauk, H. (Ed.). (2006). Organic electronics: materials, manufacturing, and applications. John Wiley & Sons.

Kumar, B., Kaushik, B. K., & Negi, Y. S. (2012, December). Analysis of Contact Resistance Effect on

Performance of Organic Thin Film Transistors. In Electronic System Design (ISED), 2012 International

Symposium on (pp. 198-202). IEEE.

Kumar, B., Kaushik, B. K., & Negi, Y. S. (2013). Modeling of top and bottom contact structure organic field

effect transistors. Journal of Vacuum Science & Technology B, 31(1), 012401.

Kumar, B., Kaushik, B. K., & Negi, Y. S. (2014). Organic thin film transistors: structures, models, materials,

fabrication, and applications: a review. Polymer Reviews, 54(1), 33-111.

Locci, S. (2009). Modeling of physical and electrical characteristics of organic thin film transistors.

Locci, S., Maccioni, M., Orgiu, E., & Bonfiglio, A. (2007). An analytical model for cylindrical thin-film

transistors. IEEE Transactions on Electron Devices, 54(9), 2362.

McMahon, M. (2013). Trade of Motor Mechanic: Basic Ignition Systems (2nd Ed). SOLAS.

Pedroni, V. A. (2004). Circuit Design with VHDL, (1st Ed.). MIT Press London.

Roth, C. H. (1998). Digital systems design using VHDL (Vol. 20). PWS publishing company.

Voge, C. J. (1933). U.S. Patent No. 1,928,744. Washington, DC: U.S. Patent and Trademark Office

Downloads

Published

2023-02-28

How to Cite

Rathod, A. P. S., Mittal, P., & Kumar, B. (2023). Advanced Digital Organic Vehicle Security System. Journal of Graphic Era University, 4(2), 72–84. Retrieved from https://riverpublishersjournal.com/index.php/JGEU/article/view/119

Issue

2016: Vol 4 Iss 2 2016

Section

Articles