prof.dr. L.C.N. de Vreede

Professor, Chairman
Electronic Circuits and Architectures (ELCA), Department of Microelectronics

Expertise: RF, Microwave, Power Amplifiers, Device Characterization & modeling

Themes: XG - Next Generation Sensing and Communication

Biography

Leo C. N. de Vreede was born in Delft, the Netherlands in 1965. He received his Ph.D. degree (cum laude) from the Delft University of Technology in 1996. In 1988, he joined the Laboratory of Telecommunication and Remote Sensing Technology of the Department of Electrical Engineering, Delft University of Technology. In 1996, he was appointed as an assistant professor at the Delft University of Technology, working on the nonlinear distortion behavior of bipolar transistors at the Delft Institute of Microelectronics and Submicron Technology (DIMES). In the winter season of 98-99, he was a guest of the high-speed device group at the University of San Diego, California.

In 1999 and 2015, he was appointed as an associate professor and, respectively, full professor at the Delft University of Technology and became responsible for the Microwave Components Group and the Electronics Research Laboratory. Since then, he worked on RF solutions for improved linearity and RF performance at the device, circuit, and system levels. He is a co-founder/advisor of Anteverta-mw, a company specializing in RF device characterization. He is (co)recipient of the IEEE Microwave Prize in 2008, mentor of the Else Kooi Prize awarded Ph.D. work in 2010, and mentor of the Dow Energy dissertation prize awarded Ph.D. work in 2011. Recipient of the TUD Entrepreneurial Scientist Award 2015. He (co)guided several students who won (best) paper awards at the BCTM, PRORISC, GAAS, ESSDERC, ISOCC, IMS, RFIT, and RFIC. He (co)authored more than 170 IEEE refereed conference and journal papers and holds over 20 patents. His current interests include RF measurement systems, technology optimization, and circuit/system concepts for wireless systems.

Announcement: Open Ph.D. position on “The design of digital-intensive transmitters for 6G applications.” This Ph.D. project targets advanced, fully integrated digital transmitters (DTX) for 6G mobile communication networks operating in the urban extreme capacity 7-to-20GHz band. The focus is on identifying new DTX architectures that meet the stringent requirements regarding operating frequency, bandwidth, spectral purity, and RF output power of the 6G standard. You will design novel CMOS/SOI-based DTX solutions for future “extreme massive multiple-input multiple-output” (XMIMO) wireless systems. You will work in the ELCA research group of the TU Delft and will be guided by Dr. Morteza Alavi and Prof. Leo de Vreede.

If you have knowledge of RF, mixed-signal, digital design, experience with ADS and Cadence, and are interested in this position, please submit your resume to Dr. Morteza Alavi ([email protected]) and/or Leo de Vreede ([email protected]).

 

 

EE4605 Integrated circuits and systems for wireless applications

Design and analysis of typical RF IC building blocks in a wireless transceiver

EE4C10 Analog circuit design fundamentals

EE4C13 Wireless systems for electrical engineering applications

Commonly used RF electronics architectures in wireless systems, with the requirements on their building blocks.

Education history

EE4600 Wireless Concepts and Systems

(not running) Basic concepts of RF design, such as noise, nonlinearity, Impedance Matching, Analog/Digital Modulation, Pulse-shaping, Mixer, Oscillator, Link-budget, Transmitter/Receiver Architectures

Digital tRAnSmitTer ICs

This project aims to develop DTX ICs for highly-integrated and energy-efficient mMIMO base stations.

Energy Efficient Wideband Transmitter, NXP Partnership ‘Advanced 5G Solutions’

This project providing enhanced average efficiency in wideband wireless transmitters while withstanding the changing load conditions that can occur in handheld devices and MIMO/smart-antenna communication systems.

Smart Energy Efficient Digital Communication

SEEDCOM aims for fully integrated energy efficient wideband transmitters

smart Everything everywhere Access to content through Small cells Technologies

EAST is focused on the development of Small cell technologies for 5G applications up to 6 GHz

Integrated Near Field sensOrs for high Resolution MicrowavE spectRoscopy

The goal of this project is the creation of a new class of sensors, enabling fast and accurate dielectric characterization of biological samples, with high-sensitivity and high-spatial resolution.

Projects history

High Power RF-DAC

This project investigates the next generation of high power RF-DACs and digital intensive receivers

Merging electronics and Micro-nano PHotonics in integrated systeMs

Research program for developing an integration platform for high-frequency electronics with micro- and nano-photonics.

  1. A Single-Supply Balun-First Three-Way mm-Wave Doherty PA
    Kumaran, Anil Kumar; Pashaeifar, Masoud; Alexanderson, Mats; de Vreede, Leonardus Cornelis Nicolaas; Alavi, Morteza S.;
    IEEE Transactions on Microwave Theory and Techniques,
    pp. 1-16, 2024. DOI: 10.1109/TMTT.2024.3365697
    Keywords: ... Inductors;Integrated circuit modeling;5G mobile communication;Capacitors;Bandwidth;Impedance;Peak to average power ratio;Compact;Doherty;lumped components;millimeter wave;Norton transformation;power amplifier (PA);three-stage.

  2. 32.7 A 25.2dBm PSAT, 35-to-43GHz VSWR-Resilient Chain-Weaver Eight-Way Balanced PA with an Embedded Impedance/Power Sensor
    Pashaeifar, Masoud; Kumaran, Anil K.; De Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2024 IEEE International Solid-State Circuits Conference (ISSCC),
    pp. 532-534, 2024. DOI: 10.1109/ISSCC49657.2024.10454427
    Keywords: ... Time-frequency analysis;5G mobile communication;Transmitters;Linearity;Power amplifiers;Solid state circuits;Reliability.

  3. A Wideband Digital-Intensive Current-Mode Transmitter Line-Up
    Y. Shen; M. Hoogelander; R. Bootsman; M. S. Alavi; L. C. N. de Vreede;
    IEEE Journal Solid-State Circuits,
    Volume 58, Issue 9, pp. 2489-2500, Sep. 2023. DOI: 10.1109/JSSC.2023.3279235

  4. A Wideband Energy-Efficient Multi-Mode CMOS Digital Transmitter
    Beikmirza, Mohammadreza; Shen, Yiyu; de Vreede, Leo C. N.; Alavi, Morteza S.;
    IEEE Journal of Solid-State Circuits,
    Volume 58, Issue 3, pp. 677-690, 2023. DOI: 10.1109/JSSC.2022.3222028

  5. A Wideband Digital-Intensive Current-Mode Transmitter Line-Up
    Shen, Yiyu; Hoogelander, Martijn; Bootsman, Rob; Alavi, Morteza S.; de Vreede, Leo C. N.;
    IEEE Journal of Solid-State Circuits,
    pp. 1-12, 2023. DOI: 10.1109/JSSC.2023.3279235

  6. An Inverted Doherty Power Amplifier Insensitive to Load Variation With an Embedded Impedance Sensor in Its Output Power-Combining Network
    Singh, Gagan Deep; Nemati, Hossein Mashad; Alavi, Morteza S.; de Vreede, Leonardus Cornelis Nicolaas;
    IEEE Transactions on Microwave Theory and Techniques,
    pp. 1-15, 2023. DOI: 10.1109/TMTT.2023.3277081

  7. A Highly Linear Receiver Using Parallel Preselect Filter for 5G Microcell Base Station Applications
    Montazerolghaem, Mohammad Ali; de Vreede, Leo C. N.; Babaie, Masoud;
    IEEE Journal of Solid-State Circuits,
    pp. 1-16, 2023. DOI: 10.1109/JSSC.2023.3267723

  8. The Efficiency and Power Utilization of Current-Scaling Digital Transmitters
    Mul, Dieuwert P. N.; Bootsman, Robert J.; Beikmirza, Mohammadreza; Alavi, Morteza S.; de Vreede, Leo C. N.;
    IEEE Transactions on Microwave Theory and Techniques,
    pp. 1-17, 2023. DOI: 10.1109/TMTT.2023.3336984
    Keywords: ... Switches;Radio frequency;Clocks;Logic gates;Transmitters;Power generation;Loading;Current mode;current scaling;digital transmitter (DTX);Doherty;efficiency;multiphase;peak-to-average-power ratio (PAPR);polar;power utilization;RF-DAC;signed Cartesian (SC);upconversion.

  9. 19.1 A 300MHz-BW, 27-to-38dBm In-Band OIP3 sub-7GHz Receiver for 5G Local Area Base Station Applications
    Montazerolghaem, Mohammad Ali; de Vreede, Leo C. N.; Babaie, Masoud;
    In 2023 IEEE International Solid- State Circuits Conference (ISSCC),
    pp. 292-294, 2023. DOI: 10.1109/ISSCC42615.2023.10067266

  10. PA Output Power and Efficiency Enhancement Across the 2:1 VSWR Circle using Static Active Load Adjustment
    Singh, Gagan Deep; Nemati, Hossein Mashad; Alavi, Morteza S.; de Vreede, Leo C.N.;
    In 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023,
    pp. 211-214, 2023. DOI: 10.1109/IMS37964.2023.10188045
    Keywords: ... Loading;Power amplifiers;Couplers;Microwave theory and techniques;Microwave amplifiers;Power generation;Power Amplifier;VSWR;Coupler;Gallium Nitrite (GaN);HEMT.

  11. A Low-Complexity Digital Predistortion Technique For Digital I/Q Transmitters
    Beikmirza, Mohammadreza; de Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2023 IEEE/MTT-S International Microwave Symposium - IMS 2023,
    pp. 787-790, 2023. DOI: 10.1109/IMS37964.2023.10187914
    Keywords: ... Microwave measurement;Constellation diagram;Transmitters;Bandwidth;Microwave theory and techniques;Predistortion;Digital pre-distortion;DPD;constellation;mapping;digital transmitter;RF-DAC.

  12. A 26GHz Balun-First Three-Way Doherty PA in 40nm CMOS with 20.7 dBm Psat and 20dB Power Gain
    Kumaran, Anil Kumar; Pashaeifar, Masoud; Nemati, Hossein Mashad; de Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2023 IEEE Radio Frequency Integrated Circuits Symposium (RFIC),
    pp. 189-192, 2023. DOI: 10.1109/RFIC54547.2023.10186161
    Keywords: ... Power measurement;5G mobile communication;Radio transmitters;Power amplifiers;Radiofrequency integrated circuits;Frequency measurement;Scattering parameters;Doherty;3-stage Power amplifier;Compact;Millimeter wave;Lumped components;Norton transformation.

  13. A Four-Way Series Doherty Digital Polar Transmitter at mm-Wave Frequencies
    Mortazavi, Mohsen; Shen, Yiyu; Mul, Dieuwert; de Vreede, Leo C. N.; Spirito, Marco; Babaie, Masoud;
    IEEE Journal of Solid-State Circuits,
    Volume 57, Issue 3, pp. 803-817, 2022. DOI: 10.1109/JSSC.2021.3133861

  14. A 23.8–30.4-GHz Vector-Modulated Phase Shifter With Two-Stage Current-Reused Variable-Gain Amplifiers Achieving 0.23° Minimum RMS Phase Error
    Zhang, Linghan; Shen, Yiyu; de Vreede, Leo; Babaie, Masoud;
    IEEE Solid-State Circuits Letters,
    Volume 5, pp. 150-153, 2022. DOI: 10.1109/LSSC.2022.3179661

  15. A Millimeter-Wave CMOS Series-Doherty Power Amplifier With Post-Silicon Inter-Stage Passive Validation
    Pashaeifar, Masoud; de Vreede, Leo C. N.; Alavi, Morteza S.;
    IEEE Journal of Solid-State Circuits,
    Volume 57, Issue 10, pp. 2999-3013, 2022. DOI: 10.1109/JSSC.2022.3175685

  16. Load-Modulation-Based IMD3 Cancellation for Millimeter-Wave Class-B CMOS Power Amplifiers Achieving EVM < 1.2%
    Pashaeifar, Masoud; de Vreede, Leo C. N.; Alavi, Morteza S.;
    IEEE Microwave and Wireless Components Letters,
    Volume 32, Issue 6, pp. 716-719, 2022. DOI: 10.1109/LMWC.2022.3166257

  17. High-Power Digital Transmitters for Wireless Infrastructure Applications (A Feasibility Study)
    Bootsman, Robert J.; Mul, Dieuwert P. N.; Shen, Yiyu; Hashemi, Mohsen; Heeres, Rob M.; van Rijs, Fred; Alavi, Morteza S.; de Vreede, Leo C. N.;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 70, Issue 5, pp. 2835-2850, 2022. DOI: 10.1109/TMTT.2022.3153000

  18. A Wideband IQ-Mapping Direct-Digital RF Modulator for 5G Transmitters
    Shen, Yiyu; Bootsman, Robert; Alavi, Morteza S.; de Vreede, Leo C. N.;
    IEEE Journal of Solid-State Circuits,
    Volume 57, Issue 5, pp. 1446-1456, 2022. DOI: 10.1109/JSSC.2022.3144362

  19. A Load Insensitive Doherty Power Amplifier with better than −39dBc ACLR on 2:1 VSWR Circle using a Constant 50 Ω Trained Pre-distorted Signal
    Singh, Gagan Deep; Mul, Dieuwert; Nemati, Hossein Mashad; Alavi, Morteza S.; de Vreede, Leo C.N.;
    In 2022 52nd European Microwave Conference (EuMC),
    pp. 222-225, 2022. DOI: 10.23919/EuMC54642.2022.9924452

  20. A 39 W Fully Digital Wideband Inverted Doherty Transmitter
    Bootsman, Robert; Shen, Yiyu; Mul, Dieuwert; Rousstia, Mohadig; Heeres, Rob; van Rijs, Fred; Gajadharsing, John; Alavi, Morteza S.; de Vreede, Leo C.N.;
    In 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022,
    pp. 979-982, 2022. DOI: 10.1109/IMS37962.2022.9865405

  21. A Wideband Two-Way Digital Doherty Transmitter in 40nm CMOS
    Beikmirza, Mohammadreza; Shen, Yiyu; de Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2022 IEEE/MTT-S International Microwave Symposium - IMS 2022,
    pp. 975-978, 2022. DOI: 10.1109/IMS37962.2022.9865506

  22. A Millimeter-Wave Front-End for FD/FDD Transceivers Featuring an Embedded PA and an N-Path Filter Based Circulator Receiver
    Pashaeifar, Masoud; De Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2022 IEEE Radio Frequency Integrated Circuits Symposium (RFIC),
    pp. 11-14, 2022. DOI: 10.1109/RFIC54546.2022.9863209

  23. A 0.5-3GHz Receiver with a Parallel Preselect Filter Achieving 120dB/dec Channel Selectivity and +28dBm Out-of-Band IIP3
    Montazerolghaem, M. A.; de Vreede, Leo C. N.; Babaie, Masoud;
    In 2022 IEEE Custom Integrated Circuits Conference (CICC),
    pp. 11-12, 2022. DOI: 10.1109/CICC53496.2022.9772854

  24. A 1-to-4GHz Multi-Mode Digital Transmitter in 40nm CMOS Supporting 200MHz 1024-QAM OFDM signals with more than 23dBm/66% Peak Power/Drain Efficiency
    Beikmirza, Mohammadreza; Shen, Yiyu; de Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2022 IEEE Custom Integrated Circuits Conference (CICC),
    pp. 01-02, 2022. DOI: 10.1109/CICC53496.2022.9772797

  25. Compact N-Way Doherty Power Combiners for mm-wave 5G Transmitters
    Kumaran, Anil Kumar; Nemati, Hossein Mashad; De Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2022 IEEE International Symposium on Circuits and Systems (ISCAS),
    pp. 438-442, 2022. DOI: 10.1109/ISCAS48785.2022.9937619

  26. A Wideband Four-Way Doherty Bits-In RF-Out CMOS Transmitter
    Beikmirza, Mohammadreza; Shen, Yiyu; de Vreede, Leo C. N.; Alavi, Morteza S.;
    IEEE Journal of Solid-State Circuits,
    Volume 56, Issue 12, pp. 3768-3783, 2021. DOI: 10.1109/JSSC.2021.3105542

  27. A Millimeter-Wave Mutual-Coupling-Resilient Double-Quadrature Transmitter for 5G Applications
    Pashaeifar, Masoud; de Vreede, Leo C. N.; Alavi, Morteza S.;
    IEEE Journal of Solid-State Circuits,
    Volume 56, Issue 12, pp. 3784-3798, 2021. DOI: 10.1109/JSSC.2021.3111126

  28. 14.4 A 24-to-30GHz Double-Quadrature Direct-Upconversion Transmitter with Mutual-Coupling-Resilient Series-Doherty Balanced PA for 5G MIMO Arrays
    Pashaeifar, Masoud; de Vreede, Leo C. N.; Alavi, Morteza S.;
    In 2021 IEEE International Solid- State Circuits Conference (ISSCC),
    pp. 223-225, 2021. DOI: 10.1109/ISSCC42613.2021.9365776

  29. 6.2 A 4-Way Doherty Digital Transmitter Featuring 50%-LO Signed IQ Interleave Upconversion with more than 27dBm Peak Power and 40% Drain Efficiency at 10dB Power Back-Off Operating in the 5GHz Band
    Beikmirza, Mohammadreza; Shen, Yiyu; Mehrpoo, Mohammadreza; Hashemi, Mohsen; Mul, Dieuwert; de Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2021 IEEE International Solid- State Circuits Conference (ISSCC),
    pp. 92-94, 2021. DOI: 10.1109/ISSCC42613.2021.9365831

  30. 6.5 A 3dB-NF 160MHz-RF-BW Blocker-Tolerant Receiver with Third-Order Filtering for 5G NR Applications
    Montazerolghaem, Mohammad Ali; Pires, Sergio; de Vreede, Leo C.N.; Babaie, Masoud;
    In 2021 IEEE International Solid- State Circuits Conference (ISSCC),
    pp. 98-100, 2021. DOI: 10.1109/ISSCC42613.2021.9365849

  31. Efficiency and Linearity of Digital "Class-C Like" Transmitters
    Mul, Dieuwert P.N.; Bootsman, Rob J.; Bruinsma, Quinten; Shen, Yiyu; Krause, Sebastian; Quay, Rüdiger; Pelk, Marco J.; van Rijs, Fred; Heeres, Rob M.; Pires, Sergio; Alavi, Morteza; de Vreede, Leo C.N.;
    In 2020 50th European Microwave Conference (EuMC),
    pp. 1-4, 2021. DOI: 10.23919/EuMC48046.2021.9338122

  32. On-Chip Output Stage Design for a Continuous Class-F Power Amplifier
    Kumaran, Anil Kumar; Pashaeifar, Masoud; D’Avino, Marco; de Vreede, Leo C. N.; Alavi, Morteza S.;
    In 2021 IEEE International Symposium on Circuits and Systems (ISCAS),
    pp. 1-5, 2021. DOI: 10.1109/ISCAS51556.2021.9401788

  33. A 24-to-32GHz series-Doherty PA with two-step impedance inverting power combiner achieving 20.4dBm Psat and 38%/34% PAE at Psat/6dB PBO for 5G applications
    Pashaeifar, Masoud; Kumaran, Anil K.; Beikmirza, Mohammadreza; de Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2021 IEEE Asian Solid-State Circuits Conference (A-SSCC),
    pp. 1-3, 2021. DOI: 10.1109/A-SSCC53895.2021.9634772

  34. A Versatile and Efficient 0.1-to-11 Gb/s CML Transmitter in 40-nm CMOS
    Feng, Jun; Beikmirza, Mohammadreza; Mehrpoo, Mohammadreza; de Vreede, Leo C.N.; Alavi, Morteza S.;
    In 2021 18th International SoC Design Conference (ISOCC),
    pp. 41-42, 2021. DOI: 10.1109/ISOCC53507.2021.9613887

  35. A 30GHz 4-way Series Doherty Digital Polar Transmitter Achieving 18% Drain Efficiency and -27.6dB EVM while Transmitting 300MHz 64-QAM OFDM Signal
    Mortazavi, Mohsen; Shen, Yiyu; Mul, Dieuwert. P. N.; de Vreede, Leo C. N.; Spirito, Marco; Babaie, Masoud;
    In 2021 IEEE Custom Integrated Circuits Conference (CICC),
    pp. 1-2, 2021. DOI: 10.1109/CICC51472.2021.9431396

  36. An 18.5 W Fully-Digital Transmitter with 60.4 % Peak System Efficiency
    Bootsman, R.J.; Mul, D.P.N.; Shen, Y.; Heeres, R.M.; van Rijs, F.; Alavi, M.S.; de Vreede, L.C.N.;
    In 2020 IEEE/MTT-S International Microwave Symposium (IMS),
    pp. 1113-1116, 2020. DOI: 10.1109/IMS30576.2020.9223942

  37. A 1–3 GHz I/Q Interleaved Direct-Digital RF Modulator As A Driver for A Common-Gate PA in 40 nm CMOS
    Shen, Yiyu; Bootsman, Rob; Alavi, Morteza S.; de Vreede, Leo C.N.;
    In 2020 IEEE Radio Frequency Integrated Circuits Symposium (RFIC),
    pp. 287-290, 2020. DOI: 10.1109/RFIC49505.2020.9218324

  38. A 0.5-3 GHz I/Q Interleaved Direct-Digital RF Modulator with up to 320 MHz Modulation Bandwidth in 40 nm CMOS
    Shen, Yiyu; Bootsman, Rob; Alavi, Morteza S.; de Vreede, Leonardus;
    In 2020 IEEE Custom Integrated Circuits Conference (CICC),
    pp. 1-4, 2020. DOI: 10.1109/CICC48029.2020.9075949

  39. Miniaturized Broadband Microwave Permittivity Sensing for Biomedical Applications
    G. Vlachogiannakis; Z. Hu; H. T. Shivamurthy; A. Neto; M. A. P. Pertijs; M. Spirito; L. C. N. de Vreede;
    IEEE Journal of Electromagnetics, RF and Microwaves in Medicine and Biology,
    Volume 3, Issue 1, pp. 48--55, March 2019. DOI: 10.1109/JERM.2018.2882564
    Abstract: ... A compact sensing pixel for the determination of the localized complex permittivity at microwave frequencies is proposed. Implemented in the 40-nm CMOS, the architecture comprises a square patch, interfaced to the material-under-test sample, that provides permittivity-dependent admittance. The patch admittance is read out by embedding the patch in a double-balanced, RF-driven Wheatstone bridge. The bridge is cascaded by a linear, low-intermediate frequency switching downconversion mixer, and is driven by a square wave that allows simultaneous characterization of multiple harmonics, thus increasing measurement speed and extending the frequency range of operation. In order to allow complex permittivity measurement, a calibration procedure has been developed for the sensor. Measurement results of liquids show good agreement with theoretical values, and the measured relative permittivity resolution is better than 0.3 over a 0.1-10-GHz range. The proposed implementation features a measurement speed of 1 ms and occupies an active area of 0.15x0.3 mm², allowing for future compact arrays of multiple sensors that facilitate 2-D dielectric imaging based on permittivity contrast.

  40. Miniaturized Broadband Microwave Permittivity Sensing for Biomedical Applications
    Vlachogiannakis, Gerasimos; Hu, Zhebin; Shivamurthy, Harshitha Thippur; Neto, Andrea; Pertijs, Michiel A. P.; de Vreede, Leo C. N.; Spirito, Marco;
    IEEE Journal of Electromagnetics, RF and Microwaves in Medicine and Biology,
    Volume 3, Issue 1, pp. 48-55, 2019. DOI: 10.1109/JERM.2018.2882564

  41. Miniaturized Broadband Microwave Permittivity Sensing for Biomedical Applications
    G. Vlachogiannakis; Z. Hu; Thippur Shivamurthy, H.; A. Neto; M.A.P. Pertijs; L.C.N. de Vreede; M. Spirito;
    IEEE Journal of Electromagnetics, RF and Microwaves in Medicine and Biology,
    Volume 3, Issue 1, pp. 48-55, Mar. 2019. DOI: 10.1109/JERM.2018.2882564

  42. A Highly Linear Wideband Polar Class-E CMOS Digital Doherty Power Amplifier
    Hashemi, Mohsen; Zhou, Lei; Shen, Yiyu; de Vreede, Leo C. N.;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 67, Issue 10, pp. 4232-4245, 2019. DOI: 10.1109/TMTT.2019.2933204

  43. Digital Transmitters for Sub-6GHz Wireless Applications
    Leo de Vreede;
    In IEEE International Solid-State Circuits Conference (ISSCC) Forum,
    2019.

  44. A Wideband Linear $I/Q$ -Interleaving DDRM
    Mehrpoo, Mohammadreza; Hashemi, Mohsen; Shen, Yiyu; de Vreede, Leo C. N.; Alavi, Morteza S.;
    IEEE Journal of Solid-State Circuits,
    Volume 53, Issue 5, pp. 1361-1373, 2018. DOI: 10.1109/JSSC.2017.2786685

  45. A 40-nm CMOS Complex Permittivity Sensing Pixel for Material Characterization at Microwave Frequencies
    Vlachogiannakis, Gerasimos; Pertijs, Michiel A. P.; Spirito, Marco; de Vreede, Leo C. N.;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 66, Issue 3, pp. 1619-1634, 2018. DOI: 10.1109/TMTT.2017.2753228

  46. A 40-nm CMOS Complex Permittivity Sensing Pixel for Material Characterization at Microwave Frequencies
    G. Vlachogiannakis; M. A. P. Pertijs; M. Spirito; L. C. N. de Vreede;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 66, Issue 3, pp. 1619-1634, March 2018. DOI: 10.1109/tmtt.2017.2753228
    Abstract: ... A compact sensing pixel for the determination of the localized complex permittivity at microwave frequencies is proposed. Implemented in the 40-nm CMOS, the architecture comprises a square patch, interfaced to the material-under-test sample, that provides permittivity-dependent admittance. The patch admittance is read out by embedding the patch in a double-balanced, RF-driven Wheatstone bridge. The bridge is cascaded by a linear, low-intermediate frequency switching downconversion mixer, and is driven by a square wave that allows simultaneous characterization of multiple harmonics, thus increasing measurement speed and extending the frequency range of operation. In order to allow complex permittivity measurement, a calibration procedure has been developed for the sensor. Measurement results of liquids show good agreement with theoretical values, and the measured relative permittivity resolution is better than 0.3 over a 0.1-10-GHz range. The proposed implementation features a measurement speed of 1 ms and occupies an active area of 0.15x0.3 mm², allowing for future compact arrays of multiple sensors that facilitate 2-D dielectric imaging based on permittivity contrast.

  47. High Efficiency and Wide Bandwidth Quasi-Load Insensitive Class-E Operation Utilizing Package Integration
    Qureshi, Abdul Raheem; Acar, Mustafa; Pires, Sergio C.; de Vreede, Leo Cornelis Nicolaas;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 66, Issue 12, pp. 5310-5321, 2018. DOI: 10.1109/TMTT.2018.2868876

  48. Quasi-load insensitive class-E for Doherty and Outphasing Transmitters
    Leo de Vreede; Morteza S. Alavi;
    In IEEE MTT-S International Microwave Symposium (IMS), Workshop,
    2018.

  49. Pushing the Linearity Limits of a Digital Polar Transmitter
    Hashemi, Mohsen; Alavi, Morteza S.; De Vreede, Leo C.N.;
    In 2018 13th European Microwave Integrated Circuits Conference (EuMIC),
    pp. 174-177, 2018. DOI: 10.23919/EuMIC.2018.8539964

  50. A 5x5 Microwave Permittivity Sensor Matrix in 0.14-μm CMOS
    Z. Hu; G. Vlachogiannakis; M. A. P. Pertijs; L. C. N. de Vreede; M. Spirito;
    In Proc. IEEE MTT-S International Microwave Symposium (IMS),
    6 2018. DOI: 10.1109/MWSYM.2018.8439438

  51. A Compact Energy Efficient CMOS Permittivity Sensor Based on Multi-Harmonic Downconversion and Tunable Impedance Bridge
    G. Vlachogiannakis; Z. Hu; H. T. Shivamurthy; A. Neto; M. A. P. Pertijs; L. C. N. de Vreede; M. Spirito;
    In Int. Microwave Biomedical Conference (IMBioC),
    pp. 1--3, June 2018. DOI: 10.1109/IMBIOC.2018.8428950
    Abstract: ... This paper presents a 0.15×0.3 mm2 complex permittivity sensor integrated in a 40-nm CMOS node. A single-ended patch, employed as a near-field sensing element, is integrated with a double-balanced, fully-differential tunable impedance bridge that is driven by a square RF pulse. The multi-harmonic, intermediate-frequency down-conversion architecture achieves a compact form factor and fast multi-frequency readout. Measurement results show good agreement with theoretical values and the measured relative permittivity variation remains below 0.3 over a 0.1-10 GHz range at a 1-ms measurement time. The energy efficiency resulting from the fast measurement time and the record-small active area allows integration in battery-operated wearables.

  52. Bits-In / RF-Out Transmitters for 5G mMIMO
    Leo de Vreede; Morteza S. Alavi;
    In IEEE European Microwave Week (EuMIC) Workshop,
    2018.

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  54. A wideband I/Q RFD AC-based phase modulator
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  55. A 5×5 Microwave Permittivity Sensor Matrix in O.14-m CMOS
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  56. An Intrinsically Linear Wideband Polar Digital Power Amplifier
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  57. An intrinsically linear wideband digital polar PA featuring AM-AM and AM-PM corrections through nonlinear sizing, overdrive-voltage control, and multiphase RF clocking
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  61. Enhanced Bipolar Transistor Design for the Linearization of the Base-Collector Capacitance
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  62. A linearization technique for bipolar amplifiers based on derivative superposition
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  63. Enhanced bipolar transistor design for the linearization of the base-collector capacitance
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  64. High efficiency RF power amplifiers featuring package integrated load insensitive class-E devices
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  65. A wideband linear direct digital RF modulator using harmonic rejection and I/Q-interleaving RF DACs
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  66. Highly efficient and linear class-E CMOS digital power amplifier using a compensated Marchand balun and circuit-level linearization achieving 67% peak DE and −40dBc ACLR without DPD
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  67. A fully-integrated digital-intensive polar Doherty transmitter
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  68. Out-of-Band Immunity to Interference of Single-Ended Baseband Amplifiers Through IM2 Cancellation
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  69. Contactless Measurement of Absolute Voltage Waveforms by a Passive Electric-Field Probe
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  70. Out-of-Band Immunity to Interference of Single-Ended Baseband Amplifiers Through $IM_2$ Cancellation
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  71. Nonintrusive Near-Field Characterization of Spatially Distributed Effects in Large-Periphery High-Power GaN HEMTs
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  72. A 40-nm CMOS permittivity sensor for chemical/biological material characterization at RF/microwave frequencies
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  73. A 5.9 GHz RFDAC-based outphasing power amplifier in 40-nm CMOS with 49.2% efficiency and 22.2 dBm power
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  74. A 112W GaN dual input Doherty-Outphasing Power Amplifier
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  75. A 40-nm CMOS permittivity sensor for chemical/biological material characterization at RF/microwave frequencies
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  76. Silicon-Based Technology for Integrated Waveguides and mm-Wave Systems
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  77. Outphasing transmitters, enabling digital-like amplifier operation with high efficiency and spectral purity
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  78. Non-intrusive near-field characterization of distributed effects in large-periphery LDMOS RF power transistors
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  79. A Wideband 2$\times$ 13-bit All-Digital I/Q RF-DAC
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  80. A package-integratable six-port reflectometer for power devices
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  81. Analysis of pure- and mixed-mode class-B outphasing amplifiers
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  82. A Package-Integrated Chireix Outphasing RF Switch-Mode High-Power Amplifier
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  83. Silicon-Filled Rectangular Waveguides and Frequency Scanning Antennas for mm-Wave Integrated Systems
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  84. Ultra-wide band CPW to substrate integrated waveguide (SIW) transition based on a U-shaped slot antenna
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  85. A 70W package-integrated class-E Chireix outphasing RF power amplifier
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  86. Non-intrusive characterization of active device interactions in high-efficiency power amplifiers
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  87. Evaluation of HBT device linearity using advanced measurement techniques
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  88. Device characterization for LTE applications with wideband baseband, fundamental and harmonic impedance control
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  89. On the bandwidth performance of Doherty amplifiers
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  90. Synthesized pulsed bias for device characterization
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  91. A 2×13-bit all-digital I/Q RF-DAC in 65-nm CMOS
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  92. On the Compression and Blocking Distortion of Semiconductor-Based Varactors
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  93. All-Digital RF $I/Q$ Modulator
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  94. RF Power Insensitive Varactors
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  95. Silicon integrated waveguide technology for mm-wave frequency scanning array
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  96. Digital predistortion for dual-input Doherty amplifiers
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  97. Contactless measurement of in-circuit reflection coefficients
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  98. On the design of package-integrated RF high-power amplifiers
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  99. An Ultra-Low-Power BPSK Receiver and Demodulator Based on Injection-Locked Oscillators
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  100. Millimeter-wave integrated waveguides on silicon
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  101. A 2-GHz digital I/Q modulator in 65-nm CMOS
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  102. A compact and power-scalable 70W GaN class-E power amplifier operating from 1.7 to 2.6 GHz
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  103. Orthogonal summing and power combining network in a 65-nm all-digital RF I/Q modulator
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  104. A compact 65W 1.7–2.3GHz class-E GaN power amplifier for base stations
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  105. A compact 65W 1.7–2.3GHz class-E GaN power amplifier for base stations
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  106. A transformer for high-power RF applications using bondwires in parallel
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  107. A 550–1050MHz +30dBm class-E power amplifier in 65nm CMOS
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  108. A 65nm CMOS pulse-width-controlled driver with 8Vpp output voltage for switch-mode RF PAs up to 3.6GHz
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  109. Millimeter-wave integrated waveguides on silicon
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  110. Efficient LDMOS device operation for envelope tracking amplifiers through second harmonic manipulation
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  111. Silicon Filled Integrated Waveguides
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  112. A GaAs Junction Varactor With a Continuously Tunable Range of 9 : 1 and an $OIP_3$ of 57 dBm
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  113. Design concepts for semiconductor based ultra linear varactor circuits.
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  114. The state-of-the-art of RF capacitive tunable components
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  115. The state-of-the-art of RF capacitive tunable components (Invited)
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  116. Design concepts for semiconductor based ultra-linear varactor circuits (invited)
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  117. A wide-band 20W LMOS Doherty power amplifier
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  118. A multi-step phase calibration procedure for closely spaced multi-tone signals
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  119. A 120µW fully-integrated BPSK receiver in 90nm CMOS
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  120. Analysis and design of a wideband high efficiency CMOS outphasing amplifier
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  121. A mixed-signal load-pull system for base-station applications
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  122. Enhanced RF power amplifiers and device characterization setups using coherent mixed-signal techniques
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  123. Ultra Linear Low-Loss Varactor Diode Configurations for Adaptive RF Systems
    C. Huang; K. Buisman; M. Maretti; L. K. Nanver; F. Sarubbi; M. Popadic; T. Scholtes; H. Schellevis; L. E. Larson; L. de Vreede;
    IEEE Transactions on Microwave Theory and Techniques,
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  124. Improved RF Devices for Future Adaptive Wireless Systems Using Two-Sided Contacting and AlN Cooling
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  125. Improved RF Devices for Future Adaptive Wireless Systems Using Two-Sided Contacting and AlN Cooling
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  126. A 90-W Peak Power GaN Outphasing Amplifier With Optimum Input Signal Conditioning
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    Volume 57, Issue 8, pp. 1925-1935, 2009. DOI: 10.1109/TMTT.2009.2025430

  127. Ultra Linear Low-Loss Varactor Diode Configurations for Adaptive RF Systems
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    Volume 57, Issue 1, pp. 205-215, 2009. DOI: 10.1109/TMTT.2008.2008978

  128. A 19GHz, 250pJ/bit non-linear BPSK demodulator in 90nm CMOS
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  129. A mixed-signal approach for high-speed fully controlled multidimensional load-pull parameters sweep
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  130. Active scan-beam reflectarray antenna loaded with tunable capacitor
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  131. Enabling low-distortion varactors for adaptive transmitters
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  132. A 67 dBm OIP3 Multistacked Junction Varactor
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    IEEE Microwave and Wireless Components Letters,
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  133. Active Harmonic Load–Pull With Realistic Wideband Communications Signals
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  134. A 67 dBm $OIP_3$ Multistacked Junction Varactor
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  135. A High-Efficiency 100-W GaN Three-Way Doherty Amplifier for Base-Station Applications
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  136. Enabling Low-Distortion Varactors for Adaptive Transmitters
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  137. 50 GHz Integrated Distributed Phase Shifter based on novel Silicon-on-Glass Varactor Diodes
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  138. RF/Microwave Device Fabrication in Silicon-on-Glass Technology
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  139. Special RF/Microwave Devices in Silicon-on-Glass Technology
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  140. Special RF/microwave devices in Silicon-on-Glass Technology
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  141. A highly efficient chireix amplifier using adaptive power combining
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  142. A low-distortion, low-loss varactor phase-shifter based on a silicon-on-glass technology
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  143. RF/microwave device fabrication in silicon-on-glass technology
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  144. 50 GHz Integrated Distributed Phase Shifter Based on Novel Silicon-on-Glass Varactor Diodes
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  145. A Monolithic Low-Distortion Low-Loss Silicon-on-Glass Varactor-Tuned Filter With Optimized Biasing
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    IEEE Microwave and Wireless Components Letters,
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  146. A Mixed-Signal Approach Towards Linear and Efficient $N$-Way Doherty Amplifiers
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    Volume 55, Issue 5, pp. 866-879, 2007. DOI: 10.1109/TMTT.2007.895160

  147. A Monolithic Low-Distortion Low-Loss Silicon-on-Glass Varactor-Tuned Filter With Optimized Biasing
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  148. Varactor Topologies for RF Adaptivity with Improved Power Handling and Linearity
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  149. A Low-Loss Compact Linear Varactor Based Phase-Shifter
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  150. A low-cost pulsed RF I-V measurement setup for isothermal device characterization
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  151. A Low-Loss Compact Linear Varactor Based Phase-Shifter
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  152. Varactor Topologies for RF Adaptivity with Improved Power Handling and Linearity
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  153. Varactor element and low distortion varactor circuit arrangement
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  154. Adaptive Multi-Band Multi-mode power amplifier using integrated varactor-based tunable matching networks
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  155. Active Harmonic Load–Pull for On-Wafer Out-of-Band Device Linearity Optimization
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  156. Silicon-on-glass technology for RF and microwave device fabrication
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  157. A pulsed network analyzer for high dynamic range isothermal measurements
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  158. Silicon-on-glass technology for RF and microwave device fabrication
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  159. A 5.5-GHz Power Amplifier For Wide Bandwidth Polar Modulator
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  160. "Linearization Techniques at the Device and Circuit Level" (Invited)
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  161. Surface-passivated high-resistivity silicon as a true microwave substrate
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  162. Surface-passivated high-resistivity silicon as a true microwave substrate
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  163. High-Performance Varactor Diodes Integrated in a Silicon-on-Glass Technology
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  164. Low-distortion, low-loss varactor-based adaptive matching networks, implemented in a silicon-on-glass technology
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  165. Distortion-free varactor diode topologies for RF adaptivity
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  166. Improved hybrid SiGe HBT class-AB power amplifier efficiency using varactor-based tunable matching networks
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  167. “Distortion-Free” Varactor Diode Topologies for RF Adaptivity
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  168. Improved hybrid SiGe HBT class-AB power amplifier efficiency using varactor-based tunable matching networks
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  169. Experimental procedure to optimize out-of-band terminations for highly linear and power efficient bipolar class-AB RF amplifiers
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  170. High-performance varactor diodes integrated in a silicon-on-glass technology
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  171. Low-distortion, low-loss varactor-based adaptive matching networks, implemented in a silicon-on-glass technology
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  172. On the design of unilateral dual-loop feedback low-noise amplifiers with simultaneous noise, impedance, and IIP3 match
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  173. The Electro-Thermal Smoothie Database Model for LDMOS Devices
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  174. A New Extraction Technique for the Series Resistances of Semiconductor Devices Based on the Intrinsic Properties of Bias-Dependent Y-Parameters
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  175. Design and Characterization of a High-Resistivity Silicon Traveling Wave Amplifier for 10 Gb/s Optical Communucation Systems
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  176. Large signal verification of the circuit-oriented smoothie database model for LDMOS devices
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  177. A technique to linearize LDMOS power amplifiers based on derivative superposition and out-of-band impedance optimization
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  178. Design and characterization of a high-resistivity silicon traveling wave amplifier for 10 Gb/s optical communication systems
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  179. Base-band impedance control and calibration for on-wafer linearity measurements
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  180. A new extraction technique for the series resistances of semiconductor devices based on the intrinsic properties of bias-dependent y-parameters [bipolar transistor examples]
    Cuoco, V.; Neo, W.C.E.; de Vreede, L.C.N.; de Graaff, H.C.; Nanver, L.K.; Buisman, K.; Wu, H.C.; Jos, H.F.F.; Burghartz, J.N.;
    In Bipolar/BiCMOS Circuits and Technology, 2004. Proceedings of the 2004 Meeting,
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  181. On the optimum biasing and input out-of-band terminations of linear and power efficient class-AB bipolar RF amplifiers
    van der Heijden, M.P.; Spirito, M.; Pelk, M.; de Vreede, L.C.N.; Burghartz, J.N.;
    In Bipolar/BiCMOS Circuits and Technology, 2004. Proceedings of the 2004 Meeting,
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  182. The electro-thermal Smoothie database model for LDMOS devices
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    In Proceedings of the 30th European Solid-State Circuits Conference (IEEE Cat. No.04EX850),
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  183. A novel active harmonic load-pull setup for on-wafer device linearity characterization
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  184. Power amplifier PAE and ruggedness optimization by second-harmonic control
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  185. Power amplifier PAE and ruggedness optimization by second-harmonic control
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  186. A Wideband Distributed Silicon Driver for 10 Gb/s External Modulators
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  187. Low-loss passives for 2nd-harmonic termination control in power amplifiers for mobile applications
    M. Spirito; L.C.N. de Vreede; L.K. Nanver; J. Mueller; J.N. Burghartz;
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  188. A 2 GHz high-gain differential InGaP HBT driver amplifier matched for high IP3
    M.P. van der Heijden; M. Spirito; L.C.N. de Vreede; F. van Straten; J.N. Burghartz;
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  189. A Calibration Procedure for On-Wafer Differential Load-Pull Measurements
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  190. Design and characterization of integrated passive elements on high ohmic silicon
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  191. A High Performance Unilateral 900 MHz LNA with Simultaneous Noise, Impedance, and IP3 Match
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  192. A calibration procedure for on-wafer differential load-pull measurements
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  193. A 2 GHz high-gain differential InGaP HBT driver amplifier matched for high IP3
    van der Heijden, M.P.; Spirito, M.; de Vreede, L.C.N.; van Straten, F.; Burghartz, J.N.;
    In IEEE MTT-S International Microwave Symposium Digest, 2003,
    pp. 235-238 vol.1, 2003. DOI: 10.1109/MWSYM.2003.1210923

  194. Design and characterization of integrated passive elements on high ohmic silicon
    Valletta, E.; Van Beek, J.; Den Dekker, A.; Pulsford, N.; Jos, H.F.F.; de Vreede, L.C.N.; Nanver, L.K.; Burghartz, J.N.;
    In IEEE MTT-S International Microwave Symposium Digest, 2003,
    pp. 1235-1238 vol.2, 2003. DOI: 10.1109/MWSYM.2003.1212592

  195. Low-loss passives for 2nd-harmonic termination control in power amplifiers for mobile applications
    Spirito, M.; de Vreede, L.C.N.; Nanver, L.K.; Mueller, J.E.; Burghartz, J.N.;
    In 2003 Topical Meeting on Silicon Monolithic Integrated Circuits in RF Systems, 2003. Digest of Papers.,
    pp. 49-52, 2003. DOI: 10.1109/SMIC.2003.1196666

  196. Theory and design of an ultra-linear square-law approximated LDMOS power amplifier in class-AB operation
    M.P van der Heijden; H.C. de Graaff; L.C.N. de Vreede; J.R. Gajadharsing; J.N. Burghartz;
    IEEE Trans. Microwave Theory and Techniques,
    Volume 50, Issue 9, pp. 2176-2184, Sep. 2002.

  197. A novel frequency-independent third-order intermodulation distortion cancellation technique for BJT amplifiers
    M.P. van der Heijden; H.C. de Graaff; L.C.N. de Vreede;
    IEEE Journal of Solid-State Circuits,
    Volume 37, Issue 9, pp. 1176-1183, Sep. 2002. ISSN 0018-9200.

  198. A novel frequency-independent third-order intermodulation distortion cancellation technique for BJT amplifiers
    van der Heijden, M.P.; de Graaff, H.C.; de Vreede, L.C.N.;
    IEEE Journal of Solid-State Circuits,
    Volume 37, Issue 9, pp. 1176-1183, 2002. DOI: 10.1109/JSSC.2002.801198

  199. Theory and design of an ultra-linear square-law approximated LDMOS power amplifier in class-AB operation
    van der Heijden, M.P.; de Graaff, H.C.; de Vreede, L.C.N.; Gajadharsing, J.R.; Burghartz, J.N.;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 50, Issue 9, pp. 2176-2184, 2002. DOI: 10.1109/TMTT.2002.802332

  200. A 1.8 GHz Integrated LNA using a Novel RF Si Technology
    F.M. De Paola; L.C.N. de Vreede; L. Nanver; B. Rejaei; N. Rinaldi; J.N. Burghartz;
    In Proc. SAFE 2002,
    Veldhoven, The Netherlands, STW, pp. 30-34, Nov. 2002. ISBN 90-73461-33-2.

  201. Verification of the IMD Behavior of the Smoothie Database Model for FET Devices
    V. Cuoco; M.P. van der Heijden; M. Pelk; L.C.N. de Vreede;
    In Proc. SAFE 2002,
    Veldhoven, The Netherlands, STW, pp. 14-21, Nov. 2002. ISBN 90-73461-33-2.

  202. Power Amplifier Optimization for Mobile Application by Second Harmonic Control
    M. Spirito; L.N.C. de Vreede; L.K. Nanver; S. Weber; J.N. Burghartz;
    In Proc. ProRISC 2002,
    Veldhoven, The Netherlands, pp. 471-475, Nov. 2002.

  203. Design of Planar Mar.and Balun for MMIC Applications
    E. Valletta; L.C.N. de Vreede; J.N. Burghartz;
    In Proc. SAFE 2002,
    Veldhoven, The Netherlands, STW, Nov. 2002. ISBN 90-73461-33-2.

  204. The Effect on Non-Saturated Electron Drift Velocity on Bipolar Device Linearity
    L.C.N. de Vreede; H.C. de Graaff; B. Rejeai;
    In Proc. 2002 IEEE BCTM,
    Monterey, CA, USA, pp. 88-91, Sep. 2002. ISBN 0-7803-7562-9.

  205. Power Amplifier PAE and Ruggedness Optimization by Second Harmonic Control
    M. Spirito; L.C.N. de Vreede; L.K. Nanver; S. Weber; J.N. Burghartz;
    In Proc. 2002 IEEE BCTM,
    Monterey, CA, USA, pp. 173-176, Sept. 2002. ISBN 0-7803-7562-9.

  206. Experimental Verification of the Smoothie Database Model for Third and Fifth Order Intermodulation Distortion
    V. Cuoco; M.P. van d. Heijden; M. Pelk; L.C.N. de Vreede;
    In ESSDERC 2002,
    Firenze, Italy, University of Bologna, pp. 635-638, Sep. 2002. ISBN 88-900847-8-2.

  207. Implementation of an isothermal non-linear device characterization system using the ICCAP program
    V. Cuoco; M. Pelk; M.P. van d. Heijden; M. de Kok; L.N.C. de Vreede;
    In European IC-CAP Workhop,
    Berlin, Germany, Mar. 2002.

  208. The smoothie data base model for the correct modeling of non-linear distortion in FET devices
    V. Cuoco; M.P. van d. Heijden; L.C.N. de Vreede;
    In 2002 IEEE MTT-S International Microwave Symposium,
    Seattle, USA, pp. 2149-2152, Jun. 2002. ISBN 0-7803-7239-5.

  209. Experimental Verification of the Smoothie Database Model for Third and Fifth Order Intermodulation Distortion
    Cuoco, V.; van de Heijden, M.P.; Pelk, M.; de Vreede, L.C.N.;
    In 32nd European Solid-State Device Research Conference,
    pp. 635-638, 2002. DOI: 10.1109/ESSDERC.2002.195011

  210. Power amplifier PAE and ruggedness optimization by second harmonic control
    Spirito, M.; de Vreede, L.C.N.; Nanver, L.K.; Weber, S.; Burghartz, J.N.;
    In Proceedings of the Bipolar/BiCMOS Circuits and Technology Meeting,
    pp. 173-176, 2002. DOI: 10.1109/BIPOL.2002.1042911

  211. The effect of non-saturated electron drift velocity on bipolar device linearity
    de Vreede, L.C.N.; de Graaff, H.C.; Rejeai, B.;
    In Proceedings of the Bipolar/BiCMOS Circuits and Technology Meeting,
    pp. 88-91, 2002. DOI: 10.1109/BIPOL.2002.1042893

  212. The "Smoothie" data base model for the correct modeling of non-linear distortion in FET devices
    Cuoco, V.; van den Heijden, M.P.; de Vreede, L.C.N.;
    In 2002 IEEE MTT-S International Microwave Symposium Digest (Cat. No.02CH37278),
    pp. 2149-2152 vol.3, 2002. DOI: 10.1109/MWSYM.2002.1012296

  213. Introduction to the 2000 bipolar/BiCMOS circuits and technology meeting
    L.C.N. de Vreede;
    IEEE J. Solid-State Circuits,
    Volume 36, Issue 9, pp. 1371-1372, Sept. 2001.

  214. Reduction of UHF power transistor distortion with a nonuniform collector doping profile
    W.D. van Noort; H.F.F. Jos; L.C.N. de Vreede; L.K. Nanver; J.W. Slotboom;
    IEEE Journal of Solid-State Circuits,
    Volume 36, Issue 9, pp. 1399-1406, Sept. 2001.

  215. Reduction of UHF power transistor distortion with a nonuniform collector doping profile
    van Noort, W.D.; de Vreede, L.C.N.; Jos, H.F.F.; Nanver, L.K.; Slotboom, J.W.;
    IEEE Journal of Solid-State Circuits,
    Volume 36, Issue 9, pp. 1399-1406, 2001. DOI: 10.1109/4.944669

  216. Introduction to the 2000 Bipolar/BiCMOS Circuits and Technology Meeting
    de Vreede, L.C.N.;
    IEEE Journal of Solid-State Circuits,
    Volume 36, Issue 9, pp. 1371-1372, 2001. DOI: 10.1109/JSSC.2001.944665

  217. Linearity optimization of a distributed base station amplifier using an automated high-speed measurement protocol
    M.P. van der Heijden; J.R. Gajadharsing; B. Rejaei; L.C.N. de Vreede;
    In B. Sigmon (Ed.), 2001 IEEE MTT-S International Microwave Symposium,
    Phoenix, AZ, USA, pp. 1679-1682, May 2001. ISBN: 0-7803-6538-0.
    document

  218. Power Amplifier PAE and Ruggedness Optimization by Second Harmonic Control
    M. Spirito; L.N.C. de Vreede; L.K. Nanver; S. Weber; J.N. Burghartz;
    In ProRISC 2001,
    Veldhoven, The Netherlands, pp. 623-629, Nov. 2001.
    document

  219. A Single Chip 1.8 GHz LNA and Power Amplifier with Improved Isolation Using Micromachining
    F.M. De Paola; L.C.N de Vreede; L.K. Nanver; B. Rajaei; N.P. Pham; N. Rinaldi; J.N. Burghartz;
    In SAFE 2001,
    Veldhoven, The Netherlands, pp. 35-41, Nov. 2001.

  220. Isothermal Non-Linear Device Characterization
    V. Cuoco; M. de Kok; M.P. van d. Heijden; L.C.N. de Vreede;
    In ProRISC 2001,
    Veldhoven, The Netherlands, pp. 338-341, Nov. 2001.
    document

  221. A novel frequency independent third-order intermodulation distortion cancellation technique for BJT amplifiers
    M.P. van der Heijden; H.C. de Graaff.; L.C.N. de Vreede;
    In Proceedings of the 2001 Bipolar/BiCMOS Circuits and Technology Meeting,
    Minneapolis, MN, USA, pp. 163-166, Sept. 2001. ISBN 0-7803-7019-8.
    document

  222. Isothermal Large Signal Device Characterization
    V. Cuoco; M. de Kok; M.P. van d. Heijden; L.C.N. de Vreede;
    In ARFTG Conference,
    San Diego, Nov. 2001.

  223. Isothermal Non-Linear Device Characterization
    Cuoco, V.; de Kok, M.; Heijden, M.P.v.d.; de Vreede, L.C.N.;
    In 58th ARFTG Conference Digest,
    pp. 1-4, 2001. DOI: 10.1109/ARFTG.2001.327493

  224. A novel frequency independent third-order intermodulation distortion cancellation technique for BJT amplifiers
    van der Heijden, M.P.; de Graaff, H.C.; de Vreede, L.C.N.;
    In Proceedings of the 2001 BIPOLAR/BiCMOS Circuits and Technology Meeting (Cat. No.01CH37212),
    pp. 163-166, 2001. DOI: 10.1109/BIPOL.2001.957882

  225. Linearity optimization of a distributed base station amplifier using an automated high-speed measurement protocol
    van der Heijden, M.P.; Gajadharsing, J.R.; Rejaei, B.; de Vreede, L.C.N.;
    In 2001 IEEE MTT-S International Microwave Sympsoium Digest (Cat. No.01CH37157),
    pp. 1679-1682 vol.3, 2001. DOI: 10.1109/MWSYM.2001.967228

  226. Ultra-linear distributed class-AB LDMOS RF power amplifier for base stations
    van der Heijden, M.P.; de Graaff, H.C.; de Vreede, L.C.N.; Gajadharsing, J.R.; Burghartz, J.N.;
    In 2001 IEEE MTT-S International Microwave Sympsoium Digest (Cat. No.01CH37157),
    pp. 1363-1366 vol.2, 2001. DOI: 10.1109/MWSYM.2001.967149

  227. Direct Mextram Parameter Computation Based on Transistor Layout and Doping Profile
    D. di Crescenzo; N. Rinaldi; H.C. de Graaff; L.C.N. de Vreede;
    In SAFE 2000,
    pp. 37-42, 2000.

  228. A High Speed Measurement Protocol for Optimizing Amplifier Linearity
    M. van der Heijden; L.C.N. de Vreede;
    In PRORISC 2000,
    pp. 307-310, 2000.

  229. Reduction of distorsion with a non-uniform BJT collector doping profile
    W.D. van Noort; L.C.N. de Vreede; H.F.F. Jos; L.K. Nanver; J.W. Slotboom;
    In Proceedings SAFE 2000,
    Veldhoven, pp. 113-118, 2000.

  230. Reduction of UHF power distortion with a non-uniform collector doping profile
    W.D. van Noort; H.F.F. Jos; L.C.N. de Vreede; L.K. Nanver; J.W. Slotboom;
    In Proceedings of the 2000 BCTM,
    Minneapolis, Minnesota, Sept 24-26, 2000, pp. 126-129, 2000. ISBN 0-7803-6384-1/-X/-8.

  231. A Mixed Level Simulator for the Large Signal Optimization of LDMOS Devices
    V. Cuoco; M.P. van der Heijden; S. Mijalkovic; N. Rinaldi; H.C. de Graaff; L.C.N. de Vreede;
    In Proc. 3rd Workshop on Semiconductor Advances for Future Electronics,
    Veldhoven, pp. 42-47, 2000.

  232. Modelling and Characterization of HF Large-signal Device Operation
    L.C.N. de Vreede;
    In Europractice workshop High Speed Devices and Circuits for Analog Applications Beyond 3 GHz,
    Germany, Feb. 2000.

  233. Bipolar transistor epilayer design using the MAIDS mixed-level simulator
    L.C.N. de Vreede; H.C. de Graaff; Willemen; J.A.; W. van Noort; Jos; R.; Larson; L.E.; J.W. Slotboom; J.L. Tauritz;
    IEEE J. Solid-State Circuits,
    Volume 34, Issue 9, pp. 1331-1338, Sept. 1999.

  234. Bipolar transistor epilayer design using the MAIDS mixed-level simulator
    de Vreede, L.C.N.; de Graaff, H.C.; Willemen, J.A.; van Noort, W.; Jos, R.; Larson, L.E.; Slotboom, J.W.; Tauritz, J.L.;
    IEEE Journal of Solid-State Circuits,
    Volume 34, Issue 9, pp. 1331-1338, 1999. DOI: 10.1109/4.782094

  235. The impact of silicon MMICs on system designs
    L.E. Larson; L.C.N. de Vreede;
    In 29th European Microwave Conference 1999,
    Munich, pp. 166-169, Oct. 1999.

  236. The Impact of Silicon Technology on Future Microwave Systems
    Larson, Lawrence E.; de Vreede, Leo C.N.;
    In 1999 29th European Microwave Conference,
    pp. 166-169, 1999. DOI: 10.1109/EUMA.1999.338299

  237. Extension of the collector charge description for compact bipolar epilayer models
    L.C.N. de Vreede; H.C. de Graaff; J.L. Tauritz; Baets; R.G.F;
    IEEE Tr. Electron Devices,
    Volume 45, Issue 1, pp. 277-285, Jan. 1998.

  238. Extension of the collector charge description for compact bipolar epilayer models
    de Vreede, L.C.N.; de Graaff, H.C.; Tauritz, J.L.; Baets, R.G.F.;
    IEEE Transactions on Electron Devices,
    Volume 45, Issue 1, pp. 277-285, 1998. DOI: 10.1109/16.658842

  239. Impact of CDMA Specifications on Circuit Design
    R. Mahmoudi; H.C. de Graaff; L.C.N. de Vreede; J.L. Tauritz;
    In Workshop on Low Cost Si-based Technology for Wireless Applications IEEE RFIC Symposium,
    Baltimore, Jun. 1998.

  240. 1.8 GHz Active Microwave Filter realized in SiGe for Mobile Communications
    M.J.M. Martinez; L.C.N. de Vreede; J.L. Tauritz;
    In Proceedings of XIII Conference on Design of Circuits and Integrated Systems (DCIS'98),
    Madrid, Nov. 1998.

  241. Optimisation of the base-collector doping profile for high-frequency distortion
    W. van Noort; L.C.N. de Vreede; L.K. Nanver; H.C. de Graaff; J.W. Slotboom;
    In Proc. 28th ESSDERC,
    France, pp. 496-499, Sep. 1998.

  242. Active Microwave Filters realized in SiGe Technology
    M.J.M. Martinez; L.C.N. de Vreede; J.L. Tauritz;
    In MTT-S European Wireless 98,
    Amsterdam, pp. 110-115, Oct. 1998.

  243. Performance of MEXTRAM and its Comparison with VBIC 95
    H.C. de Graaff; W.J. Kloosterman; L.C.N. de Vreede;
    In Hewlett-Packard SCCT Modelling Seminar,
    Tokyo, May 1998.

  244. Optimum dimensions of the epilayer for third-order intermodulation distortion
    L.C.N. de Vreede; W. van Noort; H.F.F. Jos; H.C. de Graaff; J.W. Slotboom; J.L. Tauritz;
    In Proc. Bipolar/BiCMOS Circuits and Technology Meeting,
    pp. 168-171, Sept. 1998.

  245. Optimisation of the base-collector doping profile for high-frequency distortion
    van Noort, W.; de Vreede, L.C.N.; Nanver, L.K.; de Graaff, H.C.; Slotboom, J.W.;
    In 28th European Solid-State Device Research Conference,
    pp. 496-499, 1998.

  246. Optimum dimensions of the epilayer for third-order intermodulation distortion
    de Vreede, L.C.N.; van Noort, W.; Jos, H.F.F.; de Graaff, H.C.; Slotboom, J.W.; Tauritz, J.L.;
    In Proceedings of the 1998 Bipolar/BiCMOS Circuits and Technology Meeting (Cat. No.98CH36198),
    pp. 168-171, 1998. DOI: 10.1109/BIPOL.1998.741916

  247. MAIDS: A microwave active integral device simulator
    L. de Vreede; W. van Noort; H.C. de Graaff; J.L. Tauritz; J. Slotboom;
    In Proceedings of the 27th ESSDERC,
    Stuttgart, Germany, pp. 108-111, Sept. 1997.

  248. MAIDS: A Microwave Active Integral Device Simulator
    de Vreede, L.C.N.; Noort, W.V.; de Graaff, H.C.; Tauritz, J.L.; Slotboom, J.;
    In 27th European Solid-State Device Research Conference,
    pp. 180-183, 1997. DOI: 10.1109/ESSDERC.1997.194395

  249. Advanced modeling of distortion effects in bipolar transistors using the Mextram model
    L.C.N. de Vreede; H.C. de Graaff; Mouthaan; K.; de Kok; M.; J.L. Tauritz; Baets; R.G.F;
    J. Solid-State Circuits,
    Volume 31, Issue 1, pp. 114-121, Jan. 1996.

  250. Plasma_enhanced chemical vapor deposition of thick silicon nitride films with low stress on InP
    L. Shi; C. A. M. Steenbergen; A. H. de Vreede; M. K. Smit; T. L. M. Scholtes; F. H. Groen; J. W. Pedersen;
    J. Vac. Sci. Technol. A,
    Volume 14, pp. 471, 1996.

  251. System performance of a 4-channel PHASAR WDM receiver operating at 1.2 Gbit/s
    C.A.M. Steenbergen; M.O. van Deventer; L.C.N. de Vreede; C. van Dam; M.K. Smit; B.H. Verbeek;
    In Proc. OFC 1996,
    San Jose, CA, USA, pp. 310-311, Feb. 1996.

  252. System performance of a 4-channel PHASAR WDM receiver operating at 1.2 Gbit/s
    Steenbergen, C.A.M.; van Deventer, M.O.; de Vreede, L.C.N.; van Dam, C.; Smit, M.K.; Verbeek, B.H.;
    In Optical Fiber Communications, OFC.,
    pp. 310-311, 1996. DOI: 10.1109/OFC.1996.908319

  253. HF Silicon ICs for Wide-band Communication Systems
    L.C.N. de Vreede;
    PhD thesis, Delft University of Technology, Jun 1996.
    document

  254. 4-channel wavelength flattened demultiplexer integrated with photodetectors
    C. A. M. Steenbergen; C van Dam; T. L. M. Scholtes; A. H. de Vreede; L. Shi; J.J.G.M van der Tol; P. Demeester; M.K. Smit;
    In Proc. 7th Eur. Conf. on Int. Opt. (ECIO �95),
    1995.

  255. Integrated 1 GHz 4-channel InP phasar based WDM-receiver with Si bipolar frontend array
    C.A.M. Steenbergen; L.C.N. de Vreede; C. van Dam; T.L.M. Scholtes; M.K. Smit; J.L. Tauritz; J.W. Pedersen; I. Moerman; B.H. Verbeek; R.G.F. Baets;
    In Proc. ECOC 1995,
    Brussels, Belgium, pp. 211-214, Sept. 1995.

  256. CAD-tool for integrated optics
    X.J.M. Leijtens; L.H. Spiekman; C. van Dam; L.C.N. de Vreede; M.K. Smit; J.L. Tauritz;
    In Proc. ECIO 1995,
    Delft, The Netherlands, pp. 463-466, Apr. 1995.

  257. Extension of the collector charge description for compact bipolar epilayer models
    L.C.N. de Vreede; H.C. de Graaff; J.L. Tauritz; R.G.F. Baets;
    In Proc. ESSDERC 1995,
    The Hague, The Netherlands, pp. 229-232, Sep. 1995.

  258. Extension of the collector charge description for compact bipolar epilayer models
    de Vreede, L.C.N.; de Graaff, H.C.; Tauritz, J.L.; Baets, R.G.F.;
    In ESSDERC '95: Proceedings of the 25th European Solid State Device Research Conference,
    pp. 63-66, 1995.

  259. A high gain silicon AGC amplifier with a 3 dB bandwidth of 4 GHz
    L.C.N. de Vreede; A.C. Dambrine; J.L. Tauritz; R.G.F. Baets;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 42, Issue 4, pp. 546-552, Apr. 1994.

  260. A figure of merit for the high-frequency noise behavior of bipolar transistors
    L.C.N. de Vreede; H.C. de Graaff; G.A.M. Hurkx; J.L. Tauritz; R.G.F. Baets;
    IEEE Journal of Solid State Circuits,
    Volume 29, Issue 10, pp. 1220-1226, Oct. 1994.

  261. A figure of merit for the high-frequency noise behavior of bipolar transistors
    de Vreede, L.C.N.; de Graaff, H.C.; Hurkx, G.A.M.; Tauritz, J.L.; Baets, R.G.F.;
    IEEE Journal of Solid-State Circuits,
    Volume 29, Issue 10, pp. 1220-1226, 1994. DOI: 10.1109/4.315206

  262. A high gain silicon AGC amplifier with a 3 dB bandwidth of 4 GHz
    de Vreede, L.C.N.; Dambrine, A.C.; Tauritz, J.L.; Baets, R.G.F.;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 42, Issue 4, pp. 546-552, 1994. DOI: 10.1109/22.285058

  263. Advanced modelling of distortion effects in bipolar transistors using the Mextram model
    L.C.N. de Vreede; H.C. de Graaff; K. Mouthaan; M. de Kok; J.L. Tauritz; R.G.F. Baets;
    In Proc. IEEE Bipolar/BiCMOS Circuits and Technology Meeting (BCTM 1994),
    Minneapolis, MN, USA, pp. 48-51, Oct. 1994.

  264. Advanced modelling of distortion effects in bipolar transistors using the Mextram model
    de Vreede, L.C.N.; de Graaff, H.C.; Mouthaan, K.; de Kok, M.; Tauritz, J.L.; Baets, R.G.F.;
    In Proceedings of IEEE Bipolar/BiCMOS Circuits and Technology Meeting,
    pp. 48-51, 1994. DOI: 10.1109/BIPOL.1994.587854

  265. A figure of merit for the high-frequency noise behaviour of bipolar transistors
    H.C. de Graaff; L.C.N. de Vreede; G.A.M. Hurkx; J.L. Tauritz; R.G.F. Baets;
    In Proc. 1993 IEEE BCTM,
    Minneapolis, USA, pp. 118-121, Oct. 1993.

  266. A high frequency model based on the physical structure of the ceramic multilayer capacitor
    de Vreede, L.C.N.; de Kok, M.; van Dam, C.; Tauritz, J.L.;
    IEEE Transactions on Microwave Theory and Techniques,
    Volume 40, Issue 7, pp. 1584-1587, 1992. DOI: 10.1109/22.146342

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