Madhu Jain

Work place: Department of Electronics and Communication Engineering, Jaypee Institute of Information Technology, A-10, Sector-62, Noida 201307, Uttar Pradesh, India

E-mail: ermadhu2003@gmail.com

Website:

Research Interests: Computer systems and computational processes, Embedded System

Biography

Madhu Jain is Associate Professor in Electronics & Communication Engineering Department, Jaypee Institute of Information Technology, Noida, India. She received B.E. degree in Electronics and Communication Engineering from University of Rajasthan, M. Tech. degree in Signal Processing from University of Delhi and Ph. D. degree from Indian Institute of Technology, Delhi, India. Her major teaching and research interest include Signal Processing and Embedded System. She has co-authored 18 research papers in the above areas in various international journals and conferences.

Author Articles
Design of Fractional Order Recursive Digital Differintegrators using Different Approximation Techniques

By Madhu Jain Maneesha Gupta

DOI: https://doi.org/10.5815/ijisa.2020.01.04, Pub. Date: 8 Feb. 2020

Digital integer and fractional order integrators and differentiators are very important blocks of digital signal processing. In many situations, integer order integrators and differentiators are not sufficient to model all kind of dynamics. For such systems, fractional order operators give better solution. This paper is based on design of a new family of fractional order integrators and differentiators using various approximation techniques. Here, digital fractional order integrators are designed by direct discretization method using different techniques like continued fraction expansion, Taylor series expansion, and rational Chebyshev approximation on the transfer function of Jain-Gupta-Jain second order integrator. Their response in frequency domain is compared. The frequency response of the proposed integrators with highest efficiency is also compared with the existing ones. It is proved that rational Chebyshev approximation based integrators have highest efficiency among them. The fractional order differentiators are also designed using proposed integrators. It is concluded that proposed family of fractional order operators show remarkable improvement in frequency response compared to all the existing ones over the entire Nyquist frequency range.

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