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Nick Van Helleputte
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2020 – today
- 2024
- [c45]Haoming Xin, Meiyi Zhou
, Roland Van Wegberg, Peter Vis, Konstantinos Petkos, Shrishail Patki, Nicolò Rossetti, Mark Fichman, Vojkan Mihajlovic, Carolina Mora Lopez, Geert Langereis, Mario Konijnenburg, Nick Van Helleputte:
A 10V Compliant 16-Channel Stimulator ASIC with sub-10nA Mismatch and Simultaneous ETI Sensing for Selective Vagus Nerve Stimulation. CICC 2024: 1-2 - [c44]Marios Gourdouparis, Chengyao Shi, Yuming He, Stefano Stanzione, Robert Ukropec, Pieter Gijsenbergh, Veronique Rochus, Nick Van Helleputte, Wouter A. Serdijn, Yao-Hong Liu
6.2 An Ultrasound-Powering TX with a Global Charge-Redistribution Adiabatic Drive Achieving 69% Power Reduction and 53° Maximum Beam Steering Angle for Implantable Applications. ISSCC 2024: 102-104 - 2023
- [j32]Nick Van Helleputte, Carolina Mora Lopez, Chris Van Hoof:
Design of CMOS Circuits for Electrophysiology. IEICE Trans. Electron. 106(10): 506-515 (2023) - [j31]Qiuyang Lin
A Multichannel Electrochemical Sensor Interface IC for Bioreactor Monitoring. IEEE Trans. Biomed. Circuits Syst. 17(6): 1227-1236 (2023) - [j30]Aurojyoti Das
High-Throughput Nanopore-FET Array Readout IC With 5-MHz Bandwidth and Background Offset/Drift Calibration. IEEE Trans. Circuits Syst. I Regul. Pap. 70(11): 4323-4333 (2023) - [c43]Charalampos Papadakis, Leandro Mateus Giacomini Rocha, Francky Catthoor, Nick Van Helleputte, Dwaipayan Biswas
AusculNET: A Deep Learning framework for Adventitious Lung Sounds Classification. ICECS 2023: 1-4 - [c42]Qiuyang Lin, Wim Sijbers, Christina Avdikou, Didac Gomez Salinas, Dwaipayan Biswas
A $\boldsymbol{22\mu \mathrm{W}}$ Peak Power Multimodal Electrochemical Sensor Interface IC for Bioreactor Monitoring. ISSCC 2023: 314-315 - 2022
- [j29]Xiaohua Huang
Actively Multiplexed μECoG Brain Implant System With Incremental-ΔΣ ADCs Employing Bulk-DACs. IEEE J. Solid State Circuits 57(11): 3312-3323 (2022) - [j28]Xiaohua Huang
A Compact, Low-Power Analog Front-End With Event-Driven Input Biasing for High-Density Neural Recording in 22-nm FDSOI. IEEE Trans. Circuits Syst. II Express Briefs 69(3): 804-808 (2022) - [c41]Qiuyang Lin, Christina Avidikou, Filip Tavernier, Nick Van Helleputte:
Photoplethysmography (PPG) Sensor Circuit Design Techniques. CICC 2022: 1-8 - [c40]Oi-Ying Wong, Dries Tabruyn, Veronique Rochus, Nick Van Helleputte:
An Implantable Power Extraction Circuit with Integrated PMUTs for Wireless Power Delivery. ESSCIRC 2022: 217-220 - [c39]Xiaohua Huang, Horacio Londoño-Ramírez
A 256-Channel Actively-Multiplexed µECoG Implant with Column-Parallel Incremental ΔΣ ADCs Employing Bulk-DACs in 22-nm FDSOI Technology. ISSCC 2022: 200-202 - 2021
- [j27]Xiaolin Yang
A 108 dB DR Δ∑-∑M Front-End With 720 mVpp Input Range and >±300 mV Offset Removal for Multi-Parameter Biopotential Recording. IEEE Trans. Biomed. Circuits Syst. 15(2): 199-209 (2021) - [j26]Qiuyang Lin
A 134 DB Dynamic Range Noise Shaping Slope Light-to-Digital Converter for Wearable Chest PPG Applications. IEEE Trans. Biomed. Circuits Syst. 15(6): 1224-1235 (2021) - [c38]Leandro Mateus Giacomini Rocha
LSTM-only Model for Low-complexity HR Estimation from Wrist PPG. EMBC 2021: 1068-1071 - [c37]Erika Lutin
Learning based Quality Indicator Aiding Heart Rate Estimation in Wrist-Worn PPG. EMBC 2021: 7063-7067 - [c36]Nestor Cuevas
Modeling and Characterization of Intra-Body Links for a Smart Contact Lens. ISCAS 2021: 1-5 - [c35]Munehiko Nagatani, Nick Van Helleputte, Naveen Verma:
Session 19 Overview: Optical Systems for Emerging Applications Technology Directions Subcommittee. ISSCC 2021: 284-285 - [c34]Qiuyang Lin, Shuang Song
A 28μW 134dB DR 2nd-Order Noise-Shaping Slope Light-to-Digital Converter for Chest PPG Monitoring. ISSCC 2021: 390-392 - [c33]Nick Van Helleputte, Arijit Raychowdhury, Ping-Hsuan Hsieh
F3: Silicon Technologies in the Fight Against Pandemics - From Point of Care to Computational Epidemiology. ISSCC 2021: 520-524 - 2020
- [j25]Leandro Mateus Giacomini Rocha
Binary CorNET: Accelerator for HR Estimation From Wrist-PPG. IEEE Trans. Biomed. Circuits Syst. 14(4): 715-726 (2020) - [j24]Qiuyang Lin
A 119dB Dynamic Range Charge Counting Light-to-Digital Converter For Wearable PPG/NIRS Monitoring Applications. IEEE Trans. Biomed. Circuits Syst. 14(4): 800-810 (2020) - [j23]Minyoung Song
A Millimeter-Scale Crystal-Less MICS Transceiver for Insertable Smart Pills. IEEE Trans. Biomed. Circuits Syst. 14(6): 1218-1229 (2020) - [j22]Shuang Song
A 50μW Fully Differential Interface Amplifier With a Current Steering Class AB Output Stage for PPG and NIRS Recordings. IEEE Trans. Circuits Syst. II Express Briefs 67-II(9): 1564-1568 (2020) - [c32]Minyoung Song
30.8 A 3.5mm×3.8mm Crystal-Less MICS Transceiver Featuring Coverages of ±160ppm Carrier Frequency Offset and 4.8-VSWR Antenna Impedance for Insertable Smart Pills. ISSCC 2020: 474-476 - [c31]Bogdan C. Raducanu, Samira Zali Asl, Stefano Stanzione, Chris van Liempd, Andrés Vásquez Quintero, Herbert De Smet
An Artificial Iris ASIC with High Voltage Liquid Crystal Driver, 10 nA Light Range Detector and 40 nA Blink Detector for LCD Flicker Removal. VLSI Circuits 2020: 1-2
2010 – 2019
- 2019
- [j21]Hyunsoo Ha
A Bio-Impedance Readout IC With Digital-Assisted Baseline Cancellation for Two-Electrode Measurement. IEEE J. Solid State Circuits 54(11): 2969-2979 (2019) - [j20]Yifan Zhang, Shuang Song, Rik Vullings
Motion Artifact Reduction for Wrist-Worn Photoplethysmograph Sensors Based on Different Wavelengths. Sensors 19(3): 673 (2019) - [j19]Dwaipayan Biswas
CorNET: Deep Learning Framework for PPG-Based Heart Rate Estimation and Biometric Identification in Ambulant Environment. IEEE Trans. Biomed. Circuits Syst. 13(2): 282-291 (2019) - [j18]Mingyi Chen
A 400 GΩ Input-Impedance Active Electrode for Non-Contact Capacitively Coupled ECG Acquisition With Large Linear-Input-Range and High CM-Interference-Tolerance. IEEE Trans. Biomed. Circuits Syst. 13(2): 376-386 (2019) - [j17]Shuang Song
A 769 μW Battery-Powered Single-Chip SoC With BLE for Multi-Modal Vital Sign Monitoring Health Patches. IEEE Trans. Biomed. Circuits Syst. 13(6): 1506-1517 (2019) - [j16]Shiwei Wang
A Compact Quad-Shank CMOS Neural Probe With 5, 120 Addressable Recording Sites and 384 Fully Differential Parallel Channels. IEEE Trans. Biomed. Circuits Syst. 13(6): 1625-1634 (2019) - [j15]Jan Putzeys
Neuropixels Data-Acquisition System: A Scalable Platform for Parallel Recording of 10 000+ Electrophysiological Signals. IEEE Trans. Biomed. Circuits Syst. 13(6): 1635-1644 (2019) - [c30]Leandro Mateus Giacomini Rocha
Real-time HR Estimation from wrist PPG using Binary LSTMs. BioCAS 2019: 1-4 - [c29]Parvez Ahmmed
A Wearable Wrist-Band with Compressive Sensing based Ultra-Low Power Photoplethysmography Readout Circuit. BSN 2019: 1-4 - [c28]Luke R. Everson, Dwaipayan Biswas
BioTranslator: Inferring R-Peaks from Ambulatory Wrist-Worn PPG Signal. EMBC 2019: 4241-4245 - [c27]Roland Van Wegberg, Julien Penders, Chris Van Hoof
A 5-Channel Unipolar Fetal-ECG Readout IC for Patch-Based Fetal Monitoring. ESSCIRC 2019: 71-74 - [c26]Mario Konijnenburg, Roland Van Wegberg, Shuang Song
A 769μW Battery-Powered Single-Chip SoC With BLE for Multi-Modal Vital Sign Health Patches. ISSCC 2019: 360-362 - [c25]Hyunsoo Ha, Wim Sijbers, Roland Van Wegberg, Jiawei Xu, Mario Konijnenburg, Peter Vis, Arjan Breeschoten, Shuang Song
A Bio-Impedance Readout IC With Digital-Assisted Baseline Cancellation for 2-Electrode Measurement. ISSCC 2019: 368-370 - [c24]Qiuyang Lin, Jiawei Xu, Shuang Song
A 196μW, Reconfigurable Light-to-Digital Converter with 119dB Dynamic Range, for Wearable PPG/NIRS Sensors. VLSI Circuits 2019: 58- - [c23]Xiaolin Yang, Jiawei Xu, Hosung Chun, Marco Ballini
A 108dB DR Hybrid-CTDT Direct-Digitalization ΔΣ-ΣM Front-End with 720mVpp Input Range and >300mV Offset Removal for Wearable Bio-Signal Recording. VLSI Circuits 2019: 296- - 2018
- [j14]Carolina Mora Lopez
A Multimodal CMOS MEA for High-Throughput Intracellular Action Potential Measurements and Impedance Spectroscopy in Drug-Screening Applications. IEEE J. Solid State Circuits 53(11): 3076-3086 (2018) - [j13]Jiawei Xu
A 36 μW 1.1 mm2 Reconfigurable Analog Front-End for Cardiovascular and Respiratory Signals Recording. IEEE Trans. Biomed. Circuits Syst. 12(4): 774-783 (2018) - [j12]Jiawei Xu
A 665 μW Silicon Photomultiplier-Based NIRS/EEG/EIT Monitoring ASIC for Wearable Functional Brain Imaging. IEEE Trans. Biomed. Circuits Syst. 12(6): 1267-1277 (2018) - [j11]Yahya H. Yassin
Algorithm/Architecture Co-optimisation Technique for Automatic Data Reduction of Wireless Read-Out in High-Density Electrode Arrays. ACM Trans. Embed. Comput. Syst. 17(3): 67:1-67:19 (2018) - [c22]Jiawei Xu, Qiuyang Lin, Ming Ding, Yao Li, Chris Van Hoof
A 0.6V 3.8μW ECG/bio-impedance monitoring IC for disposable health patch in 40nm CMOS. CICC 2018: 1-4 - [c21]Luke R. Everson, Dwaipayan Biswas
BiometricNet: Deep Learning based Biometric Identification using Wrist-Worn PPG. ISCAS 2018: 1-5 - [c20]Jiawei Xu, Mario Konijnenburg, Budi Lukita, Shuang Song
A 665μW silicon photomultiplier-based NIRS/EEG/EIT monitoring asic for wearable functional brain imaging. ISSCC 2018: 294-296 - [c19]Pedram Mohseni, Nick Van Helleputte, Makoto Ikeda:
Session 29 overview: Advanced biomedical systems: IMMD subcommittee. ISSCC 2018: 458-459 - [c18]Carolina Mora Lopez
A 16384-electrode 1024-channel multimodal CMOS MEA for high-throughput intracellular action potential measurements and impedance spectroscopy in drug-screening applications. ISSCC 2018: 464-466 - [c17]Mingyi Chen, Ivan Dario Castro, Qiuyang Lin, Tom Torfs, Filip Tavernier, Chris Van Hoof
A 400GΩ Input-Impedance, 220MVpp Linear-Input-Range, 2.8Vpp CM-Interference-Tolerant Active Electrode for Non-Contact Capacitively Coupled ECG Acquisition. VLSI Circuits 2018: 129-130 - 2017
- [j10]Rachit Mohan
A 0.6-V, 0.015-mm2, Time-Based ECG Readout for Ambulatory Applications in 40-nm CMOS. IEEE J. Solid State Circuits 52(1): 298-308 (2017) - [j9]Bogdan C. Raducanu, Refet Firat Yazicioglu, Carolina Mora Lopez
Time Multiplexed Active Neural Probe with 1356 Parallel Recording Sites. Sensors 17(10): 2388 (2017) - [j8]Venkata Rajesh Pamula, Jose Manuel Valero-Sarmiento, Long Yan, Alper Bozkurt, Chris Van Hoof
A 172 µW Compressively Sampled Photoplethysmographic (PPG) Readout ASIC With Heart Rate Estimation Directly From Compressively Sampled Data. IEEE Trans. Biomed. Circuits Syst. 11(3): 487-496 (2017) - [j7]Carolina Mora Lopez
A Neural Probe With Up to 966 Electrodes and Up to 384 Configurable Channels in 0.13 µm SOI CMOS. IEEE Trans. Biomed. Circuits Syst. 11(3): 510-522 (2017) - [c16]Luis E. Rueda G.
Analysis of passive charge balancing for safe current-mode neural stimulation. ISCAS 2017: 1-4 - 2016
- [j6]Mario Konijnenburg
A Multi(bio)sensor Acquisition System With Integrated Processor, Power Management, 8×8 LED Drivers, and Simultaneously Synchronized ECG, BIO-Z, GSR, and Two PPG Readouts. IEEE J. Solid State Circuits 51(11): 2584-2595 (2016) - [c15]Daniele Bortolotti
PHIDIAS: ultra-low-power holistic design for smart bio-signals computing platforms. Conf. Computing Frontiers 2016: 309-314 - [c14]Bogdan C. Raducanu, Refet Firat Yazicioglu, Carolina Mora Lopez
Time multiplexed active neural probe with 678 parallel recording sites. ESSDERC 2016: 385-388 - [c13]Pamula Venkata Rajesh, Jose Manuel Valero-Sarmiento, Long Yan, Alper Bozkurt, Chris Van Hoof
22.4 A 172µW compressive sampling photoplethysmographic readout with embedded direct heart-rate and variability extraction from compressively sampled data. ISSCC 2016: 386-387 - [c12]Mario Konijnenburg, Stefano Stanzione, Long Yan, Dong-Woo Jee, Julia Pettine, Roland Van Wegberg, Hyejung Kim, Chris van Liempd, Ram Fish, James Schuessler, Harmke de Groot, Chris Van Hoof
28.4 A battery-powered efficient multi-sensor acquisition system with simultaneous ECG, BIO-Z, GSR, and PPG. ISSCC 2016: 480-481 - [c11]Rachit Mohan, Samira Zaliasl, Georges G. E. Gielen, Chris Van Hoof
28.5 A 0.6V 0.015mm2 time-based biomedical readout for ambulatory applications in 40nm CMOS. ISSCC 2016: 482-483 - 2015
- [j5]Nick Van Helleputte
A 345 µW Multi-Sensor Biomedical SoC With Bio-Impedance, 3-Channel ECG, Motion Artifact Reduction, and Integrated DSP. IEEE J. Solid State Circuits 50(1): 230-244 (2015) - 2014
- [j4]Hyejung Kim, Sunyoung Kim, Nick Van Helleputte
A Configurable and Low-Power Mixed Signal SoC for Portable ECG Monitoring Applications. IEEE Trans. Biomed. Circuits Syst. 8(2): 257-267 (2014) - [c10]Nick Van Helleputte
18.3 A multi-parameter signal-acquisition SoC for connected personal health applications. ISSCC 2014: 314-315 - 2012
- [j3]Nick Van Helleputte
A 160 $\mu{\rm A}$ Biopotential Acquisition IC With Fully Integrated IA and Motion Artifact Suppression. IEEE Trans. Biomed. Circuits Syst. 6(6): 552-561 (2012) - [c9]Hyejung Kim, Sunyoung Kim, Nick Van Helleputte
Motion artifact removal using cascade adaptive filtering for ambulatory ECG monitoring system. BioCAS 2012: 160-163 - [c8]Dilpreet Buxi, Torfinn Berset, Martijn Hijdra, Marc Tutelaers, Di Geng, Jos Hulzink, Michel van Noorloos, Iñaki Romero, Tom Torfs, Nick Van Helleputte
Wireless 3-lead ECG system with on-board digital signal processing for ambulatory monitoring. BioCAS 2012: 308-311 - [c7]Sunyoung Kim, Hyejung Kim, Nick Van Helleputte
Real time digitally assisted analog motion artifact reduction in ambulatory ECG monitoring system. EMBC 2012: 2096-2099 - [c6]Nick Van Helleputte
A 160μA biopotential acquisition ASIC with fully integrated IA and motion-artifact suppression. ISSCC 2012: 118-120 - 2011
- [c5]Iñaki Romero, Torfinn Berset, Dilpreet Buxi, Lindsay Brown, Julien Penders, Sunyoung Kim, Nick Van Helleputte, Hyejung Kim, Chris Van Hoof
Motion artifact reduction in ambulatory ECG monitoring: an integrated system approach. Wireless Health 2011: 11 - [c4]Marco Altini, Salvatore Polito, Julien Penders, Hyejung Kim, Nick Van Helleputte, Sunyoung Kim, Refet Firat Yazicioglu:
An ECG patch combining a customized ultra-low-power ECG SoC with Bluetooth low energy for long term ambulatory monitoring. Wireless Health 2011: 15 - 2010
- [j2]Nick Van Helleputte
A Reconfigurable, 130 nm CMOS 108 pJ/pulse, Fully Integrated IR-UWB Receiver for Communication and Precise Ranging. IEEE J. Solid State Circuits 45(1): 69-83 (2010)
2000 – 2009
- 2009
- [j1]Nick Van Helleputte
A 70 pJ/Pulse Analog Front-End in 130 nm CMOS for UWB Impulse Radio Receivers. IEEE J. Solid State Circuits 44(7): 1862-1871 (2009) - [c3]Wim Dehaene, Georges G. E. Gielen
RFID, where are they? ESSCIRC 2009: 36-43 - [c2]Marian Verhelst
A reconfigurable, 0.13µm CMOS 110pJ/pulse, fully integrated IR-UWB receiver for communication and sub-cm ranging. ISSCC 2009: 250-251 - 2008
- [c1]Nick Van Helleputte
A 46pJ/pulse analog front-end in 130nm CMOS for UWB impulse radio receivers. ESSCIRC 2008: 378-381
Coauthor Index
[j32] [j30] [j29] [j28] [c39] [j27] [j26] [c38] [c37] [c34] [c33] [j25] [j24] [j22] [c31] [j21] [j20] [j19] [j18] [j17] [c30] [c29] [c28] [c27] [c26] [c25] [c24] [c23] [j13] [j12] [c22] [c21] [c20] [c17] [j10] [j9] [j8] [j7] [j6] [c15] [c14] [c13] [c12] [c11] [j5] [j4] [c10] [j3] [c9] [c7] [c6] [c5]
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last updated on 2024-10-07 21:24 CEST by the dblp team
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