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Thomas H. Lee
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2020 – today
- 2024
- [j48]Richelle L. Smith, Thomas H. Lee:
Quantum Computing Gate Emulation Using CMOS Oscillatory Cellular Neural Networks. IEEE Trans. Circuits Syst. II Express Briefs 71(10): 4541-4545 (2024) - 2023
- [j47]Richelle L. Smith, Thomas H. Lee:
Polychronous Oscillatory Cellular Neural Networks for Solving Graph Coloring Problems. IEEE Open J. Circuits Syst. 4: 156-164 (2023) - [j46]Richelle L. Smith, Masum Hossain, Carl W. Werner, Joseph M. Kahn, Thomas H. Lee:
Differential Edge Modulation Signaling for Low-Energy, High-Speed Wireline Communication. IEEE Trans. Circuits Syst. I Regul. Pap. 70(8): 3359-3372 (2023) - 2022
- [j45]Richelle L. Smith, Thomas H. Lee:
Analysis and Design of a Tetrahedral Oscillator. IEEE Trans. Circuits Syst. II Express Briefs 69(1): 75-79 (2022) - [c33]Richelle L. Smith, Thomas H. Lee:
Hybrid Analysis and Simulation Methodology for Noise in Active Mixers. MWSCAS 2022: 1-5 - 2021
- [c32]Richelle L. Smith, Thomas H. Lee:
Modeling of Injection Locking in Neurons for Neuromorphic and Biomedical Systems. ISCAS 2021: 1-5 - [c31]Ramesh Harjani, Mike Chen, Marco Berkhout, Johan H. C. van den Heuvel, Thomas H. Lee, Robert Bogdan Staszewski, Kathleen Philips, Howard C. Luong, Vadim Ivanov:
SE3: Favorite Circuit Design and Testing Mistakes of Starting Engineers. ISSCC 2021: 541-542 - [c30]Richelle L. Smith, Thomas H. Lee:
Hybrid Frequency Domain Simulation Method to Speed-up Analysis of Injection Locked Oscillators. MWSCAS 2021: 722-726 - 2020
- [c29]Ashwin Raghunathan, Thomas H. Lee:
A Simple Linear Time-Variant Theory of Superregeneration. ISCAS 2020: 1-5
2010 – 2019
- 2018
- [c28]Ashwin Raghunathan, Thomas H. Lee:
A 125 pJ/hit 5 mW 28 GHz Superregenerative Receiver with Automatic Gain Control and Energy Efficient Startup for Burst Mode IoE Applications. ESSCIRC 2018: 70-73 - 2015
- [j44]Kanupriya Bhardwaj, Thomas H. Lee:
A Phase-Interpolation and Quadrature-Generation Method Using Parametric Energy Transfer in CMOS. IEEE Trans. Circuits Syst. I Regul. Pap. 62-I(5): 1250-1259 (2015) - 2014
- [c27]Thomas H. Lee:
Terahertz electronics: The last frontier. ESSCIRC 2014: 30-34 - [c26]Thomas H. Lee:
Terahertz electronics: The last frontier. ESSDERC 2014: 30-34 - [c25]Kanupriya Bhardwaj, Thomas H. Lee:
A 0.96mW, 5.3-6.75GHz, phase-interpolation and quadrature-generation method using parametric energy transfer in 65nm CMOS. ISCAS 2014: 2145-2148 - 2013
- [c24]Kanupriya Bhardwaj, Sriram Narayan, Sergey Y. Shumarayev, Thomas H. Lee:
A 3.1mW phase-tunable quadrature-generation method for CEI 28G short-reach CDR in 28nm CMOS. ISSCC 2013: 412-413 - 2010
- [j43]Reza Navid, Thomas H. Lee, Robert W. Dutton:
Circuit-Based Characterization of Device Noise Using Phase Noise Data. IEEE Trans. Circuits Syst. I Regul. Pap. 57-I(6): 1265-1272 (2010)
2000 – 2009
- 2009
- [c23]Ali Kiaei, Mounir Bohsali, Ahmad Bahai, Thomas H. Lee:
A 10Gb/s NRZ receiver with feedforward equalizer and glitch-free phase-frequency detector. ESSCIRC 2009: 372-375 - 2008
- [c22]Igor Loi, Subhasish Mitra, Thomas H. Lee, Shinobu Fujita, Luca Benini:
A low-overhead fault tolerance scheme for TSV-based 3D network on chip links. ICCAD 2008: 598-602 - 2007
- [j42]Shinobu Fujita, Kumiko Nomura, Keiko Abe, Thomas H. Lee:
3-D Nanoarchitectures With Carbon Nanotube Mechanical Switches for Future On-Chip Network Beyond CMOS Architecture. IEEE Trans. Circuits Syst. I Regul. Pap. 54-I(11): 2472-2479 (2007) - [c21]Ali Kiaei, Babak Matinpour, Ahmad Bahai, Thomas H. Lee:
A 10Gb/s Equalizer with Decision Feedback for High Speed Serial Links. CICC 2007: 285-288 - [c20]Moon-Jung Kim, Henrik Icking, Harald Gossner, Thomas H. Lee:
High-Voltage-Tolerant I/O Circuit Design for USB 2.0-Compliant Applications. CICC 2007: 491-494 - [c19]Reza Navid, Thomas H. Lee, Robert W. Dutton:
A Circuit-Based Noise Parameter Extraction Technique for MOSFETs. ISCAS 2007: 3347-3350 - [c18]Michael D. Mulligan, Bill Broach, Thomas H. Lee:
A 3MHz Low-Voltage Buck Converter with Improved Light Load Efficiency. ISSCC 2007: 528-620 - [c17]Wolfgang Soldner, Moon-Jung Kim, Martin Streibl, Harald Gossner, Thomas H. Lee, Doris Schmitt-Landsiedel:
A 10GHz Broadband Amplifier with Bootstrapped 2kV ESD Protection. ISSCC 2007: 550-551 - 2006
- [j41]Donhee Ham, Xiaofeng Li, Scott A. Denenberg, Thomas H. Lee, David S. Ricketts:
Ordered and chaotic electrical solitons: communication perspectives. IEEE Commun. Mag. 44(12): 126-135 (2006) - [j40]Derek K. Shaeffer, Thomas H. Lee:
Comment on Corrections to "A 1.5-V, 1.5-GHz CMOS Low Noise Amplifier". IEEE J. Solid State Circuits 41(10): 2359 (2006) - [c16]Shinobu Fujita, Kumiko Nomura, Keiko Abe, Thomas H. Lee:
3D on-chip networking technology based on post-silicon devices for future networks-on-chip. Nano-Net 2006: 1-5 - 2005
- [j39]Reza Navid, Thomas H. Lee, Robert W. Dutton:
Minimum achievable phase noise of RC oscillators. IEEE J. Solid State Circuits 40(3): 630-637 (2005) - [j38]Derek K. Shaeffer, Thomas H. Lee:
Corrections to "A 1.5-V, 1.5-GHz CMOS Low Noise Amplifier". IEEE J. Solid State Circuits 40(6): 1397-1398 (2005) - [j37]Shwetabh Verma, Junfeng Xu, Mototsugu Hamada, Thomas H. Lee:
A 17-mW 0.66-mm2 direct-conversion receiver for 1-Mb/s cable replacement. IEEE J. Solid State Circuits 40(12): 2547-2554 (2005) - [j36]Reza Navid, Thomas H. Lee, Robert W. Dutton:
An analytical formulation of phase noise of signals with Gaussian-distributed jitter. IEEE Trans. Circuits Syst. II Express Briefs 52-II(3): 149-153 (2005) - 2004
- [j35]Shwetabh Verma, Junfeng Xu, Thomas H. Lee:
A multiply-by-3 coupled-ring oscillator for low-power frequency synthesis. IEEE J. Solid State Circuits 39(4): 709-713 (2004) - [c15]Joel L. Dawson, Thomas H. Lee:
Cartesian feedback for RF power amplifier linearization. ACC 2004: 361-366 - 2003
- [j34]Shwetabh Verma, Hamid R. Rategh, Thomas H. Lee:
A unified model for injection-locked frequency dividers. IEEE J. Solid State Circuits 38(6): 1015-1027 (2003) - [j33]Mark Johnson, Ali Al-Shamma, Derek Bosch, Matthew Crowley, Michael Farmwald, Luca Fasoli, Alper Ilkbahar, Bendik Kleveland, Thomas H. Lee, Tz-Yi Liu, Quang Nguyen, Roy Scheuerlein, Kenneth So, Tyler Thorp:
512-Mb PROM with a three-dimensional array of diode/antifuse memory cells. IEEE J. Solid State Circuits 38(11): 1920-1928 (2003) - [j32]Joel L. Dawson, Thomas H. Lee:
Automatic phase alignment for a fully integrated Cartesian feedback power amplifier system. IEEE J. Solid State Circuits 38(12): 2269-2279 (2003) - [c14]David M. Colleran, Clemenz L. Portmann, Arash Hassibi, César A. R. Crusius, Sunderarajan S. Mohan, Stephen P. Boyd, Thomas H. Lee, Maria del Mar Hershenson:
Optimization of phase-locked loop circuits via geometric programming. CICC 2003: 377-380 - [c13]Reza Navid, Thomas H. Lee, Robert W. Dutton:
Lumped, inductorless oscillators: how far can they go? [phase noise reduction limit]. CICC 2003: 543-546 - 2002
- [j31]Kenneth D. Mandl, Thomas H. Lee:
Viewpoint: Integrating Medical Informatics and Health Services Research: The Need for Dual Training at the Clinical Health Systems and Policy Levels. J. Am. Medical Informatics Assoc. 9(2): 127-132 (2002) - [j30]Jeffrey M. Rothschild, Thomas H. Lee, Taran Bae, David W. Bates:
Research Paper: Clinician Use of a Palmtop Drug Reference Guide. J. Am. Medical Informatics Assoc. 9(3): 223-229 (2002) - [j29]Bendik Kleveland, Carlos H. Diaz, Dieter Vook, Liam Madden, Thomas H. Lee, S. Simon Wong:
Correction to "exploiting CMOS reverse interconnect scaling in multigigahertz amplifier and oscillator design". IEEE J. Solid State Circuits 37(2): 255 (2002) - [j28]Jung-Suk Goo, Hee-Tae Ahn, Donald J. Ladwig, Zhiping Yu, Thomas H. Lee, Robert W. Dutton:
A noise optimization technique for integrated low-noise amplifiers. IEEE J. Solid State Circuits 37(8): 994-1002 (2002) - 2001
- [j27]Min Xu, David K. Su, Derek K. Shaeffer, Thomas H. Lee, Bruce A. Wooley:
Measuring and modeling the effects of substrate noise on the LNA for a CMOS GPS receiver. IEEE J. Solid State Circuits 36(3): 473-485 (2001) - [j26]Bendik Kleveland, Carlos H. Diaz, Dieter Vook, Liam Madden, Thomas H. Lee, S. Simon Wong:
Exploiting CMOS reverse interconnect scaling in multigigahertz amplifier and oscillator design. IEEE J. Solid State Circuits 36(10): 1480-1488 (2001) - [j25]Maria del Mar Hershenson, Stephen P. Boyd, Thomas H. Lee:
Optimal design of a CMOS op-amp via geometric programming. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 20(1): 1-21 (2001) - 2000
- [j24]HongMo Wang, Ali Hajimiri, Thomas H. Lee:
Comments on "Design issues in CMOS differential LC oscillators" [and reply]. IEEE J. Solid State Circuits 35(2): 286-287 (2000) - [j23]Thomas H. Lee, Ali Hajimiri:
Oscillator phase noise: a tutorial. IEEE J. Solid State Circuits 35(3): 326-336 (2000) - [j22]Sunderarajan S. Mohan, Maria del Mar Hershenson, Stephen P. Boyd, Thomas H. Lee:
Bandwidth extension in CMOS with optimized on-chip inductors. IEEE J. Solid State Circuits 35(3): 346-355 (2000) - [j21]Ramin Farjad-Rad, Chih-Kong Ken Yang, Mark A. Horowitz, Thomas H. Lee:
A 0.3-μm CMOS 8-Gb/s 4-PAM serial link transceiver. IEEE J. Solid State Circuits 35(5): 757-764 (2000) - [j20]Hirad Samavati, Hamid R. Rategh, Thomas H. Lee:
A 5-GHz CMOS wireless LAN receiver front end. IEEE J. Solid State Circuits 35(5): 765-772 (2000) - [j19]Hamid R. Rategh, Hirad Samavati, Thomas H. Lee:
A CMOS frequency synthesizer with an injection-locked frequency divider for a 5-GHz wireless LAN receiver. IEEE J. Solid State Circuits 35(5): 780-787 (2000) - [j18]Thomas H. Lee, Simon S. Wong:
CMOS RF integrated circuits at 5 GHz and beyond. Proc. IEEE 88(10): 1560-1571 (2000) - [c12]Jeffrey M. Rothschild, Thomas H. Lee, Taran Bae, Rena Yamamoto, Jan Horsky, David W. Bates:
Survey of Physicians' Experience Using a Handheld Drug Reference Guide. AMIA 2000 - [c11]Min Xu, David K. Su, Derek K. Shaeffer, Thomas H. Lee, Bruce A. Wooley:
Measuring and modeling the effects of substrate noise on the LNA for a CMOS GPS receiver. CICC 2000: 353-356
1990 – 1999
- 1999
- [j17]Ramin Farjad-Rad, Chih-Kong Ken Yang, Mark A. Horowitz, Thomas H. Lee:
A 0.4-μm CMOS 10-Gb/s 4-PAM pre-emphasis serial link transmitter. IEEE J. Solid State Circuits 34(5): 580-585 (1999) - [j16]Bruno W. Garlepp, Kevin S. Donnelly, Jun Kim, Pak Shing Chau, Jared L. Zerbe, Charlie Huang, Chanh Tran, Clemenz L. Portmann, Donald Stark, Yiu-Fai Chan, Thomas H. Lee, Mark A. Horowitz:
A portable digital DLL for high-speed CMOS interface circuits. IEEE J. Solid State Circuits 34(5): 632-644 (1999) - [j15]Ali Hajimiri, Thomas H. Lee:
Design issues in CMOS differential LC oscillators. IEEE J. Solid State Circuits 34(5): 717-724 (1999) - [j14]Ali Hajimiri, Sotirios Limotyrakis, Thomas H. Lee:
Jitter and phase noise in ring oscillators. IEEE J. Solid State Circuits 34(6): 790-804 (1999) - [j13]Hamid R. Rategh, Thomas H. Lee:
Superharmonic injection-locked frequency dividers. IEEE J. Solid State Circuits 34(6): 813-821 (1999) - [j12]Sunderarajan S. Mohan, Maria del Mar Hershenson, Stephen P. Boyd, Thomas H. Lee:
Simple accurate expressions for planar spiral inductances. IEEE J. Solid State Circuits 34(10): 1419-1424 (1999) - [c10]Thomas H. Lee:
Oscillator phase noise: a tutorial. CICC 1999: 373-380 - [c9]Sunderarajan S. Mohan, Thomas H. Lee:
A 2.125 Gbaud 1.6 kΩ transimpedance preamplifier in 0.5 μm CMOS. CICC 1999: 513-516 - [c8]Hamid R. Rategh, Hirad Samavati, Thomas H. Lee:
A 5 GHz, 1 mW CMOS voltage controlled differential injection locked frequency divider. CICC 1999: 517-520 - [c7]Maria del Mar Hershenson, Sunderarajan S. Mohan, Stephen P. Boyd, Thomas H. Lee:
Optimization of Inductor Circuits via Geometric Programming. DAC 1999: 994-998 - [c6]Maria del Mar Hershenson, Ali Hajimiri, Sunderarajan S. Mohan, Stephen P. Boyd, Thomas H. Lee:
Design and optimization of LC oscillators. ICCAD 1999: 65-69 - [r1]Thomas H. Lee, Maria del Mar Hershenson, Sunderarajan S. Mohan, Kirad Samavati, C. Patrick Yue:
RF Passive IC Components. The VLSI Handbook 1999 - 1998
- [j11]Ali Hajimiri, Thomas H. Lee:
A general theory of phase noise in electrical oscillators. IEEE J. Solid State Circuits 33(2): 179-194 (1998) - [j10]Ali Hajimiri, Thomas H. Lee:
Corrections to "A General Theory of Phase Noise in Electrical Oscillators". IEEE J. Solid State Circuits 33(6): 928 (1998) - [j9]Hirad Samavati, Ali Hajimiri, Arvin R. Shahani, Gitty N. Nasserbakht, Thomas H. Lee:
Fractal capacitors. IEEE J. Solid State Circuits 33(12): 2035-2041 (1998) - [j8]Derek K. Shaeffer, Arvin Shahani, Sunderarajan S. Mohan, Hirad Samavati, Hamid R. Rategh, Maria del Mar Hershenson, Min Xu, C. Patrick Yue, Daniel J. Eddleman, Thomas H. Lee:
A 115-mW, 0.5-μm CMOS GPS receiver with wide dynamic-range active filters. IEEE J. Solid State Circuits 33(12): 2219-2231 (1998) - [j7]Arvin Shahani, Derek K. Shaeffer, Sunderarajan S. Mohan, Hirad Samavati, Hamid R. Rategh, Maria del Mar Hershenson, Min Xu, C. Patrick Yue, Daniel J. Eddleman, Mark A. Horowitz, Thomas H. Lee:
Low-power dividerless frequency synthesis using aperture phase detection. IEEE J. Solid State Circuits 33(12): 2232-2239 (1998) - [c5]Ali Hajimiri, Sotirios Limotyrakis, Thomas H. Lee:
Phase noise in multi-gigahertz CMOS ring oscillators. CICC 1998: 49-52 - [c4]Maria del Mar Hershenson, Stephen P. Boyd, Thomas H. Lee:
GPCAD: a tool for CMOS op-amp synthesis. ICCAD 1998: 296-303 - [c3]Maria del Mar Hershenson, Stephen P. Boyd, Thomas H. Lee:
Automated design of folded-cascode op-amps with sensitivity analysis. ICECS 1998: 121-124 - [c2]Tamara I. Ahrens, Thomas H. Lee:
A 1.4-GHz 3-mW CMOS LC low phase noise VCO using tapped bond wire inductances. ISLPED 1998: 16-19 - [c1]Rafael J. Betancourt-Zamora, Thomas H. Lee:
CMOS VCOs for frequency synthesis in wireless biotelemetry. ISLPED 1998: 91-94 - 1997
- [j6]James Montanaro, Richard T. Witek, Krishna Anne, Andrew J. Black, Elizabeth M. Cooper, Daniel W. Dobberpuhl, Paul M. Donahue, Jim Eno, Gregory W. Hoeppner, David Kruckemyer, Thomas H. Lee, Peter C. M. Lin, Liam Madden, Daniel Murray, Mark H. Pearce, Sribalan Santhanam, Kathryn J. Snyder, Ray Stephany, Stephen C. Thierauf:
A 160-MHz, 32-b, 0.5-W CMOS RISC Microprocessor. Digit. Tech. J. 9(1) (1997) - [j5]Derek K. Shaeffer, Thomas H. Lee:
A 1.5-V, 1.5-GHz CMOS low noise amplifier. IEEE J. Solid State Circuits 32(5): 745-759 (1997) - [j4]Don Draper, Matt Crowley, John Holst, Greg Favor, Albrecht Schoy, Jeff Trull, Amos Ben-Meir, Rajesh Khanna, Dennis Wendell, Ravi Krishna, Joe Nolan, Dhiraj Mallick, Hamid Partovi, Mark Roberts, Mark Johnson, Thomas H. Lee:
Circuit techniques in a 266-MHz MMX-enabled processor. IEEE J. Solid State Circuits 32(11): 1650-1664 (1997) - [j3]Arvin Shahani, Derek K. Shaeffer, Thomas H. Lee:
A 12-mW wide dynamic range CMOS front-end for a portable GPS receiver. IEEE J. Solid State Circuits 32(11): 2061-2070 (1997) - 1996
- [j2]James Montanaro, Richard T. Witek, Krishna Anne, Andrew J. Black, Elizabeth M. Cooper, Daniel W. Dobberpuhl, Paul M. Donahue, Jim Eno, Gregory W. Hoeppner, David Kruckemyer, Thomas H. Lee, Peter C. M. Lin, Liam Madden, Daniel Murray, Mark H. Pearce, Sribalan Santhanam, Kathryn J. Snyder, Ray Stephany, Stephen C. Thierauf:
A 160-MHz, 32-b, 0.5-W CMOS RISC microprocessor. IEEE J. Solid State Circuits 31(11): 1703-1714 (1996) - 1994
- [j1]Thomas H. Lee, Kevin S. Donnelly, John T. C. Ho, Jared Zerbe, Mark Johnson, Tom Ishikawa:
A 2.5 V CMOS delay-locked loop for 18 Mbit, 500 megabyte/s DRAM. IEEE J. Solid State Circuits 29(12): 1491-1496 (1994)
Coauthor Index
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last updated on 2024-10-23 21:28 CEST by the dblp team
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