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2020 – today
- 2024
[j51]Carl D'heer
, Patrick Reynaert:
A Fully Integrated 135-GHz Direct-Digital 16-QAM Wireless and Dielectric Waveguide Link in 28-nm CMOS. IEEE J. Solid State Circuits 59(3): 889-907 (2024)- [j50]Kristof Dens, Joren Vaes, Christian Blümm, Gabriel Guimaraes, Berke Gungor, Changsong Xie, Alexander Dyck, Patrick Reynaert:
Design of a Noncoherent 100-Gb/s 3-m Dual-Band PAM-4 Dielectric Waveguide Link in 28-nm CMOS. IEEE J. Solid State Circuits 59(5): 1398-1408 (2024) - 2023
- [b1]Bart Philippe, Patrick Reynaert:
Mm-wave Circuit Design in 16nm FinFET for 6G Applications. Springer 2023, ISBN 978-3-031-11223-2, pp. 1-133 - [j49]Yiyang Wang, Haipeng Duan, Long He, Depeng Cheng, Xu Wu, Dongming Wang, Patrick Reynaert, Lianming Li:
A 39-GHz High Image-Rejection Up-Conversion Mixer in 65-nm CMOS for 5G Communication. IEEE Trans. Circuits Syst. II Express Briefs 70(2): 491-495 (2023) - [c72]Senne Gielen, Yang Zhang, Mark Ingels, Patrick Reynaert:
A Compact 0.98 THz Source With On-Chip Antenna In 250-nm InP DHBT. BCICTS 2023: 86-89 - [c71]Ariane De Vroede, Patrick Reynaert:
A $4\times 4$ 607GHz Harmonic Injection-Locked Receiver Array Achieving $4.4\text{pW}/\surd\text{Hz}$ NEP in 28nm CMOS. ISSCC 2023: 288-289 - [c70]Bharat Kalyan Thota, Patrick Reynaert:
Low-Loss Tunable-Phase Transmission Line Couplers -A Comparative Study. PRIME 2023: 337-340 - 2022
- [j48]Kaizhe Guo, Patrick Reynaert:
Analysis and Design of Fourth Harmonic Boosting Technique for THz Signal Generation. IEEE Trans. Circuits Syst. I Regul. Pap. 69(6): 2311-2324 (2022) - [j47]Ariane De Vroede, Patrick Reynaert:
Analysis and Implementation of Harmonic Injection Locking in Cross-Coupled Oscillators Exploiting Inter-Harmonic Translations. IEEE Trans. Circuits Syst. I Regul. Pap. 69(8): 3136-3149 (2022) - [c69]Gabriel Guimaraes, Patrick Reynaert:
A D-Band mm-wave spectroscopy TX and RX in 28 nm CMOS with 15.6 dBm EIRP and 17.1 dB NF with integrated antennas. ESSCIRC 2022: 457-460 - [c68]Carl D'heer, Patrick Reynaert:
A 135 GHz 32 Gb/s Direct-Digital Modulation 16-QAM Transmitter in 28 nm CMOS. ESSCIRC 2022: 481-484 - [c67]Carl D'heer, Patrick Reynaert:
A 135 GHz 24 Gb/s Direct-Digital Demodulation 16-QAM Receiver in 28 nm CMOS. ESSCIRC 2022: 485-488 - [c66]Ibrahim Kazi, Patrick Reynaert, Wim Dehaene:
Clock Recovery Circuit Using a Transmission Line as a Delay Element from a 100Gb/s bit stream. NEWCAS 2022: 261-264 - 2021
- [j46]Umut Çelik, Patrick Reynaert:
Robust, Efficient Distributed Power Amplifier Achieving 96 Gbit/s With 10 dBm Average Output Power and 3.7% PAE in 22-nm FD-SOI. IEEE J. Solid State Circuits 56(2): 382-391 (2021) - [j45]Gabriel Guimarães, Patrick Reynaert:
A 670-GHz 4 × 2 Oscillator-Radiator Array Achieving 7.4-dBm EIRP in 40-nm CMOS. IEEE J. Solid State Circuits 56(11): 3399-3411 (2021) - [j44]Valdrin Qunaj, Patrick Reynaert:
A Ka-Band Doherty-Like LMBA for High-Speed Wireless Communication in 28-nm CMOS. IEEE J. Solid State Circuits 56(12): 3694-3703 (2021) - [j43]Dragan Simic, Kaizhe Guo, Patrick Reynaert:
A 420-GHz Sub-5-μm Range Resolution TX-RX Phase Imaging System in 40-nm CMOS Technology. IEEE J. Solid State Circuits 56(12): 3827-3839 (2021) - [j42]Dragan Simic, Patrick Reynaert:
Analysis and Design of Lossy Capacitive Over-Neutralization Technique for Amplifiers Operating Near fMAX. IEEE Trans. Circuits Syst. I Regul. Pap. 68(5): 1945-1955 (2021) - [c65]Kristof Dens, Joren Vaes, Simon Ooms, Martin Wagner, Patrick Reynaert:
A PAM4 Dielectric Waveguide Link in 28 nm CMOS. ESSCIRC 2021: 479-482 - [c64]Dragan Simic, Kaizhe Guo, Patrick Reynaert:
22.3 A 0.42THz Coherent TX-RX System Achieving 10dBm EIRP and 27dB NF in 40nm CMOS for Phase-Contrast Imaging. ISSCC 2021: 318-320 - [c63]Swaminathan Sankaran, Patrick Reynaert, Shuhei Amakawa:
Session 23 Overview: THz Circuits and Front-Ends Rf Subcommittee. ISSCC 2021: 322-323 - [c62]Ariane De Vroede, Patrick Reynaert:
23.3 A 605GHz 0.84mW Harmonic Injection-Locked Receiver Achieving 2.3pW/√Hz NEP in 28nm CMOS. ISSCC 2021: 328-330 - [c61]Valdrin Qunaj, Patrick Reynaert:
26.2 A Doherty-Like Load-Modulated Balanced Power Amplifier Achieving 15.5dBm Average Pout and 20% Average PAE at a Data Rate of 18Gb/s in 28nm CMOS. ISSCC 2021: 356-358 - 2020
- [j41]Rui Xu, Steven Shichang Gao, Benito Sanz-Izquierdo, Chao Gu, Patrick Reynaert, Alexander Standaert, Gregory J. Gibbons, Wolfgang Bösch, Michael Ernst Gadringer, Dong Li:
A Review of Broadband Low-Cost and High-Gain Low-Terahertz Antennas for Wireless Communications Applications. IEEE Access 8: 57615-57629 (2020) - [j40]Anshuman Shastri, Benito Sanz-Izquierdo, Edward A. Parker, Steven Shichang Gao, Patrick Reynaert, Zhijiao Chen, Lee Winchester:
3D Printing of Millimetre Wave and Low-Terahertz Frequency Selective Surfaces Using Aerosol Jet Technology. IEEE Access 8: 177341-177350 (2020) - [j39]Lucien J. Breems, Patrick Reynaert, Sylvain Clerc:
Guest Editorial Special Section on the 45th IEEE European Solid-State Circuits Conference (ESSCIRC). IEEE J. Solid State Circuits 55(7): 1747-1748 (2020) - [j38]Alexander Standaert, Patrick Reynaert:
A 390-GHz Outphasing Transmitter in 28-nm CMOS. IEEE J. Solid State Circuits 55(10): 2703-2713 (2020) - [c60]Bart Philippe, Patrick Reynaert:
24.7 A 15dBm 12.8%-PAE Compact D-Band Power Amplifier with Two-Way Power Combining in 16nm FinFET CMOS. ISSCC 2020: 374-376 - [c59]Kaizhe Guo, Patrick Reynaert:
29.2 A 0.59THz Beam-Steerable Coherent Radiator Array with 1mW Radiated Power and 24.1dBm EIRP in 40nm CMOS. ISSCC 2020: 442-444 - [c58]Gabriel Guimaraes, Patrick Reynaert:
29.6 A 660-to-676GHz 4×2 Oscillator-Radiator Array with Intrinsic Frequency-Filtering Feedback for Harmonic Power Boost Achieving 7.4dBm EIRP in 40nm CMOS. ISSCC 2020: 450-452 - [c57]Simon Ooms, Patrick Reynaert:
Stability Analysis of Parasitic Coupling Between on-Chip Antenna and mm-Wave Front-End. RWS 2020: 275-278
2010 – 2019
- 2019
- [j37]Kaizhe Guo, Yang Zhang, Patrick Reynaert:
A 0.53-THz Subharmonic Injection-Locked Phased Array With 63-µW Radiated Power in 40-nm CMOS. IEEE J. Solid State Circuits 54(2): 380-391 (2019) - [j36]Maxime De Wit, Yang Zhang, Patrick Reynaert:
Analysis and Design of a Foam-Cladded PMF Link With Phase Tuning in 28-nm CMOS. IEEE J. Solid State Circuits 54(7): 1960-1969 (2019) - [c56]Alexander Standaert, Patrick Reynaert:
A Packaged Fully Digital 390GHz Harmonic Outphasing Transmitter in 28nm CMOS. A-SSCC 2019: 149-152 - [c55]Valdrin Qunaj, Patrick Reynaert:
A Compact Ka-Band Transformer-Coupled Power Amplifier for 5G in 0.15um GaAs. BCICTS 2019: 1-4 - [c54]Ariane De Vroede, Simon Ooms, Bart Philippe, Patrick Reynaert:
A 94 GHz Voltage-Boosted Energy Harvester in 45 nm CMOS Achieving a Peak Efficiency of 21.2% at -8.5 dBm Input Power. EUROCON 2019: 1-6 - [c53]Patrick Reynaert, Kristof Dens, Carl D'heer, Dragan Simic, Joren Vaes, Bart Philippe, Simon Ooms:
Polymer Microwave Fiber: a New Communication Concept That Blends Wireless, Wireline and Optical Communication. ICECS 2019: 755-758 - 2018
- [j35]Marco Vigilante, Patrick Reynaert:
A Wideband Class-AB Power Amplifier With 29-57-GHz AM-PM Compensation in 0.9-V 28-nm Bulk CMOS. IEEE J. Solid State Circuits 53(5): 1288-1301 (2018) - [j34]Niels Van Thienen, Yang Zhang, Patrick Reynaert:
Bidirectional Communication Circuits for a 120-GHz PMF Data Link in 40-nm CMOS. IEEE J. Solid State Circuits 53(7): 2023-2031 (2018) - [j33]Marco Vigilante, Patrick Reynaert:
A Coupled-RTWO-Based Subharmonic Receiver Front End for 5G E-Band Backhaul Links in 28-nm Bulk CMOS. IEEE J. Solid State Circuits 53(10): 2927-2938 (2018) - [c52]Bart Philippe, Patrick Reynaert:
A Quadrature Phase Detector in 28nm CMOS for Differential mm-Wave Sensing Applications Using Dielectric Waveguides. ESSCIRC 2018: 114-117 - [c51]Yang Zhang, Maxime De Wit, Patrick Reynaert:
A D-band Foam-Cladded Dielectric Waveguide Communication Link with Automatic Tuning. ESSCIRC 2018: 234-237 - [c50]Jan Cools, Thibaut Gurne, Patrick Reynaert:
A Broadband 13 Vpp 40% PAE Stacked Line Driver in 28 nm Bulk CMOS. ICECS 2018: 445-448 - [c49]Marco Vigilante, Patrick Reynaert:
A coupled-RTWO-based subharmonic receiver front-end for 5G E-Band backhaul links in 28nm bulk CMOS. ISSCC 2018: 412-414 - [c48]Valdrin Qunaj, Umut Çelik, Patrick Reynaert:
An Integrated Power Detector for a 5GHz RF PA. PRIME 2018: 141-144 - 2017
- [j32]Marco Vigilante, Patrick Reynaert:
On the Design of Wideband Transformer-Based Fourth Order Matching Networks for E-Band Receivers in 28-nm CMOS. IEEE J. Solid State Circuits 52(8): 2071-2082 (2017) - [j31]Bram Faes, Patrick Reynaert, Paul Leroux:
Highly Tunable Triangular Wave UWB Baseband Pulse Generator With Amplitude Stabilization in 40-nm CMOS. IEEE Trans. Circuits Syst. II Express Briefs 64-II(5): 505-509 (2017) - [c47]Niels Van Thienen, Patrick Reynaert:
A 120GHz in-band full-duplex PMF transceiver with tunable electrical-balance duplexer in 40nm CMOS. ESSCIRC 2017: 103-106 - [c46]Thibaut Gurne, Maarten Strackx, Maarten Tytgat, Jan Cools, Patrick Reynaert:
A 20Gbps 1.2GHz full-duplex integrated AFE in 28nm CMOS for copper access. ESSCIRC 2017: 107-110 - 2016
- [j30]Niels Van Thienen, Wouter Volkaerts, Patrick Reynaert:
A Multi-Gigabit CPFSK Polymer Microwave Fiber Communication Link in 40 nm CMOS. IEEE J. Solid State Circuits 51(8): 1952-1958 (2016) - [c45]Patrick Reynaert, Maarten Tytgat, Wouter Volkaerts, Alexander Standaert, Yang Zhang, Maxime De Wit, Niels Van Thienen:
Polymer Microwave Fibers: A blend of RF, copper and optical communication. ESSCIRC 2016: 15-20 - [c44]Jan Cools, Patrick Reynaert:
A 40nm bulk CMOS line driver for broadband communication. ESSCIRC 2016: 273-276 - [c43]Niels Van Thienen, Yang Zhang, Maxime De Wit, Patrick Reynaert:
An 18Gbps polymer microwave fiber (PMF) communication link in 40nm CMOS. ESSCIRC 2016: 483-486 - [c42]Marco Vigilante, Patrick Reynaert:
20.10 A 68.1-to-96.4GHz variable-gain low-noise amplifier in 28nm CMOS. ISSCC 2016: 360-362 - [c41]Arnout Devos, Marco Vigilante, Patrick Reynaert:
Multiphase digitally controlled oscillator for future 5G phased arrays in 90 nm CMOS. NORCAS 2016: 1-4 - 2015
- [j29]Brecht François, Patrick Reynaert:
A Fully Integrated Transformer-Coupled Power Detector With 5 GHz RF PA for WLAN 802.11ac in 40 nm CMOS. IEEE J. Solid State Circuits 50(5): 1237-1250 (2015) - [j28]Paramartha Indirayanti, Tuba Ayhan, Marian Verhelst, Wim Dehaene, Patrick Reynaert:
A mm-Precise 60 GHz Transmitter in 40 nm CMOS for Discrete-Carrier Indoor Localization. IEEE J. Solid State Circuits 50(7): 1604-1617 (2015) - [j27]Ercan Kaymaksut, Patrick Reynaert:
Dual-Mode CMOS Doherty LTE Power Amplifier With Symmetric Hybrid Transformer. IEEE J. Solid State Circuits 50(9): 1974-1987 (2015) - [j26]Dixian Zhao, Patrick Reynaert:
A 40 nm CMOS E-Band Transmitter With Compact and Symmetrical Layout Floor-Plans. IEEE J. Solid State Circuits 50(11): 2560-2571 (2015) - [j25]Maarten Strackx, Emiliano D'Agostino, Paul Leroux, Patrick Reynaert:
Direct RF Subsampling Receivers Enabling Impulse-Based UWB Signals for Breast Cancer Detection. IEEE Trans. Circuits Syst. II Express Briefs 62-II(2): 144-148 (2015) - [c40]Wouter Steyaert, Patrick Reynaert:
A THz signal source with integrated antenna for non-destructive testing in 28nm bulk CMOS. A-SSCC 2015: 1-4 - [c39]Marco Vigilante, Patrick Reynaert:
A 25-102GHz 2.81-5.64mW tunable divide-by-4 in 28nm CMOS. A-SSCC 2015: 1-4 - [c38]Shailesh Kulkarni, Ibrahim Kazi, David Seebacher, Peter Singerl, Franz Dielacher, Wim Dehaene, Patrick Reynaert:
Multi-standard wideband OFDM RF-PWM transmitter in 40nm CMOS. ESSCIRC 2015: 88-91 - [c37]Bram Faes, Jeffrey Prinzie, Maarten Strackx, Patrick Reynaert, Paul Leroux:
Experimental validation of a compact model for EM reflection and transmission in multi-layered structures. I2MTC 2015: 905-909 - [c36]Bram Faes, Patrick Reynaert, Paul Leroux:
A 280 ps - 7.5 ns UWB Pulse Generator with Amplitude Compensation in 40 nm CMOS. ICUWB 2015: 1-4 - [c35]Wouter Volkaerts, Niels Van Thienen, Patrick Reynaert:
10.2 An FSK plastic waveguide communication link in 40nm CMOS. ISSCC 2015: 1-3 - 2014
- [j24]Noël Deferm, Patrick Reynaert:
A 120 GHz Fully Integrated 10 Gb/s Short-Range Star-QAM Wireless Transmitter With On-Chip Bondwire Antenna in 45 nm Low Power CMOS. IEEE J. Solid State Circuits 49(7): 1606-1616 (2014) - [j23]Wouter Steyaert, Patrick Reynaert:
A 0.54 THz Signal Generator in 40 nm Bulk CMOS With 22 GHz Tuning Range and Integrated Planar Antenna. IEEE J. Solid State Circuits 49(7): 1617-1626 (2014) - [j22]Bo Liu, Dixian Zhao, Patrick Reynaert, Georges G. E. Gielen:
GASPAD: A General and Efficient mm-Wave Integrated Circuit Synthesis Method Based on Surrogate Model Assisted Evolutionary Algorithm. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 33(2): 169-182 (2014) - [j21]Pieter A. J. Nuyts, Patrick Reynaert, Wim Dehaene:
Frequency-Domain Analysis of Digital PWM-Based RF Modulators for Flexible Wireless Transmitters. IEEE Trans. Circuits Syst. I Regul. Pap. 61-I(1): 238-246 (2014) - [j20]David Seebacher, Peter Singerl, Christian Schuberth, Franz Dielacher, Patrick Reynaert, Wolfgang Bösch:
Reduction of Aliasing Effects of RF PWM Modulated Signals by Cross Point Estimation. IEEE Trans. Circuits Syst. I Regul. Pap. 61-I(11): 3184-3192 (2014) - [c34]Dixian Zhao, Patrick Reynaert:
A 3 Gb/s 64-QAM E-band direct-conversion transmitter in 40-nm CMOS. A-SSCC 2014: 177-180 - [c33]Paramartha Indirayanti, Tuba Ayhan, Marian Verhelst, Wim Dehaene, Patrick Reynaert:
A 60GHz transmitter in 40nm CMOS achieving mm-precision for discrete-carrier localization. ESSCIRC 2014: 291-294 - [c32]Marco Vigilante, Patrick Reynaert:
An E-Band low-noise Transformer-Coupled Quadrature VCO in 40 nm CMOS. ESSCIRC 2014: 423-426 - [c31]Barend van Liempd, Jan Craninckx, R. Singh, Patrick Reynaert, Satoshi Malotaux, John R. Long:
A dual-notch +27dBm Tx-power electrical-balance duplexer. ESSCIRC 2014: 463-466 - [c30]Niels Van Thienen, Patrick Reynaert:
A 160-GHz three-stage fully-differential amplifier in 40-nm CMOS. ICECS 2014: 144-147 - [c29]Florian De Roose, Valentijn De Smedt, Wouter Volkaerts, Michiel Steyaert, Georges G. E. Gielen, Patrick Reynaert, Wim Dehaene:
Design of a frequency reference based on a PVT-independent transmission line delay. ISCAS 2014: 1772-1775 - [c28]Brecht François, Patrick Reynaert:
3.3 A transformer-coupled true-RMS power detector in 40nm CMOS. ISSCC 2014: 62-63 - [c27]Ercan Kaymaksut, Patrick Reynaert:
3.4 A dual-mode transformer-based doherty LTE power amplifier in 40nm CMOS. ISSCC 2014: 64-65 - [c26]Dixian Zhao, Patrick Reynaert:
14.1 A 0.9V 20.9dBm 22.3%-PAE E-band power amplifier with broadband parallel-series power combiner in 40nm CMOS. ISSCC 2014: 248-249 - [c25]Shailesh Kulkarni, Patrick Reynaert:
14.3 A Push-Pull mm-Wave power amplifier with. ISSCC 2014: 252-253 - [c24]Tom Redant, Tuba Ayhan, Nico De Clercq, Marian Verhelst, Patrick Reynaert, Wim Dehaene:
20.1 A 40nm CMOS receiver for 60GHz discrete-carrier indoor localization achieving mm-precision at 4m range. ISSCC 2014: 342-343 - 2013
- [j19]Dixian Zhao, Patrick Reynaert:
A 60-GHz Dual-Mode Class AB Power Amplifier in 40-nm CMOS. IEEE J. Solid State Circuits 48(10): 2323-2337 (2013) - [j18]Shailesh Kulkarni, Dixian Zhao, Patrick Reynaert:
Design of an Optimal Layout Polyphase Filter for Millimeter-Wave Quadrature LO Generation. IEEE Trans. Circuits Syst. II Express Briefs 60-II(4): 202-206 (2013) - [j17]Ercan Kaymaksut, Brecht François, Patrick Reynaert:
Analysis and Optimization of Transformer-Based Power Combining for Back-Off Efficiency Enhancement. IEEE Trans. Circuits Syst. I Regul. Pap. 60-I(4): 825-835 (2013) - [j16]Tom Redant, Pieter A. J. Nuyts, Patrick Reynaert, Wim Dehaene:
Presilicon Circuit-Aware Linear Least Squares Spectral Analysis for Time-Based Data Converters. IEEE Trans. Circuits Syst. II Express Briefs 60-II(11): 751-755 (2013) - [c23]Noël Deferm, Wouter Volkaerts, Juan F. Osorio, Anton de Graauw, Michiel Steyaert, Patrick Reynaert:
A 120GHz fully integrated 10Gb/s wireless transmitter with on-chip antenna in 45nm low power CMOS. ESSCIRC 2013: 331-334 - [c22]Maarten Tytgat, Patrick Reynaert:
A plastic waveguide receiver in 40nm CMOS with on-chip bondwire antenna. ESSCIRC 2013: 335-338 - [c21]Wouter Steyaert, Patrick Reynaert:
A 0.54 THz signal generator in 40 nm bulk CMOS with 22 GHz tuning range. ESSCIRC 2013: 411-414 - 2012
- [j15]Atila Alvandpour, Patrick Reynaert, Trond Ytterdal:
Introduction to the Special Issue on the 37th European Solid-State Circuits Conference (ESSCIRC). IEEE J. Solid State Circuits 47(7): 1511-1514 (2012) - [j14]Ercan Kaymaksut, Patrick Reynaert:
Transformer-Based Uneven Doherty Power Amplifier in 90 nm CMOS for WLAN Applications. IEEE J. Solid State Circuits 47(7): 1659-1671 (2012) - [j13]Pieter A. J. Nuyts, Peter Singerl, Franz Dielacher, Patrick Reynaert, Wim Dehaene:
A Fully Digital Delay Line Based GHz Range Multimode Transmitter Front-End in 65-nm CMOS. IEEE J. Solid State Circuits 47(7): 1681-1692 (2012) - [j12]Dixian Zhao, Shailesh Kulkarni, Patrick Reynaert:
A 60-GHz Outphasing Transmitter in 40-nm CMOS. IEEE J. Solid State Circuits 47(12): 3172-3183 (2012) - [j11]Bo Liu, Noël Deferm, Dixian Zhao, Patrick Reynaert, Georges G. E. Gielen:
An Efficient High-Frequency Linear RF Amplifier Synthesis Method Based on Evolutionary Computation and Machine Learning Techniques. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 31(7): 981-993 (2012) - [j10]Pieter A. J. Nuyts, Brecht François, Wim Dehaene, Patrick Reynaert:
A CMOS Burst-Mode Transmitter With Watt-Level RF PA and Flexible Fully Digital Front-End. IEEE Trans. Circuits Syst. II Express Briefs 59-II(10): 613-617 (2012) - [c20]Dixian Zhao, Shailesh Kulkarni, Patrick Reynaert:
A 60 GHz dual-mode power amplifier with 17.4 dBm output power and 29.3% PAE in 40-nm CMOS. ESSCIRC 2012: 337-340 - [c19]Shailesh Kulkarni, Dixian Zhao, Patrick Reynaert:
Analysis and characterization of mismatches in outphasing transmitter. ICECS 2012: 169-172 - [c18]Paramartha Indirayanti, Wouter Volkaerts, Patrick Reynaert, Wim Dehaene:
Picosecond pulse generation with nonlinear transmission lines in 90-nm CMOS for mm-wave imaging applications. ICECS 2012: 885-888 - [c17]Dixian Zhao, Shailesh Kulkarni, Patrick Reynaert:
A 60GHz outphasing transmitter in 40nm CMOS with 15.6dBm output power. ISSCC 2012: 170-172 - 2011
- [j9]Bo Liu, Dixian Zhao, Patrick Reynaert, Georges G. E. Gielen:
Synthesis of Integrated Passive Components for High-Frequency RF ICs Based on Evolutionary Computation and Machine Learning Techniques. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 30(10): 1458-1468 (2011) - [c16]Bo Liu, Ying He, Patrick Reynaert, Georges G. E. Gielen:
Global optimization of integrated transformers for high frequency microwave circuits using a Gaussian process based surrogate model. DATE 2011: 1101-1106 - [c15]Ercan Kaymaksut, Patrick Reynaert:
CMOS transformer-based uneven Doherty power amplifier for WLAN applications. ESSCIRC 2011: 135-138 - [c14]Maarten Tytgat, Michiel Steyaert, Patrick Reynaert:
A 200GHz downconverter in 90nm CMOS. ESSCIRC 2011: 239-242 - [c13]Brecht François, Patrick Reynaert:
A fully integrated CMOS power amplifier for LTE-applications using clover shaped DAT. ESSCIRC 2011: 303-306 - [c12]Pieter A. J. Nuyts, Peter Singerl, Franz Dielacher, Patrick Reynaert, Wim Dehaene:
A fully digital delay-line based GHz-range multimode transmitter front-end in 65-nm CMOS. ESSCIRC 2011: 395-398 - [c11]Lianming Li, Patrick Reynaert, Michiel Steyaert:
A colpitts LC VCO with Miller-capacitance gm enhancing and phase noise reduction techniques. ESSCIRC 2011: 491-494 - [c10]Noël Deferm, Patrick Reynaert:
A 120GHz 10Gb/s phase-modulating transmitter in 65nm LP CMOS. ISSCC 2011: 290-292 - 2010
- [c9]Lianming Li, Patrick Reynaert, Michiel Steyaert:
A 60GHz 15.7mW static frequency divider in 90nm CMOS. ESSCIRC 2010: 246-249 - [c8]Ercan Kaymaksut, Patrick Reynaert:
A 2.4 GHz fully integrated Doherty power amplifier using series combining transformer. ESSCIRC 2010: 302-305 - [c7]Ying He, Lianming Li, Patrick Reynaert:
60GHz power amplifier with distributed active transformer and local feedback. ESSCIRC 2010: 314-317 - [c6]Wouter Volkaerts, Bart Marien, Hans Danneels, Valentijn De Smedt, Patrick Reynaert, Wim Dehaene, Georges G. E. Gielen:
A 0.5 V-1.4 V supply-independent frequency-based analog-to-digital converter with fast start-up time for wireless sensor networks. ISCAS 2010: 3096-3099
2000 – 2009
- 2009
- [j8]Ali M. Niknejad, Ehsan Adabi, Babak Heydari, Mounir Bohsali, Bagher Afshar, Debopriyo Chowdhury, Patrick Reynaert:
Device, Circuit, and System Considerations for 60 GHz CMOS. IEICE Trans. Fundam. Electron. Commun. Comput. Sci. 92-A(2): 350-359 (2009) - [j7]Lianming Li, Patrick Reynaert, Michiel S. J. Steyaert:
Design and Analysis of a 90 nm mm-Wave Oscillator Using Inductive-Division LC Tank. IEEE J. Solid State Circuits 44(7): 1950-1958 (2009) - [j6]Debopriyo Chowdhury, Patrick Reynaert, Ali M. Niknejad:
Design Considerations for 60 GHz Transformer-Coupled CMOS Power Amplifiers. IEEE J. Solid State Circuits 44(10): 2733-2744 (2009) - 2008
- [j5]Peter Haldi, Debopriyo Chowdhury, Patrick Reynaert, Gang Liu, Ali M. Niknejad:
A 5.8 GHz 1 V Linear Power Amplifier Using a Novel On-Chip Transformer Power Combiner in Standard 90 nm CMOS. IEEE J. Solid State Circuits 43(5): 1054-1063 (2008) - [j4]Debopriyo Chowdhury, Patrick Reynaert, Ali M. Niknejad:
Transformer-Coupled Power Amplifier Stability and Power Back-Off Analysis. IEEE Trans. Circuits Syst. II Express Briefs 55-II(6): 507-511 (2008) - [c5]Lianming Li, Patrick Reynaert, Michiel Steyaert:
A 90nm CMOS mm-wave VCO using an LC tank with inductive division. ESSCIRC 2008: 238-241 - [c4]Debopriyo Chowdhury, Patrick Reynaert, Ali M. Niknejad:
A 60GHz 1V + 12.3dBm Transformer-Coupled Wideband PA in 90nm CMOS. ISSCC 2008: 560-561 - 2007
- [j3]Patrick Reynaert, Michiel S. J. Steyaert:
A 2.45-GHz 0.13-µm CMOS PA With Parallel Amplification. IEEE J. Solid State Circuits 42(3): 551-562 (2007) - [c3]Patrick Reynaert, Ali M. Niknejad:
Power combining techniques for RF and mm-wave CMOS power amplifiers. ESSCIRC 2007: 272-275 - 2005
- [j2]Patrick Reynaert, Michiel S. J. Steyaert:
A 1.75-GHz polar modulated CMOS RF power amplifier for GSM-EDGE. IEEE J. Solid State Circuits 40(12): 2598-2608 (2005) - [c2]Koen Cornelissens, Patrick Reynaert, Michiel Steyaert:
A 0.18μm CMOS switched capacitor voltage modulator. ESSCIRC 2005: 375-378 - [c1]Michiel Steyaert, Frederique Gobert, Carolien Hermans, Patrick Reynaert, Bert Serneels:
Digital communication systems: the problem of analog interface circuits. ESSCIRC 2005: 423-426 - 2003
- [j1]Patrick Reynaert, Koen L. R. Mertens, Michiel Steyaert:
A state-space behavioral model for CMOS class E power amplifiers. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 22(2): 132-138 (2003)
Coauthor Index
Michiel Steyaert
aka: Michiel S. J. Steyaert
aka: Michiel S. J. Steyaert
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Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from 
, 
, and 
to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from 
.
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2024-10-07 21:21 CEST by the dblp team
all metadata released as open data under CC0 1.0 license
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since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by:
