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Jeremy Holleman
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- affiliation: University of Tennessee, Knoxville, USA
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2020 – today
- 2024
- [i4]Arya Tschand, Arun Tejusve Raghunath Rajan, Sachin Idgunji, Anirban Ghosh, Jeremy Holleman, Csaba Király, Pawan Ambalkar, Ritika Borkar, Ramesh Chukka, Trevor Cockrell, Oliver Curtis, Grigori Fursin, Miro Hodak, Hiwot Kassa, Anton Lokhmotov, Dejan Miskovic, Yuechao Pan, Manu Prasad Manmathan, Liz Raymond, Tom St. John, Arjun Suresh, Rowan Taubitz, Sean Zhan, Scott Wasson, David Kanter, Vijay Janapa Reddi:
MLPerf Power: Benchmarking the Energy Efficiency of Machine Learning Systems from Microwatts to Megawatts for Sustainable AI. CoRR abs/2410.12032 (2024) - 2023
- [j10]Md. Munir Hasan
, Jeremy Holleman:
Fast Simulation of Analog Spiking Neural Network With Device Non-Idealites. IEEE Trans. Circuits Syst. II Express Briefs 70(9): 3574-3578 (2023) - [c31]David Garrett, Youn Sung Park, Seongjong Kim, Jay Sharma, Wenbin Huang, Majid Shaghaghi, Vinay Parthasarathy, Stephen Gibellini, Stephen Bailey, Mallik Moturi, Pieter Vorenkamp, Kurt Busch, Jeremy Holleman, Behrooz Javid, Alireza Yousefi, Mohsen Judy, Atul Gupta:
A 1mW Always-on Computer Vision Deep Learning Neural Decision Processor. ISSCC 2023: 158-159 - 2021
- [c30]Md. Munir Hasan, Jeremy Holleman:
Hardware Model Based Simulation of Spiking Neuron Using Phase Plane. ISCAS 2021: 1-5 - [c29]Colby R. Banbury, Vijay Janapa Reddi, Peter Torelli, Nat Jeffries, Csaba Király, Jeremy Holleman, Pietro Montino, David Kanter, Pete Warden, Danilo Pau, Urmish Thakker, Antonio Torrini, Jay Cordaro, Giuseppe Di Guglielmo, Javier M. Duarte, Honson Tran, Nhan Tran, Wenxu Niu, Xuesong Xu:
MLPerf Tiny Benchmark. NeurIPS Datasets and Benchmarks 2021 - [i3]Md. Munir Hasan, Jeremy Holleman:
Training Neural Networks Using the Property of Negative Feedback to Inverse a Function. CoRR abs/2103.14115 (2021) - [i2]Colby R. Banbury, Vijay Janapa Reddi, Peter Torelli, Jeremy Holleman, Nat Jeffries, Csaba Király, Pietro Montino, David Kanter, Sebastian Ahmed, Danilo Pau, Urmish Thakker, Antonio Torrini, Pete Warden, Jay Cordaro, Giuseppe Di Guglielmo, Javier M. Duarte, Stephen Gibellini, Videet Parekh, Honson Tran, Nhan Tran, Wenxu Niu, Xuesong Xu:
MLPerf Tiny Benchmark. CoRR abs/2106.07597 (2021) - 2020
- [c28]Md. Munir Hasan, Jeremy Holleman:
Low Power Compact Analog Spiking Neuron Circuit Using Exponential Positive Feedback With Adaptation and Bursting Capability. MWSCAS 2020: 452-455 - [c27]Md. Munir Hasan, Jeremy Holleman:
Leakage Current Compensation in Large Number of Inactive Synapses in a 130nm CMOS Process. MWSCAS 2020: 460-463 - [c26]Md. Munir Hasan, Jeremy Holleman:
Spiking Sparse Coding Algorithm with Reduced Inhibitory Feedback Weights. MWSCAS 2020: 1040-1043 - [i1]Colby R. Banbury, Vijay Janapa Reddi, Max Lam, William Fu, Amin Fazel, Jeremy Holleman, Xinyuan Huang, Robert Hurtado, David Kanter, Anton Lokhmotov, David A. Patterson, Danilo Pau, Jae-sun Seo, Jeff Sieracki, Urmish Thakker, Marian Verhelst, Poonam Yadav:
Benchmarking TinyML Systems: Challenges and Direction. CoRR abs/2003.04821 (2020)
2010 – 2019
- 2018
- [j9]Mohsen Judy
A Digitally Interfaced Analog Correlation Filter System for Object Tracking Applications. IEEE Trans. Circuits Syst. I Regul. Pap. 65-I(9): 2764-2773 (2018) - [c25]David A. Basford, Mohsen Judy, Peixing Liu, Jeremy Holleman:
A Sub-1V-Read Flash Memory in a Standard 130nm CMOS Process. ISCAS 2018: 1-4 - [c24]Md. Munir Hasan, Jeremy Holleman:
Implementation of Linear Discriminant Classifier in 130nm Silicon Process. ISCAS 2018: 1-5 - 2017
- [c23]David S. Bolme, Aravind K. Mikkilineni, Derek C. Rose, Srikanth B. Yoginath
Deep modeling: Circuit characterization using theory based models in a data driven framework. ISCAS 2017: 1-4 - [c22]Mohsen Judy, Jeremy Holleman:
A fast convergent and energy efficient offset calibration technique for dynamic comparators. MWSCAS 2017: 551-554 - 2016
- [c21]Jeremy Holleman:
Design considerations for neural amplifiers. EMBC 2016: 6331-6334 - [c20]David A. Basford, Jared M. Smith
The impact of analog computational error on an analog boolean satisfiability solver. ISCAS 2016: 2503-2506 - 2015
- [j8]Junjie Lu
A 1 TOPS/W Analog Deep Machine-Learning Engine With Floating-Gate Storage in 0.13 µm CMOS. IEEE J. Solid State Circuits 50(1): 270-281 (2015) - [j7]Tan Yang, Jeremy Holleman:
An Ultralow-Power Low-Noise CMOS Biopotential Amplifier for Neural Recording. IEEE Trans. Circuits Syst. II Express Briefs 62-II(10): 927-931 (2015) - [c19]Jeremy Holleman, Itamar Arel, Steven R. Young
Analog inference circuits for deep learning. BioCAS 2015: 1-4 - [c18]Tan Yang, Junjie Lu, M. Shahriar Jahan, Kelly Griffin, Jeremy Langford, Jeremy Holleman:
A configurable 5.9 μW analog front-end for biosignal acquisition. CICC 2015: 1-4 - [c17]M. Shahriar Jahan, Tan Yang, Junjie Lu, Jeremy Holleman:
A 167 μW 915 MHz gain-boosted LC VCO. ISCAS 2015: 882-885 - 2014
- [j6]Steven R. Young
On the Impact of Approximate Computation in an Analog DeSTIN Architecture. IEEE Trans. Neural Networks Learn. Syst. 25(5): 934-946 (2014) - [c16]Junjie Lu, Steven R. Young, Itamar Arel, Jeremy Holleman:
30.10 A 1TOPS/W analog deep machine-learning engine with floating-gate storage in 0.13μm CMOS. ISSCC 2014: 504-505 - [c15]Junjie Lu, Tan Yang, M. Shahriar Jahan, Jeremy Holleman:
A low-power 84-dB dynamic-range tunable Gm-C filter for bio-signal acquisition. MWSCAS 2014: 1029-1032 - [c14]Tan Yang, Junjie Lu, Nicholas Poore, Jeremy Holleman:
A current-reuse complementary-input chopper-stabilized amplifier for neural recording. NEWCAS 2014: 85-88 - 2013
- [j5]Junjie Lu, Jeremy Holleman:
A Low-Power High-Precision Comparator With Time-Domain Bulk-Tuned Offset Cancellation. IEEE Trans. Circuits Syst. I Regul. Pap. 60-I(5): 1158-1167 (2013) - [c13]Junjie Lu, Jeremy Holleman:
A floating-gate analog memory with bidirectional sigmoid updates in a standard digital process. ISCAS 2013: 1600-1603 - [c12]Tan Yang, Junjie Lu, Jeremy Holleman:
A high input impedance low-noise instrumentaion amplifier with JFET input. MWSCAS 2013: 173-176 - 2012
- [j4]Fan Zhang, Jeremy Holleman, Brian P. Otis:
Design of Ultra-Low Power Biopotential Amplifiers for Biosignal Acquisition Applications. IEEE Trans. Biomed. Circuits Syst. 6(4): 344-355 (2012) - [c11]Junjie Lu, Jeremy Holleman:
A wideband ultra-low-current on-chip ammeter. CICC 2012: 1-4 - [c10]M. Shahriar Jahan, Jeremy H. Holleman:
A 3.3 µW dual-modulus frequency divider with 189% locking range for MICS band applications. ISCAS 2012: 1504-1507 - [c9]Xiaojun Tu, Jeremy H. Holleman:
An ultra-low-power 902-928MHz RF receiver front-end in CMOS 90nm process. ISCAS 2012: 2199-2202 - [c8]Junjie Lu, Jeremy Holleman:
A low-power dynamic comparator with time-domain bulk-driven offset cancellation. ISCAS 2012: 2493-2496 - [c7]Chandradevi Ulaganathan, Benjamin J. Blalock, Jeremy Holleman, Charles L. Britton Jr.:
An ultra-low voltage self-startup charge pump for energy harvesting applications. MWSCAS 2012: 206-209
2000 – 2009
- 2009
- [j3]Daniel J. Yeager, Jeremy Holleman, Richa Prasad, Joshua R. Smith, Brian P. Otis:
NeuralWISP: A Wirelessly Powered Neural Interface With 1-m Range. IEEE Trans. Biomed. Circuits Syst. 3(6): 379-387 (2009) - [c6]Brian P. Otis, Robert G. Egbert
Design Techniques for Self-powered Microsystems. ISCAS 2009: 1429-1432 - [c5]Shailesh Rai, Jeremy Holleman, Jagdish Nayayan Pandey, Fan Zhang, Brian P. Otis:
A 500µW neural tag with 2µVrms AFE and frequency-multiplying MICS/ISM FSK transmitter. ISSCC 2009: 212-213 - 2008
- [j2]Ying Su, Jeremy Holleman, Brian P. Otis:
A Digital 1.6 pJ/bit Chip Identification Circuit Using Process Variations. IEEE J. Solid State Circuits 43(1): 69-77 (2008) - [j1]Jeremy Holleman, Seth Bridges, Brian P. Otis, Chris Diorio:
A 3 µW CMOS True Random Number Generator With Adaptive Floating-Gate Offset Cancellation. IEEE J. Solid State Circuits 43(5): 1324-1336 (2008) - [c4]Jeremy Holleman, Apurva Mishra, Chris Diorio, Brian P. Otis:
A micro-power neural spike detector and feature extractor in .13μm CMOS. CICC 2008: 333-336 - 2007
- [c3]Jeremy Holleman, Brian P. Otis, Chris Diorio:
A compact pulse-based charge pump in 0.13 μm CMOS. CICC 2007: 381-384 - [c2]Ying Su, Jeremy Holleman, Brian P. Otis:
A 1.6pJ/bit 96% Stable Chip-ID Generating Circuit using Process Variations. ISSCC 2007: 406-611
1990 – 1999
- 1997
- [c1]Girish N. Patel, Jeremy H. Holleman, Stephen P. DeWeerth:
Analog VLSI Model of Intersegmental Coordination with Nearest-Neighbor Coupling. NIPS 1997: 719-725
Coauthor Index
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last updated on 2024-11-27 20:27 CET by the dblp team
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