Friday, August 10th 2018, the IEEE Toronto SSCS/CAS invites you to the IEEE SSCS/CAS Distinguished Lecture Series on: “A 13b ENOB Noise-Shaping SAR ADC with a Two-Capacitor DAC” by Lukang Shi and Gabor C. Temes, and “Noise Filtering and Linearization of Single-Ended Circuits” by Gabor C. Temes et al., School of EECS, Oregon State University.
Date: Friday August 10th, 2018
Organizers: IEEE Toronto SSCS/CAS
Location: Bahen Centre Room BA1210
Lecture 1 (10:10am – 11:00am): A 13b ENOB Noise-Shaping SAR ADC with a Two-Capacitor DAC
Speakers: Lukang Shi and Gabor C. Temes
School of EECS, Oregon State University
Abstract: An active noise-shaping successive-approximation-register (SAR) analog-to-digital converter is described. Instead of binary-weighted capacitors, it uses two equal-valued capacitors as the embedded digital-to-analog converter (DAC). Thus, the capacitance spread in the DAC is much smaller than that of the conventional binary-weighted capacitor array, and the mismatch error can be greatly reduced. The circuit provides first-order noise shaping, which can improve the ADC’s linearity even for a small oversampling ratio. Also, the proposed architecture uses a monotonic approximation procedure, which requires fewer conversion steps than for a conventional SAR ADCs. The ADC was fabricated in 0.18 um CMOS technology. For a 2 kHz signal bandwidth, it achieved a 78.8 dB SNDR. It consumes 74.2 mW power from a 1.5 V power supply. The performance can be drastically improved by introducing noise mitigation schemes and higher-order noise shaping. These topics will also be discussed.
Lecture 2 (11:10am – 12:00pm): Noise Filtering and Linearization of Single-Ended Circuits
Speakers: Gabor C. Temes et al.
School of EECS, Oregon State University
Abstract: The performance of analog integrated circuits is often limited by the noise generated in its components. Several circuit techniques exist for suppressing the effects of the low-frequency noise. In this paper, existing techniques are described for noise mitigation. Also, a novel approach is proposed, which can suppress low-frequency noise. In addition, the new process will also reduce even-order distortion, another major limitation of analog circuits. Finally, it may allow the use of single-ended circuits in applications where usually differential structures are needed.
Biography: Gabor C. Temes received the Ph.D. degree in electrical engineering from the University of Ottawa, ON, Canada, in 1961, and an honorary doctorate from the Technical University of Budapest, Budapest, Hungary, in 1991. He held academic positions at the Technical University of Budapest, Stanford University and the University of California at Los Angeles. He worked in industry at Northern Electric R&D Laboratories and at Ampex Corp. He is now a Professor in the School of Electrical Engineering and Computer Science at Oregon State University.
Dr. Temes received the IEEE Leon K. Kirchmayer Graduate Teaching Award in 1998, and the IEEE Millennium Medal in 2000. He was the 2006 recipient of the IEEE Gustav Robert Kirchhoff Award, and the 2009 IEEE CAS Mac Valkenburg Award. He received the 2017 Semiconductor Industry Association-SRC University Researcher Award. He is a member of the National Academy of Engineering.