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Fabio Sebastiano
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2020 – today
- 2024
- [j31]Niels Fakkel
, Mohsen Mortazavi
A Cryo-CMOS DAC-Based 40-Gb/s PAM4 Wireline Transmitter for Quantum Computing. IEEE J. Solid State Circuits 59(5): 1433-1446 (2024) - [j30]Rob A. Damsteegt
A Benchmark of Cryo-CMOS Embedded SRAM/DRAMs in 40-nm CMOS. IEEE J. Solid State Circuits 59(7): 2042-2054 (2024) - [j29]Job van Staveren
Cryo-CMOS Voltage References for the Ultrawide Temperature Range From 300 K Down to 4.2 K. IEEE J. Solid State Circuits 59(9): 2884-2894 (2024) - [j28]Niels Fakkel
A Cryo-CMOS Controller With Class-DE Driver and DC Magnetic-Field Tuning for Quantum Computers Based on Color Centers in Diamond. IEEE J. Solid State Circuits 59(11): 3627-3643 (2024) - [j27]Gerd Kiene
A Cryo-CMOS SAR ADC With FIA Sampling Driver Enabled by Cryogenic-Aware Back-Biasing. IEEE Trans. Circuits Syst. I Regul. Pap. 71(3): 1071-1081 (2024) - [c54]Carmen G. Almudéver, Robert Wille, Fabio Sebastiano, Nadia Haider, Eduard Alarcón:
From Designing Quantum Processors to Large-Scale Quantum Computing Systems. DATE 2024: 1-10 - [c53]Luc Enthoven, Niels Fakkel, Hans Bartling, Margriet van Riggelen, Kai-Niklas Schymik, Jiwon Yun, Eftychia Tsapanou Katranara, René Vollmer, Tim Taminiau, Fabio Sebastiano, Masoud Babaie:
29.2 A Cryo-CMOS Controller with Class-DE Driver and DC Magnetic-Field Tuning for Color-Center-Based Quantum Computers. ISSCC 2024: 472-474 - [c52]Bagas Prabowo, Oriol Pietx-Casas, Mohammad Ali Montazerolghaem, Giordano Scappucci, Lieven M. K. Vandersypen, Fabio Sebastiano, Masoud Babaie:
29.3 A Cryo-CMOS Receiver with 15K Noise Temperature Achieving 9.8dB SNR in 10μs Integration Time for Spin Qubit Readout. ISSCC 2024: 474-476 - [c51]Sander Derksen, Maël Demarets, Gerard Villar Pique, Fabio Sebastiano:
A 0.9V Rail-to-Rail Ultra-Low-Power Fully Integrated Clock Generator Achieving 23fJ/Cycle in 28nm CMOS. VLSI Technology and Circuits 2024: 1-2 - [i3]Luc Enthoven, Masoud Babaie, Fabio Sebastiano:
Optimizing the Electrical Interface for Large-Scale Color-Center Quantum Processors. CoRR abs/2403.09526 (2024) - [i2]Gerd Kiene, Sadik Ilik, Luigi Mastrodomenico, Masoud Babaie, Fabio Sebastiano:
Cryogenic Characterization of Low-Frequency Noise in 40-nm CMOS. CoRR abs/2405.17685 (2024) - 2023
- [j26]Jiang Gong
A Cryo-CMOS PLL for Quantum Computing Applications. IEEE J. Solid State Circuits 58(5): 1362-1375 (2023) - [j25]Gerd Kiene
A 1-GS/s 6-8-b Cryo-CMOS SAR ADC for Quantum Computing. IEEE J. Solid State Circuits 58(7): 2016-2027 (2023) - [c50]Rob A. Damsteegt
A Benchmark of Cryo-CMOS 40-nm Embedded SRAM/DRAMs for Quantum Computing. ESSCIRC 2023: 165-168 - [c49]Eduard Alarcón, Sergi Abadal, Fabio Sebastiano, Masoud Babaie, Edoardo Charbon, Peter Haring Bolívar, Maurizio Palesi, Elena Blokhina, Dirk Leipold, Robert Bogdan Staszewski, Artur García-Sáez, Carmen G. Almudéver:
Scalable multi-chip quantum architectures enabled by cryogenic hybrid wireless/quantum-coherent network-in-package. ISCAS 2023: 1-5 - [c48]Samantha Van Rijs, Ilke Ercan
Single-Electron-Transistor Compact Model for Spin-Qubit Readout. SMACD 2023: 1-4 - [i1]Eduard Alarcón, Sergi Abadal, Fabio Sebastiano, Masoud Babaie, Edoardo Charbon, Peter Haring Bolívar, Maurizio Palesi, Elena Blokhina, Dirk Leipold, Robert Bogdan Staszewski, Artur García-Sáez, Carmen G. Almudéver:
Scalable multi-chip quantum architectures enabled by cryogenic hybrid wireless/quantum-coherent network-in-package. CoRR abs/2303.14008 (2023) - 2022
- [j24]Jiang Gong
A Low-Jitter and Low-Spur Charge-Sampling PLL. IEEE J. Solid State Circuits 57(2): 492-504 (2022) - [j23]Vyshnavi Suntharalingam
Guest Editorial Introduction to the Special Issue on the 2022 IEEE International Solid-State Circuits Conference (ISSCC). IEEE J. Solid State Circuits 57(11): 3183-3185 (2022) - [j22]Giovanni Capobianco, Ciriaco D'Ambrosio
A hybrid metaheuristic for the Knapsack Problem with Forfeits. Soft Comput. 26(2): 749-762 (2022) - [j21]Jiang Gong
A Cryo-CMOS Oscillator With an Automatic Common-Mode Resonance Calibration for Quantum Computing Applications. IEEE Trans. Circuits Syst. I Regul. Pap. 69(12): 4810-4822 (2022) - [c47]Stefano Pellerano, Sushil Subramanian, Jong Seok Park, Bishnu Patra, Todor Mladenov, Xiao Xue
Cryogenic CMOS for Qubit Control and Readout. CICC 2022: 1-8 - [c46]Gerd Kiene, Aishwarya Gunaputi Sreenivasulu, Ramon Overwater
Cryogenic Comparator Characterization and Modeling for a Cryo-CMOS 7b 1-GSa/s SAR ADC. ESSCIRC 2022: 53-56 - [c45]Jiang Gong, Bishnu Patra, Luc Enthoven, Job van Staveren, Fabio Sebastiano, Masoud Babaie:
A 0.049mm2 7.1-to-16.8GHz Dual-Core Triple-Mode VCO Achieving 200dB FoMA in 22nm FinFET. ISSCC 2022: 1-3 - [c44]Luc Enthoven, Job van Staveren, Jiang Gong, Masoud Babaie, Fabio Sebastiano:
A 3V 15b 157μW Cryo-CMOS DAC for Multiplexed Spin-Qubit Biasing. VLSI Technology and Circuits 2022: 228-229 - 2021
- [j20]Giovanni Capobianco, Carmine Cerrone
Image convolution: a linear programming approach for filters design. Soft Comput. 25(14): 8941-8956 (2021) - [c43]Jiang Gong, Edoardo Charbon, Fabio Sebastiano, Masoud Babaie:
A 2.7mW 45fsrms-Jitter Cryogenic Dynamic-Amplifier-Based PLL for Quantum Computing Applications. CICC 2021: 1-2 - [c42]Bagas Prabowo
A 6-to-8GHz 0.17mW/Qubit Cryo-CMOS Receiver for Multiple Spin Qubit Readout in 40nm CMOS Technology. ISSCC 2021: 212-214 - [c41]Gerd Kiene, Alessandro Catania, Ramon Overwater
13.4 A 1GS/s 6-to-8b 0.5mW/Qubit Cryo-CMOS SAR ADC for Quantum Computing in 40nm CMOS. ISSCC 2021: 214-216 - 2020
- [j19]Andrea Ruffino
A Wideband Low-Power Cryogenic CMOS Circulator for Quantum Applications. IEEE J. Solid State Circuits 55(5): 1224-1238 (2020) - [j18]Jeroen Petrus Gerardus van Dijk
A Scalable Cryo-CMOS Controller for the Wideband Frequency-Multiplexed Control of Spin Qubits and Transmons. IEEE J. Solid State Circuits 55(11): 2930-2946 (2020) - [j17]Ming Ding
A 33-ppm/°C 240-nW 40-nm CMOS Wakeup Timer Based on a Bang-Bang Digital-Intensive Frequency-Locked-Loop for IoT Applications. IEEE Trans. Circuits Syst. I Regul. Pap. 67-I(7): 2263-2273 (2020) - [j16]Jeroen P. G. van Dijk
Designing a DDS-Based SoC for High-Fidelity Multi-Qubit Control. IEEE Trans. Circuits Syst. 67-I(12): 5380-5393 (2020) - [c40]Jeroen P. G. van Dijk, Pascal 't Hart, Gerd Kiene, Ramon Overwater
Cryo-CMOS for Analog/Mixed-Signal Circuits and Systems. CICC 2020: 1-8 - [c39]Bishnu Patra
19.1 A Scalable Cryo-CMOS 2-to-20GHz Digitally Intensive Controller for 4×32 Frequency Multiplexed Spin Qubits/Transmons in 22nm FinFET Technology for Quantum Computers. ISSCC 2020: 304-306 - [c38]Jiang Gong, Yue Chen
19.3 A 200dB FoM 4-to-5GHz Cryogenic Oscillator with an Automatic Common-Mode Resonance Calibration for Quantum Computing Applications. ISSCC 2020: 308-310
2010 – 2019
- 2019
- [j15]Jeroen P. G. van Dijk, Edoardo Charbon
The electronic interface for quantum processors. Microprocess. Microsystems 66: 90-101 (2019) - [j14]Massimo Alioto, Magdy S. Abadir, Tughrul Arslan, Chirn Chye Boon, Andreas Burg
Editorial TVLSI Positioning - Continuing and Accelerating an Upward Trajectory. IEEE Trans. Very Large Scale Integr. Syst. 27(2): 253-280 (2019) - [c37]Job van Staveren, Carmen García Almudéver
Voltage References for the Ultra-Wide Temperature Range from 4.2K to 300K in 40-nm CMOS. ESSCIRC 2019: 37-40 - [c36]Pascal Alexander 't Hart, Masoud Babaie, Edoardo Charbon, Andrei Vladimirescu, Fabio Sebastiano:
Subthreshold Mismatch in Nanometer CMOS at Cryogenic Temperatures. ESSDERC 2019: 98-101 - [c35]Mohammadreza Mehrpoo, Bishnu Patra
Benefits and Challenges of Designing Cryogenic CMOS RF Circuits for Quantum Computers. ISCAS 2019: 1-5 - [c34]Jeroen P. G. van Dijk, Andrei Vladimirescu, Masoud Babaie, Edoardo Charbon, Fabio Sebastiano:
SPINE (SPIN Emulator) - A Quantum-Electronics Interface Simulator. IWASI 2019: 23-28 - 2018
- [j13]Bishnu Patra
Cryo-CMOS Circuits and Systems for Quantum Computing Applications. IEEE J. Solid State Circuits 53(1): 309-321 (2018) - [j12]Cagri Gurleyuk
A CMOS Dual-RC Frequency Reference With ±200-ppm Inaccuracy From -45 °C to 85 °C. IEEE J. Solid State Circuits 53(12): 3386-3395 (2018) - [j11]Shoubhik Karmakar
A 280 µW Dynamic Zoom ADC With 120 dB DR and 118 dB SNDR in 1 kHz BW. IEEE J. Solid State Circuits 53(12): 3497-3507 (2018) - [c33]Jeroen P. G. van Dijk, Andrei Vladimirescu, Masoud Babaie, Edoardo Charbon, Fabio Sebastiano
A co-design methodology for scalable quantum processors and their classical electronic interface. DATE 2018: 573-576 - [c32]Carmen G. Almudéver
Towards a scalable quantum computer. DTIS 2018: 1 - [c31]Pascal Alexander 't Hart, Jeroen P. G. van Dijk, Masoud Babaie, Edoardo Charbon, Andrei Vladimirescu, Fabio Sebastiano
Characterization and Model Validation of Mismatch in Nanometer CMOS at Cryogenic Temperatures. ESSDERC 2018: 246-249 - [c30]Cagri Gurleyuk, Lorenzo Pedala, Fabio Sebastiano
A CMOS Dual-RC frequency reference with ±250ppm inaccuracy from -45°C to 85°C. ISSCC 2018: 54-56 - [c29]Shoubhik Karmakar, Burak Gonen, Fabio Sebastiano
A 280μW dynamic-zoom ADC with 120dB DR and 118dB SNDR in 1kHz BW. ISSCC 2018: 238-240 - 2017
- [j10]Ugur Sonmez, Fabio Sebastiano
Compact Thermal-Diffusivity-Based Temperature Sensors in 40-nm CMOS for SoC Thermal Monitoring. IEEE J. Solid State Circuits 52(3): 834-843 (2017) - [j9]Burak Gonen
A Dynamic Zoom ADC With 109-dB DR for Audio Applications. IEEE J. Solid State Circuits 52(6): 1542-1550 (2017) - [j8]Ugur Sonmez, Fabio Sebastiano
Analysis and Design of VCO-Based Phase-Domain ΣΔ Modulators. IEEE Trans. Circuits Syst. I Regul. Pap. 64-I(5): 1075-1084 (2017) - [c28]Fabio Sebastiano, Harald Homulle
Cryo-CMOS Electronic Control for Scalable Quantum Computing: Invited. DAC 2017: 13:1-13:6 - [c27]Lorenzo Pedala, Cagri Gurleyuk, Sining Pan, Fabio Sebastiano
A frequency-locked loop based on an oxide electrothermal filter in standard CMOS. ESSCIRC 2017: 7-10 - [c26]Rosario M. Incandela, Lin Song, Harald A. R. Homulle
Nanometer CMOS characterization and compact modeling at deep-cryogenic temperatures. ESSDERC 2017: 58-61 - [c25]Enrico Prati
From the Quantum Moore's Law toward Silicon Based Universal Quantum Computing. ICRC 2017: 1-4 - [c24]Edoardo Charbon, Fabio Sebastiano
15.5 Cryo-CMOS circuits and systems for scalable quantum computing. ISSCC 2017: 264-265 - [c23]Fabio Sebastiano
Cryogenic CMOS interfaces for quantum devices. IWASI 2017: 59-62 - 2016
- [c22]Harald Homulle
CryoCMOS hardware technology a classical infrastructure for a scalable quantum computer. Conf. Computing Frontiers 2016: 282-287 - [c21]Xiang Fu, Leon Riesebos
A heterogeneous quantum computer architecture. Conf. Computing Frontiers 2016: 323-330 - [c20]Lorenzo Pedala, Ugur Sonmez, Fabio Sebastiano
An oxide electrothermal filter in standard CMOS. IEEE SENSORS 2016: 1-3 - [c19]Lin Song, Harald Homulle
Characterization of bipolar transistors for cryogenic temperature sensors in standard CMOS. IEEE SENSORS 2016: 1-3 - [c18]Ugur Sonmez, Fabio Sebastiano
11.4 1650µm2 thermal-diffusivity sensors with inaccuracies down to ±0.75°C in 40nm CMOS. ISSCC 2016: 206-207 - [c17]Burak Gonen, Fabio Sebastiano
15.7 A 1.65mW 0.16mm2 dynamic zoom-ADC with 107.5dB DR in 20kHz BW. ISSCC 2016: 282-283 - 2015
- [c16]Jan A. Angevare, Lorenzo Pedala, Ugur Sonmez, Fabio Sebastiano
A 2800-μm2 thermal-diffusivity temperature sensor with VCO-based readout in 160-nm CMOS. A-SSCC 2015: 1-4 - [c15]Wouter Brevet, Fabio Sebastiano
A 25 mW smart CMOS wind sensor with corner heaters. IECON 2015: 1194-1199 - [c14]Rui Quan, Ugur Sonmez, Fabio Sebastiano
27.8 A 4600μm2 1.5°C (3σ) 0.9kS/s thermal-diffusivity temperature sensor with VCO-based readout. ISSCC 2015: 1-3 - 2014
- [c13]Ugur Sonmez, Rui Quan, Fabio Sebastiano
A 0.008-mm2 area-optimized thermal-diffusivity-based temperature sensor in 160-nm CMOS for SoC thermal monitoring. ESSCIRC 2014: 395-398 - [c12]Fabio Sebastiano
17.5 A 0.07mm2 2-channel instrumentation amplifier with 0.1% gain matching in 0.16μm CMOS. ISSCC 2014: 294-295 - 2013
- [c11]Fabio Sebastiano
A 0.1-mm2 3-channel area-optimized ΣΔ ADC in 0.16-µm CMOS with 20-kHz BW and 86-dB DR. ESSCIRC 2013: 375-378 - [c10]Selcuk Ersoy, Robert H. M. van Veldhoven, Fabio Sebastiano
A 0.25mm2 AC-biased MEMS microphone interface with 58dBA SNR. ISSCC 2013: 382-383 - 2011
- [j7]Qinwen Fan, Fabio Sebastiano
A 1.8 μ W 60 nV √ Hz Capacitively-Coupled Chopper Instrumentation Amplifier in 65 nm CMOS for Wireless Sensor Nodes. IEEE J. Solid State Circuits 46(7): 1534-1543 (2011) - [j6]Fabio Sebastiano
A 65-nm CMOS Temperature-Compensated Mobility-Based Frequency Reference for Wireless Sensor Networks. IEEE J. Solid State Circuits 46(7): 1544-1552 (2011) - [c9]Fabio Sebastiano
Effects of packaging and process spread on a mobility-based frequency reference in 0.16-μm CMOS. ESSCIRC 2011: 511-514 - 2010
- [j5]Salvatore Drago, Domine Leenaerts, Bram Nauta
A 200 μA Duty-Cycled PLL for Wireless Sensor Nodes in 65 nm CMOS. IEEE J. Solid State Circuits 45(7): 1305-1315 (2010) - [j4]Fabio Sebastiano
A 1.2-V 10-μ W NPN-Based Temperature Sensor in 65-nm CMOS With an Inaccuracy of 0.2°C (3 Sigma ) From - 70°C to 125°C. IEEE J. Solid State Circuits 45(12): 2591-2601 (2010) - [c8]Fabio Sebastiano
A 65-nm CMOS temperature-compensated mobility-based frequency reference for Wireless Sensor Networks. ESSCIRC 2010: 102-105 - [c7]Qinwen Fan, Fabio Sebastiano
A 1.8µW 1µV-offset capacitively-coupled chopper instrumentation amplifier in 65nm CMOS. ESSCIRC 2010: 170-173 - [c6]Salvatore Drago, Domine M. W. Leenaerts, Fabio Sebastiano
A 2.4GHz 830pJ/bit duty-cycled wake-up receiver with -82dBm sensitivity for crystal-less wireless sensor nodes. ISSCC 2010: 224-225 - [c5]Fabio Sebastiano
A 1.2V 10µW NPN-based temperature sensor in 65nm CMOS with an inaccuracy of ±0.2°C (3s) from -70°C to 125°C. ISSCC 2010: 312-313
2000 – 2009
- 2009
- [j3]Fabio Sebastiano
A Low-Voltage Mobility-Based Frequency Reference for Crystal-Less ULP Radios. IEEE J. Solid State Circuits 44(7): 2002-2009 (2009) - [j2]Salvatore Drago, Fabio Sebastiano
Impulse-Based Scheme for Crystal-Less ULP Radios. IEEE Trans. Circuits Syst. I Regul. Pap. 56-I(5): 1041-1052 (2009) - [c4]Salvatore Drago, Domine Leenaerts, Bram Nauta
A 200 µA duty-cycled PLL for wireless sensor nodes. ESSCIRC 2009: 132-135 - 2008
- [c3]Fabio Sebastiano
A low-voltage mobility-based frequency reference for crystal-less ULP radios. ESSCIRC 2008: 306-309 - [c2]Fabio Sebastiano
Impulse based scheme for crystal-less ULP radios. ISCAS 2008: 1508-1511 - 2006
- [j1]Paolo Bruschi
CMOS Transconductors With Nearly Constant Input Ranges Over Wide Tuning Intervals. IEEE Trans. Circuits Syst. II Express Briefs 53-II(10): 1002-1006 (2006) - 2005
- [c1]Paolo Bruschi
A tunable CMOS transconductor for ultra-low Gm with wide differential input voltage range. ECCTD 2005: 337-340
Coauthor Index
Jeroen P. G. van Dijk
aka: Jeroen Petrus Gerardus van Dijk
aka: Jeroen Petrus Gerardus van Dijk
Domine Leenaerts
aka: Domine M. W. Leenaerts
aka: Domine M. W. Leenaerts
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last updated on 2024-12-10 20:50 CET by the dblp team
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