Smart Electrical Vehicle

B. Ram Vara Prasad *, Ch. Prasanthi **, G. Jyothika Santhoshini ***, K. J. S. V. Kranti Kumar ****, K. Yernaidu *****
*-***** Department of Electrical and Electronics Engineering, Lendi Institute of Engineering & Technology, Vizianagaram, Andhra Pradesh, India.
Periodicity:January - June'2020


The primary objective of this paper is to design a feasible yet highly adaptable E-BICYCLE, as number of motor vehicles on the roads all-over the world increases. The worlds’ car usage is booming. Cars are polluting the cities as they consume large quantity of Petroleum and the amounts of carbon dioxide released increases which in turn pollutes the green house gases causing climate change. Huge amount of money is being spent on the development and manufacturing of electrical vehicles. This paper presents the study of design of Electrical Bicycle. The aim of this paper is to design a simple, cost effective model of Electrical Bicycle with intelligent control system. The materials used are mostly environmental friendly and cost is much lower than the existing electric power bike. This can be implemented by connecting an electrical motor, a controller and battery pack, cabling and monitoring instruments.


BLDC Motor, Controller, Battery System, Electrical Bicycle, Pollution, Intelligent Control System.

How to Cite this Article?

Prasad, B. R. V., Prasanthi, Ch., Santhoshini, G. J., Kumar, K. J. S. V. K., and Yernaidu, K. (2020). Smart Electrical Vehicle. i-manager's Journal on Digital Signal Processing, 8(1), 7-14.


[1]. Chuang, H. S., Ke, Y. L., & Chuang, Y. C. (2009, May). Analysis of commutation torque ripple using different PWM modes in BLDC motors. In Conference Record 2009 IEEE Industrial & Commercial Power Systems Technical Conference (pp. 1-6). IEEE.
[2]. Colton, S. (2009). A simple series battery/ultracapacitor drive system for light vehicles and educational demonstration. In Fourth International Conference & Exhibition on Ecological Vehicles and Renewable Energies.
[3]. Dixon, J., Nakashima, I., Arcos, E. F., & Ortúzar, M. (2009). Electric vehicle using a combination of ultracapacitors and ZEBRA battery. IEEE Transactions on Industrial Electronics, 57(3), 943-949.
[4]. Dolly, R. A. (2015). Enhancement of PFC and torque ripple reduction using bl buck-boost converter fed hcc bldc drive. International Journal of Research, 2(11), 895–901.
[5]. Jones, D., & Stitt, M. (1997). Precision absolute value circuits. Burr-Brown Application Bulletin.
[6]. Manoj, E., Isa, D., & Arelhi, R. (2010). Super capacitor/battery hybrid powered electric bicycle via a smart boost converter. World Electric Vehicle Journal, 4(2), 280-286. Retrieved 02_PEARL_Arch/Vol_16/Sec_53/Burr_Brown_App_Notes/AB- 121.pdf
[7]. Ortúzar, M., Moreno, J., & Dixon, J. (2007). Ultracapacitor-based auxiliary energy system for an electric vehicle: Implementation and evaluation. IEEE Transactions on Industrial Electronics, 54(4), 2147-2156.
[8]. Prasad, B. R. V., Baba, C. H., Kumar, B. A., Vamsi, J., & Rajendra, G. (2019). Solar Powered BLDC Motor with HCC Fed Water Pumping System for Irrigation. International Journal for Research in Applied Science & Engineering Technology, 7(3), 788-796. t.2019.3137
[9]. Prasad, B. R. V., Babu, K. M., Sreekanth, K., Naveen, K., & Kumar, C. V. (2018). Minimization of torque ripple of brushless DC motor using HCC with DC-DC converter. International Journal of Research, 05(12), 110–117.
[10]. Prasad, B. R. V., Kiranmayee, S. S., Venkatesh, M., Sowrya, M. V., & Venugopal, S. (2020). Highway monitoring system and power saving. International Journal of Creative Research Thoughts (IJCRT), 8(4), 2270-2274.
[11]. Prasad, B. R. V., Poojitha, D. V. S. J., & Suneetha, K. (2017). Closed-loop control of bldc motor driven solar PV array using zeta converter fed water pumping system. International Journal of Research, 4(17), 2795-2803.
[12]. Salah, W. A., Ishak, D., & Hammadi, K. J. (2011). Minimization of torque ripples in BLDC motors due to phase commutation: A review. Przeglad Elektrotechniczny, 87(1), 182-188.
[13]. Su, N., Xu, D., Chen, M., & Tao, J. (2008, September). Study of bi-directional buck-boost converter with different control methods. In 2008 IEEE Vehicle Power and Propulsion Conference (pp. 1-5). IEEE.
[14]. Yedamale, P. (2003). Brushless DC (BLDC) motor fundamentals. Microchip Technology Inc. Retrieved http:// hless%20DC%20(BLDC)%20Motor%20Fundamentals.pdf

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