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Reseach Article

Implementation of Tunable and Non-Tunable Pseudo-Resistors using 0.18mm Technology

Published on December 2016 by Kulbhushan Sharma, Lipika Gupta
National Symposium on Modern Information and Communication Technologies for Digital India
Foundation of Computer Science USA
MICTDI2016 - Number 2
December 2016
Authors: Kulbhushan Sharma, Lipika Gupta
4ebff7aa-8b9c-42fd-bc14-14eee27683bf

Kulbhushan Sharma, Lipika Gupta . Implementation of Tunable and Non-Tunable Pseudo-Resistors using 0.18mm Technology. National Symposium on Modern Information and Communication Technologies for Digital India. MICTDI2016, 2 (December 2016), 23-27.

@article{
author = { Kulbhushan Sharma, Lipika Gupta },
title = { Implementation of Tunable and Non-Tunable Pseudo-Resistors using 0.18mm Technology },
journal = { National Symposium on Modern Information and Communication Technologies for Digital India },
issue_date = { December 2016 },
volume = { MICTDI2016 },
number = { 2 },
month = { December },
year = { 2016 },
issn = 0975-8887,
pages = { 23-27 },
numpages = 5,
url = { /proceedings/mictdi2016/number2/26556-1615/ },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Proceeding Article
%1 National Symposium on Modern Information and Communication Technologies for Digital India
%A Kulbhushan Sharma
%A Lipika Gupta
%T Implementation of Tunable and Non-Tunable Pseudo-Resistors using 0.18mm Technology
%J National Symposium on Modern Information and Communication Technologies for Digital India
%@ 0975-8887
%V MICTDI2016
%N 2
%P 23-27
%D 2016
%I International Journal of Computer Applications
Abstract

in integrated circuits implemented to attain high value resistance. Incremental resistance for both non-tunable, tunable pseudo-resistor has been estimated in Cadence Analog Design Environment using 0. 18?m technology. Pseudo-resistors make use of diode-connected MOS devices working in subthreshold region and consume less area as compared to the discrete counterpart. Different V-R curves for both non-tunable and tunable pseudo-resistors are obtained and a comparison is presented in terms of linearity and consistency. Low tuning voltages, currents and smaller W/L ratios are selected for analysis to obtain high value resistors greater than 1011 ?. It also leads to the design of Low power integrated circuits

References
  1. N. Neshatvar, H. A. Nashash and L. Albasha, " Design of Low Frequency Analog Low Pass Filter Using Tunable Pseudo-resistors," Middle East Conference on Biomedical Engineering (MECBME) pp. 17-20, February 2014.
  2. T. Delbrück and C. A. Mead, "Analog VLSI adaptive, logarithmic widedy namic-range photoreceptor," in Proc. IEEE Int. Symp. Circuitsand Systems, vol. 4, pp. 339–342, 1994.
  3. R. Harrison and C. Charles, "A Low-Power Low-Noise CMOS Amplifier for Neural Recording Application," IEEE Journal of solid-state circuits, vol. 38, no. 36, pp. 958-965, June 2003.
  4. S. Hwang, K. Aninakwa and S. Sonkusale, "Bandwidth tunableamplifier for recording biopotential signals," EMBS, pp. 662-665, 2010.
  5. H. M. Aliabad, M. M. Nejad, E. Shadkami, N. Khorashahian and M. Mianji "Design of an ECG Signals Amplifier with programmable Gain and Bandwidth Based on a New Method in Pseudo-Resistor Circuits," Bulletin of Environment, Pharmacology and Life Sciences, vol. 4, no. 1, pp. 131-141, 2014.
  6. X. Zou, X. Xu, L. Yao, Y. Lian, "A 1-V 450-nW Fully Integrated Programmable Biomedical Sensor Interface Chip," IEEE Journal of solid-state circuits, vol. 44, no. 4, pp. 1067-1077, April 2009.
  7. N. Neshatvar, H. A. Nashash, L. A. Basha, "Design Of Low Frequency Highpass Filter Using pseudo resistors," 1st Middle East Conference on Biomedical Engineering (MECBME) pp. 407-410, Feb 2011.
  8. K. Yao, C. Gong, S. Yang and M. Shiue, "Design of a Neural Recording Amplifier with Tunable Pseudo Resistors," IEEE International SOC Conference(SOCC), pp. 376-379, September 2011.
  9. R. Jacob Baker, CMOS Circuit Design, Layout and Simulation, 2nd ed. John Wiley & Son.
  10. S. Ha, Yu M. Chi, A. Akinin, C. Maier, A. Ueno and G. Cauwenberghs, "Integrated Circuits and Electrode Interfaces for Noninvasive Physiological Monitoring," IEEE Transactions On Biomedical Engineering, vol 5, pp: 1522-1537, May 2014.
  11. H. Dehsorkh, N. Ravanshad, R. Lofti and A. Sodagar, "Analysis and Design of Tunable Amplifiers for Implantable Neural Recording Applications," IEEE Journal on Emerging and Selected Topics on Circuits and system, vol. 1, no. 4, pp. 546-556, December 2011.
  12. H. Dehsorkh, N. Ravanshad, R. Lofti and K. Mafinezhad, "A Linear Tunable Amplifier for Implantable Neural Recording Applications," IEEE International Midwest Symposium on Circuits and system (MWSCAS), pp. 1-4 , 2011.
  13. E. Vittoz, C. Enz, and F. Krummenacher, "Workshop on Compact Modeling," Proc. vol. 2, pp. 246-249, Feb, 2003.
Index Terms

Computer Science
Information Sciences

Keywords

Tunable Pseudo-resistors Topologies Integrated Circuits Subthreshold Region.