Feb 7, 2017

[paper] Impact of technology scaling on analog and RF performance of SOI–TFET

Impact of technology scaling on analog and RF performance of SOI–TFET
P Kumari, S Dash and G P Mishra
Advances in Natural Sciences: Nanoscience and Nanotechnology, Volume 6, Number 4 
Published 9 October 2015

Abstract
This paper presents both the analytical and simulation study of analog and RF performance for single gate semiconductor on insulator tunnel field effect transistor in an extensive manner. Here 2D drain current model has been developed using initial and final tunneling length of band-to-band process. The investigation is further extended to the quantitative and comprehensive analysis of analog parameters such as surface potential, electric field, tunneling path, and transfer characteristics of the device. The impact of scaling of gate oxide thickness and silicon body thickness on the electrostatic and RF performance of the device is discussed. The analytical model results are validated with TCAD Sentaurus device simulation results [read more...]

Citations
[1] Extensive electrostatic investigation of workfunction-modulated SOI tunnel FETs Subhrasmita Panda et al  2016 Journal of Computational Electronics 15 1326
[2] S. Sahoo et al  2016 337
[3] A comprehensive investigation of silicon film thickness (T SI) of nanoscale DG TFET for low power applications Rajeev Ranjan et al  2016 Advances in Natural Sciences: Nanoscience and Nanotechnology 7 03500
[4] A complete analytical potential based solution for a 4H-SiC MOSFET in nanoscale M K Yadav et al  2016 Advances in Natural Sciences: Nanoscience and Nanotechnology 7 025011
[5] S. Dash et al  2015 447
   

Feb 5, 2017

[paper] Processes of AM-PM Distortion in Large-Signal Single-FET Amplifiers

Processes of AM-PM Distortion in Large-Signal Single-FET Amplifiers
S. Golara, S. Moloudi and A. A. Abidi, " 
in IEEE Transactions on Circuits and Systems I: Regular Papers
vol. 64, no. 2, pp. 245-260, Feb. 2017; doi: 10.1109/TCSI.2016.2604000
Abstract: Using an appropriate formulation of field-effect transistor (FET) current as a nonlinear function of terminal voltages, and a simplified model of gain compression in common source amplifiers, we are able to identify four principal sources of amplitude-to-phase (AM-PM) distortion. A new analysis shows the varactor effect of gate-source capacitance on AM-PM distortion, and the changing Miller-multiplied gate-drain capacitance as the field-effect transistor (FET) is driven into compression. The phase shift in the load impedance at the frequency of operation and incomplete suppression of 2nd harmonic by a resonant load of limited Q are explained and analyzed. We are able to identify the dominant mechanism of AM-PM distortion in various practical circuits, which then suggests methods of remediation. The analysis was put to test by predicting the measured AM-PM distortion of power amplifiers reported in the literature. Good agreement is found in all cases, with insights gained into the dominant cause of distortion in each case. In this paper, AM-PM distortion is first defined in Section II. In Section III, the EKV model of the MOSFET is briefly presented and dominant mechanisms are explained. In Section IV the analysis is compared against measured data to validate the theory and Section V summarizes the conclusions [read more...]

Feb 1, 2017

IEEE Workshop on Compact Modeling

IEEE Workshop on Compact Modeling
March 3, 2017
Technical Sponsorship by: IEEE Electron Devices Society UP Chapter
Organized by: Department of Electrical Engineering, IIT Kanpur
Coordinator: Prof. Yogesh Singh Chauhan
Venue: Outreach Auditorium, IIT Kanpur

IEEE Workshop on Compact Modeling Agenda:
Time Topic Speaker
8:00 - 8:15 Workshop inauguration by Director IIT Kanpur and IEEE-UP Chairman
8:15 - 9:00 Industry Standard Compact Modelling Dr. Yogesh Singh Chauhan
IIT Kanpur
9:00 - 9:30 Modelling of mismatch and process variations Dr. Abhisek Dixit
IIT-Delhi
9:30 - 10:00 TBA Dr. Nihar Ranjan Mohapatra
IIT-Gandhinagar
10:00 - 10:30 Modelling of normally-off GaN based MOSHEMT Dr. Trupti Ranjan Lenka
NIT Silchar
10:30 - 10:45 ASM-HEMT: Industry standard compact model for GaN HEMTs Dr. Sudip Ghosh
IIT-Kanpur
10:45 - 11:00 Modelling of quasi ballistic transport in nano-wire transistors Mr. Avirup Dasgupta
IIT Kanpur
11:00 - 11:15 TBA Mr. Priyank Rastogi
IIT Kanpur
11:15 - 11:30 Compact modelling of TMD based thin body transistors Mr. Chandan Yadav
IIT Kanpur
11:30 - 11:45 Tea Break
11:45 - 12:15 Qualification techniques for sim models for EEsof products Mr. Mohit Khanna
Keysight Technologies
12:15 - 12:45 High frequency device characterization and modeling for THz applications Prof. Thomas Zimmer
IMS-BORDEAUX
12:45 - 2:00 Lunch
2:00 - 2:30 Device design consideration: IoT perspective Dr. Santosh Kumar Vishvakarma
IIT-Indore
2:30 - 3:00 TBA Dr. Aditya Sankar Medury
IISER-Bhopal
3:00 - 3:30 Simulations, analysis and applications of doping- and junction- free transistors Dr. Jawar Singh
IIIT-Jabalpur
3:30 - 4:00 Design of radiation hardened 24-bit ADC for generic applications Mr. H.S.Jattana
SCL
4:00 - 4:15 Tea Break
4:15 - 4:45 Role of Feynman diagrams in energy band structure of materials - A post density functional theory approach Dr. Sitangshu Bhattacharya
IIIT-Allahabad
4:45 - 5:15 TBA Dr. Swaroop Ganguly
IIT-Bombay
5:15 - 5:45 TBA Dr. Saurabh Lodha
IIT-Bombay
5:45 - 6:15 TBA Dr. Udayan Ganguly
IIT-Bombay
6:15 - 6:45 TBA Dr. Manoj Saxena
Delhi University
6:45 - 7:00 Closing Keynote

Jan 31, 2017

#Memristors, the fourth fundamental circuit element? https://t.co/V03Zp7Oaxw #cad #feedly #papers


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January 31, 2017 at 02:53PM
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[chapter] Near-Threshold Digital Circuits for Nearly-Minimum Energy Processing

Near-Threshold Digital Circuits for Nearly-Minimum Energy Processing
Massimo Alioto
Department of Electrical & Computer Engineering, National University of Singapore
in Enabling the Internet of Things; pp 95-148 
DOI: 10.1007/978-3-319-51482-6_4
This chapter addresses the challenges and the opportunities to perform computation with nearly-minimum energy consumption through the adoption of logic circuits operating at near-threshold voltages. Simple models are provided to gain an insight into the fundamental design tradeoffs. A wide set of design techniques is presented to preserve the nearly-minimum energy feature in spite of the fundamental challenges in terms of performance, leakage and variations. Emphasis is given on debunking the incorrect assumptions that stem from traditional low-power common wisdom at above-threshold voltages. The traditional EKV model is very useful for quick estimates, but it oversimplifies the IV characteristics that is observed in actual nanometer CMOS technologies [read more...]