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2020 – today
- 2023
[c31]Dongyang Yan, Yang Zhang, Dries Peumans
, Mark Ingels, Piet Wambacq:
A 33 dBm, >30% PAE GaN Power Amplifier Based on a Sub-Quarter-Wavelength Balun for 5G Applications. BCICTS 2023: 70-73- [c30]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 - [c29]Dongyang Yan, Sehoon Park, Yang Zhang, Mark Ingels, Piet Wambacq:
A Compact K-band, Asymmetric Coupler-based, Switchless Transmit-Receive Front-End in 0.15μm GaN-on-SiC Technology. ESSCIRC 2023: 457-460 - [c28]Dongyang Yan, Yang Zhang, Mark Ingels, Piet Wambacq:
A 0.13μm GaAs HEMT Reconfigurable Balance-to-Doherty Stacked Power Amplifier for 5G mm-wave Applications. PRIME 2023: 1-4 - 2022
- [c27]Emilio Calvanese Strinati, Michaël Peeters, César Roda Neve, Manil Dev Gomony, Andreia Cathelin, Mauro Renato Boldi, Mark Ingels, Aritra Banerjee, Pascal Chevalier, Bartek Kozicki, Didier Belot:
The Hardware Foundation of 6G: The NEW-6G Approach. EuCNC 2022: 423-428 - 2020
- [c26]Claude Desset, Piet Wambacq, Yang Zhang, Mark Ingels, André Bourdoux:
A flexible power model for mm-wave and THz high-throughput communication systems. PIMRC 2020: 1-6
2010 – 2019
- 2019
- [c25]Dongyang Yan, Mark Ingels, Giovanni Mangraviti, Yao Liu, Bertrand Parvais, Niamh Waldron, Nadine Collaert, Piet Wambacq:
Design of a 28 GHz differential GaAs power amplifier with capacitive neutralization for 5G mmwave applications. NEWCAS 2019: 1-4 - 2017
- [c24]Saurabh Agarwal, Mark Ingels, Marianna Pantouvaki, Michiel Steyaert, Philippe Absil, Joris Van Campenhout:
Highly integrated wavelength-locked Si photonic ring transmitter using direct monitoring of drop-port OMA. ESSCIRC 2017: 111-114 - [c23]Mark Ingels, Davide Dermit, Yao Liu, Hans Cappelle, Jan Craninckx:
A 2×14bit digital transmitter with memoryless current unit cells and integrated AM/PM calibration. ESSCIRC 2017: 324-327 - 2016
- [j12]Khaled Khalaf, Vojkan Vidojkovic, Kristof Vaesen, Michael Libois, Giovanni Mangraviti, Viki Szortyka, Chunshu Li, Bob Verbruggen, Mark Ingels, André Bourdoux, Charlotte Soens, Wim Van Thillo, John R. Long, Piet Wambacq:
Digitally Modulated CMOS Polar Transmitters for Highly-Efficient mm-Wave Wireless Communication. IEEE J. Solid State Circuits 51(7): 1579-1592 (2016) - [j11]Saurabh Agarwal, Mark Ingels, Marianna Pantouvaki, Michiel Steyaert, Philippe Absil, Joris Van Campenhout:
Wavelength Locking of a Si Ring Modulator Using an Integrated Drop-Port OMA Monitoring Circuit. IEEE J. Solid State Circuits 51(10): 2328-2344 (2016) - [c22]Pedro Emiliano Paro Filho, Mark Ingels, Piet Wambacq, Jan Craninckx:
13.7 A 0.22mm2 CMOS resistive charge-based direct-launch digital transmitter with -159dBc/Hz out-of-band noise. ISSCC 2016: 250-252 - [c21]Saurabh Agarwal, Mark Ingels, Michal Rakowski, Marianna Pantouvaki, Michiel Steyaert, Philippe Absil, Joris Van Campenhout:
Wavelength locking of a Si photonic ring transmitter using a dithering-based OMA stabilizing feedback loop. OFC 2016: 1-3 - 2015
- [j10]Pedro Emiliano Paro Filho, Mark Ingels, Piet Wambacq, Jan Craninckx:
An Incremental-Charge-Based Digital Transmitter With Built-in Filtering. IEEE J. Solid State Circuits 50(12): 3065-3076 (2015) - [j9]Chunshu Li, Min Li, Marian Verhelst, André Bourdoux, Mark Ingels, Liesbet Van der Perre, Sofie Pollin:
Efficient Timing Mismatch Correction for Low-Cost Digital-Mixing Transmitter. IEEE Trans. Signal Process. 63(24): 6553-6564 (2015) - [j8]Chunshu Li, Min Li, Khaled Khalaf, André Bourdoux, Marian Verhelst, Mark Ingels, Piet Wambacq, Jan Craninckx, Liesbet Van der Perre, Sofie Pollin:
Opportunities and Challenges of Digital Signal Processing in Deeply Technology-Scaled Transceivers. J. Signal Process. Syst. 78(1): 5-19 (2015) - [c20]Saurabh Agarwal, Mark Ingels, Michal Rakowski, Marianna Pantouvaki, Michiel Steyaert, Philippe P. Absil, Joris Van Campenhout:
Wavelength locking of a Si ring modulator using an integrated drop-port OMA monitoring circuit. A-SSCC 2015: 1-4 - [c19]Pedro Emiliano Paro Filho, Mark Ingels, Piet Wambacq, Jan Craninckx:
9.3 A transmitter with 10b 128MS/S incremental-charge-based DAC achieving -155dBc/Hz out-of-band noise. ISSCC 2015: 1-3 - [c18]Michal Rakowski, Marianna Pantouvaki, Peter De Heyn, Peter Verheyen, Mark Ingels, Hongtao Chen, Jeroen De Coster, Guy Lepage, Brad Snyder, Kristin De Meyer, Michiel Steyaert, Nicola Pavarelli, Jun Su Lee, Peter O'Brien, Philippe P. Absil, Joris Van Campenhout:
22.5 A 4×20Gb/s WDM ring-based hybrid CMOS silicon photonics transceiver. ISSCC 2015: 1-3 - 2014
- [c17]Saurabh Agarwal, Mark Ingels, Michal Rakowski, Marianna Pantouvaki, Michiel Steyaert, Philippe Absil, Joris Van Campenhout:
Monitoring optical modulation amplitude using a low-power CMOS circuit for thermal control of Si ring transmitters. ECOC 2014: 1-3 - [c16]Mark Ingels, Xiaoqiang Zhang, Kuba Raczkowski, Sungwoo Cha, Pieter Palmers, Jan Craninckx:
A linear 28nm CMOS digital transmitter with 2×12bit up to LO baseband sampling and -58dBc C-IM3. ESSCIRC 2014: 379-382 - [c15]Chunshu Li, Min Li, Mark Ingels, Marian Verhelst, Xiaoqiang Zhang, Joris Van Driessche, André Bourdoux, Liesbet Van der Perre, Sofie Pollin:
Efficient duty-cycle mismatch compensation in digital transmitter. ICASSP 2014: 4998-5002 - 2013
- [j7]Vincenzo Chironi, Björn Debaillie, Stefano D'Amico, Andrea Baschirotto, Jan Craninckx, Mark Ingels:
A Digitally Modulated Class-E Polar Amplifier in 90 nm CMOS. IEEE Trans. Circuits Syst. I Regul. Pap. 60-I(4): 918-925 (2013) - [c14]Mark Ingels, Yoshikazu Furuta, Xiaoqiang Zhang, Sungwoo Cha, Jan Craninckx:
A multiband 40nm CMOS LTE SAW-less modulator with -60dBc C-IM3. ISSCC 2013: 338-339 - [c13]Chunshu Li, Min Li, Mark Ingels, Xiaoqiang Zhang, Marian Verhelst, Sofie Pollin, Joris Van Driessche, André Bourdoux, Liesbet Van der Perre:
Efficient self-correction scheme for static non-idealities in nano-scale quadrature digital RF transmitters. SiPS 2013: 71-76 - [c12]Min Li, Khaled Khalaf, Chunshu Li, Vojkan Vidojkovic, Mark Ingels, André Bourdoux, Piet Wambacq, Jan Craninckx, Liesbet Van der Perre:
Signal processing challenges for emerging digital intensive and digitally assisted transceivers with deeply scaled technology (Invited). SiPS 2013: 324-329 - 2012
- [c11]Wagdy M. Gaber, Piet Wambacq, Jan Craninckx, Mark Ingels:
A CMOS IQ Digital Doherty Transmitter using modulated tuning capacitors. ESSCIRC 2012: 341-344 - 2011
- [j6]Jonathan Borremans, Gunjan Mandal, Vito Giannini, Björn Debaillie, Mark Ingels, Tomohiro Sano, Bob Verbruggen, Jan Craninckx:
A 40 nm CMOS 0.4-6 GHz Receiver Resilient to Out-of-Band Blockers. IEEE J. Solid State Circuits 46(7): 1659-1671 (2011) - [c10]Mark Ingels, Vincenzo Chironi, Björn Debaillie, Andrea Baschirotto, Jan Craninckx:
An impedance modulated class-E polar amplifier in 90 nm CMOS. A-SSCC 2011: 285-288 - [c9]Jan Craninckx, Jonathan Borremans, Mark Ingels:
SAW-less software-defined radio transceivers in 40nm CMOS. CICC 2011: 1-8 - [c8]Wagdy M. Gaber, Piet Wambacq, Jan Craninckx, Mark Ingels:
A CMOS IQ direct digital RF modulator with embedded RF FIR-based quantization noise filter. ESSCIRC 2011: 139-142 - [c7]Jonathan Borremans, Gunjan Mandal, Vito Giannini, Tomohiro Sano, Mark Ingels, Bob Verbruggen, Jan Craninckx:
A 40nm CMOS highly linear 0.4-to-6GHz receiver resilient to 0dBm out-of-band blockers. ISSCC 2011: 62-64 - [c6]Vito Giannini, Mark Ingels, Tomohiro Sano, Björn Debaillie, Jonathan Borremans, Jan Craninckx:
A multiband LTE SAW-less modulator with -160dBc/Hz RX-band noise in 40nm LP CMOS. ISSCC 2011: 374-376 - 2010
- [j5]Mark Ingels, Vito Giannini, Jonathan Borremans, Gunjan Mandal, Björn Debaillie, Peter Van Wesemael, Tomohiro Sano, Takaya Yamamoto, Dries Hauspie, Joris Van Driessche, Jan Craninckx:
A 5 mm2 40 nm LP CMOS Transceiver for a Software-Defined Radio Platform. IEEE J. Solid State Circuits 45(12): 2794-2806 (2010) - [c5]Vincenzo Chironi, Björn Debaillie, Andrea Baschirotto, Jan Craninckx, Mark Ingels:
A compact digital amplitude modulator in 90nm CMOS. DATE 2010: 702-705 - [c4]Vincenzo Chironi, Björn Debaillie, Andrea Baschirotto, Jan Craninckx, Mark Ingels:
An area efficient digital amplitude modulator in 90nm CMOS. ISCAS 2010: 2219-2222 - [c3]Mark Ingels, Vito Giannini, Jonathan Borremans, Gunjan Mandal, Björn Debaillie, Peter Van Wesemael, Tomohiro Sano, Takaya Yamamoto, Dries Hauspie, Joris Van Driessche, Jan Craninckx:
A 5mm2 40nm LP CMOS 0.1-to-3GHz multistandard transceiver. ISSCC 2010: 458-459
2000 – 2009
- 2009
- [j4]Vito Giannini, Pierluigi Nuzzo, Charlotte Soens, Kameswaran Vengattaramane, Julien Ryckaert, Michaël Goffioul, Björn Debaillie, Jonathan Borremans, Joris Van Driessche, Jan Craninckx, Mark Ingels:
A 2-mm2 0.1-5 GHz Software-Defined Radio Receiver in 45-nm Digital CMOS. IEEE J. Solid State Circuits 44(12): 3486-3498 (2009) - [c2]Vito Giannini, Pierluigi Nuzzo, Charlotte Soens, Kameswaran Vengattaramane, Michiel Steyaert, Julien Ryckaert, Michaël Goffioul, Björn Debaillie, Joris Van Driessche, Jan Craninckx, Mark Ingels:
A 2mm2 0.1-to-5GHz SDR receiver in 45nm digital CMOS. ISSCC 2009: 408-409 - 2007
- [c1]Mark Ingels, Charlotte Soens, Jan Craninckx, Vito Giannini, T. Kim, Björn Debaillie, Michael Libois, Michaël Goffioul, Joris Van Driessche:
A CMOS 100 MHz to 6 GHz software defined radio analog front-end with integrated pre-power amplifier. ESSCIRC 2007: 436-439
1990 – 1999
- 1999
- [j3]Mark Ingels, Michel S. J. Steyaert:
A 1-Gb/s, 0.7-μm CM+ OS optical receiver with full rail-to-rail output swing. IEEE J. Solid State Circuits 34(7): 971-977 (1999) - 1997
- [j2]Mark Ingels, Michiel S. J. Steyaert:
Design strategies and decoupling techniques for reducing the effects of electrical interference in mixed-mode IC's. IEEE J. Solid State Circuits 32(7): 1136-1141 (1997) - 1994
- [j1]Mark Ingels, Geert Van der Plas, Jan Crols, Michiel Steyaert:
A CMOS 18 THzΩ 248 Mb/s transimpedance amplifier and 155 Mb/s LED-driver for low cost optical fiber links. IEEE J. Solid State Circuits 29(12): 1552-1559 (1994)
Coauthor Index
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