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Mario Konijnenburg
Person information
- affiliation: IMEC, Eindhoven, The Netherlands
- affiliation: Delft University of Technology, The Netherlands
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2020 – today
- 2024
- [j19]Yuming He, Stan van der Ven, Hua-Peng Liaw, Chengyao Shi, Pietro Russo, Marios Gourdouparis, Mario Konijnenburg, Stefano Traferro, Martijn Timmermans, Carolina Mora Lopez, Pieter Harpe, Eugenio Cantatore, Elisabetta Chicca, Yao-Hong Liu:
An Event-Based Neural Compressive Telemetry With >11× Loss-Less Data Reduction for High-Bandwidth Intracortical Brain Computer Interfaces. IEEE Trans. Biomed. Circuits Syst. 18(5): 1100-1111 (2024) - [j18]Leandro Mateus Giacomini Rocha, Refik Bilgic, Mohamed Naeim, Sudipta Das, Herman Oprins, Amirreza Yousefzadeh, Mario Konijnenburg, Dragomir Milojevic, James Myers, Julien Ryckaert, Dwaipayan Biswas:
Multidie 3-D Stacking of Memory Dominated Neuromorphic Architectures. IEEE Trans. Very Large Scale Integr. Syst. 32(11): 2144-2148 (2024) - [c44]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 - [c43]Anoop Narayan Bhat, Paul Mateman, Zule Xu, Peter Vis, Paul Detterer, Gururaja Kasanadi Ramachandra, Yunus Baykal, Mario Konijnenburg, Yao-Hong Liu, Christian Bachmann, Peng Zhang:
23.5 A 7.6mW IR-UWB Receiver Achieving -13dBm Blocker Resilience with a Linear RF Front-End. ISSCC 2024: 408-410 - [i3]Alexandra F. Dobrita, Amirreza Yousefzadeh, Simon Thorpe, Kanishkan Vadivel, Paul Detterer, Guangzhi Tang, Gert-Jan van Schaik, Mario Konijnenburg, Anteneh Gebregiorgis, Said Hamdioui, Manolis Sifalakis:
EON-1: A Brain-Inspired Processor for Near-Sensor Extreme Edge Online Feature Extraction. CoRR abs/2406.17285 (2024) - 2023
- [j17]Manolis Katsaragakis, Lazaros Papadopoulos, Mario Konijnenburg, Francky Catthoor, Dimitrios Soudris:
A memory footprint optimization framework for Python applications targeting edge devices. J. Syst. Archit. 142: 102936 (2023) - [j16]Benoît Walter Denkinger, Miguel Peón Quirós, Mario Konijnenburg, David Atienza, Francky Catthoor:
Acceleration of Control Intensive Applications on Coarse-Grained Reconfigurable Arrays for Embedded Systems. IEEE Trans. Computers 72(9): 2548-2560 (2023) - [c42]Guangzhi Tang, Ali Safa, Kevin Shidqi, Paul Detterer, Stefano Traferro, Mario Konijnenburg, Manolis Sifalakis, Gert-Jan van Schaik, Amirreza Yousefzadeh:
Open the box of digital neuromorphic processor: Towards effective algorithm-hardware co-design. ISCAS 2023: 1-5 - [i2]Guangzhi Tang, Ali Safa, Kevin Shidqi, Paul Detterer, Stefano Traferro, Mario Konijnenburg, Manolis Sifalakis, Gert-Jan van Schaik, Amirreza Yousefzadeh:
Open the box of digital neuromorphic processor: Towards effective algorithm-hardware co-design. CoRR abs/2303.15224 (2023) - 2022
- [c41]Amirreza Yousefzadeh, Gert-Jan van Schaik, Mohammad Tahghighi, Paul Detterer, Stefano Traferro, Martijn Hijdra, Jan Stuijt, Federico Corradi, Manolis Sifalakis, Mario Konijnenburg:
SENeCA: Scalable Energy-efficient Neuromorphic Computer Architecture. AICAS 2022: 371-374 - [c40]Benoît W. Denkinger, Miguel Peón Quirós, Mario Konijnenburg, David Atienza, Francky Catthoor:
VWR2A: a very-wide-register reconfigurable-array architecture for low-power embedded devices. DAC 2022: 895-900 - [c39]Minyoung Song, Yu Huang, Yiyu Shen, Chengyao Shi, Arjan Breeschoten, Mario Konijnenburg, Huib Visser, Jac Romme, Barundeb Dutta, Morteza S. Alavi, Christian Bachmann, Yao-Hong Liu:
A 1.66Gb/s and 5.8pJ/b Transcutaneous IR-UWB Telemetry System with Hybrid Impulse Modulation for Intracortical Brain-Computer Interfaces. ISSCC 2022: 394-396 - [i1]Benoît Walter Denkinger, Miguel Peón Quirós, Mario Konijnenburg, David Atienza, Francky Catthoor:
VWR2A: A Very-Wide-Register Reconfigurable-Array Architecture for Low-Power Embedded Devices. CoRR abs/2204.05009 (2022) - 2021
- [j15]Qiuyang Lin, Shuang Song, Roland Van Wegberg, Wim Sijbers, Dwaipayan Biswas, Mario Konijnenburg, Chris Van Hoof, Filip Tavernier, Nick Van Helleputte:
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]Qiuyang Lin, Shuang Song, Roland Van Wegberg, Mario Konijnenburg, Dwaipayan Biswas, Chris Van Hoof, Filip Tavernier, Nick Van Helleputte:
A 28μW 134dB DR 2nd-Order Noise-Shaping Slope Light-to-Digital Converter for Chest PPG Monitoring. ISSCC 2021: 390-392 - 2020
- [j14]Leandro Mateus Giacomini Rocha, Dwaipayan Biswas, Bram-Ernst Verhoef, Sergio Bampi, Chris Van Hoof, Mario Konijnenburg, Marian Verhelst, Nick Van Helleputte:
Binary CorNET: Accelerator for HR Estimation From Wrist-PPG. IEEE Trans. Biomed. Circuits Syst. 14(4): 715-726 (2020) - [j13]Qiuyang Lin, Jiawei Xu, Shuang Song, Arjan Breeschoten, Mario Konijnenburg, Chris Van Hoof, Filip Tavernier, Nick Van Helleputte:
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) - [c37]Manolis Katsaragakis, Lazaros Papadopoulos, Mario Konijnenburg, Francky Catthoor, Dimitrios Soudris:
Memory Footprint Optimization Techniques for Machine Learning Applications in Embedded Systems. ISCAS 2020: 1-4
2010 – 2019
- 2019
- [j12]Hyunsoo Ha, Wim Sijbers, Roland Van Wegberg, Jiawei Xu, Mario Konijnenburg, Peter Vis, Arjan Breeschoten, Shuang Song, Chris Van Hoof, Nick Van Helleputte:
A Bio-Impedance Readout IC With Digital-Assisted Baseline Cancellation for Two-Electrode Measurement. IEEE J. Solid State Circuits 54(11): 2969-2979 (2019) - [j11]Dwaipayan Biswas, Luke R. Everson, Muqing Liu, Madhuri Panwar, Bram-Ernst Verhoef, Shrishail Patki, Chris H. Kim, Amit Acharyya, Chris Van Hoof, Mario Konijnenburg, Nick Van Helleputte:
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) - [j10]Shuang Song, Peter Vis, Chris van Liempd, Chris Van Hoof, Nick Van Helleputte, Mario Konijnenburg, Roland Van Wegberg, Jiawei Xu, Hyunsoo Ha, Wim Sijbers, Stefano Stanzione, Dwaipayan Biswas, Arjan Breeschoten:
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) - [c36]Leandro Mateus Giacomini Rocha, Nick Van Helleputte, Muqing Liu, Dwaipayan Biswas, Bram-Ernst Verhoef, Sergio Bampi, Chris H. Kim, Chris Van Hoof, Mario Konijnenburg, Marian Verhelst:
Real-time HR Estimation from wrist PPG using Binary LSTMs. BioCAS 2019: 1-4 - [c35]Luke R. Everson, Dwaipayan Biswas, Bram-Ernst Verhoef, Chris H. Kim, Chris Van Hoof, Mario Konijnenburg, Nick Van Helleputte:
BioTranslator: Inferring R-Peaks from Ambulatory Wrist-Worn PPG Signal. EMBC 2019: 4241-4245 - [c34]Roland Van Wegberg, Julien Penders, Chris Van Hoof, Nick Van Helleputte, Wim Sijbers, Shuang Song, Arjan Breeschoten, Peter Vis, Mario Konijnenburg, Hui Jiang, Michiel Rooijakkers, Torfinn Berset:
A 5-Channel Unipolar Fetal-ECG Readout IC for Patch-Based Fetal Monitoring. ESSCIRC 2019: 71-74 - [c33]Mario Konijnenburg, Roland Van Wegberg, Shuang Song, Hyunsoo Ha, Wim Sijbers, Jiawei Xu, Stefano Stanzione, Chris van Liempd, Dwaipayan Biswas, Arjan Breeschoten, Peter Vis, Chris Van Hoof, Nick Van Helleputte:
A 769μW Battery-Powered Single-Chip SoC With BLE for Multi-Modal Vital Sign Health Patches. ISSCC 2019: 360-362 - [c32]Hyunsoo Ha, Wim Sijbers, Roland Van Wegberg, Jiawei Xu, Mario Konijnenburg, Peter Vis, Arjan Breeschoten, Shuang Song, Chris Van Hoof, Nick Van Helleputte:
A Bio-Impedance Readout IC With Digital-Assisted Baseline Cancellation for 2-Electrode Measurement. ISSCC 2019: 368-370 - [c31]Qiuyang Lin, Jiawei Xu, Shuang Song, Arjan Breeschoten, Mario Konijnenburg, Mingyi Chen, Chris Van Hoof, Filip Tavernier, Nick Van Helleputte:
A 196μW, Reconfigurable Light-to-Digital Converter with 119dB Dynamic Range, for Wearable PPG/NIRS Sensors. VLSI Circuits 2019: 58- - 2018
- [j9]Jiawei Xu, Mario Konijnenburg, Hyunsoo Ha, Roland Van Wegberg, Shuang Song, Dolores Blanco-Almazán, Chris Van Hoof, Nick Van Helleputte:
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) - [j8]Jiawei Xu, Mario Konijnenburg, Shuang Song, Hyunsoo Ha, Roland Van Wegberg, Massimo Mazzillo, Giorgio Fallica, Chris Van Hoof, Walter De Raedt, Nick Van Helleputte:
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) - [c30]Luke R. Everson, Dwaipayan Biswas, Madhuri Panwar, Dimitrios Rodopoulos, Amit Acharyya, Chris H. Kim, Chris Van Hoof, Mario Konijnenburg, Nick Van Helleputte:
BiometricNet: Deep Learning based Biometric Identification using Wrist-Worn PPG. ISCAS 2018: 1-5 - [c29]Jiawei Xu, Mario Konijnenburg, Budi Lukita, Shuang Song, Hyunsoo Ha, Roland Van Wegberg, Erfan Sheikhi, Massimo Mazzillo, Giorgio Fallica, Walter De Raedt, Chris Van Hoof, Nick Van Helleputte:
A 665μW silicon photomultiplier-based NIRS/EEG/EIT monitoring asic for wearable functional brain imaging. ISSCC 2018: 294-296 - 2016
- [j7]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, Refet Firat Yazicioglu, Nick Van Helleputte:
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) - [c28]Erik Jan Marinissen, Yervant Zorian, Mario Konijnenburg, Chih-Tsun Huang, Ping-Hsuan Hsieh, Peter Cockburn, Jeroen Delvaux, Vladimir Rozic, Bohan Yang, Dave Singelée, Ingrid Verbauwhede, Cedric Mayor, Robert Van Rijsinge, Cocoy Reyes:
IoT: Source of test challenges. ETS 2016: 1-10 - [c27]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, Refet Firat Yazicioglu, Nick Van Helleputte:
28.4 A battery-powered efficient multi-sensor acquisition system with simultaneous ECG, BIO-Z, GSR, and PPG. ISSCC 2016: 480-481 - 2015
- [j6]Nick Van Helleputte, Mario Konijnenburg, Julia Pettine, Dong-Woo Jee, Hyejung Kim, Alonso Morgado, Roland Van Wegberg, Tom Torfs, Rachit Mohan, Arjan Breeschoten, Harmke de Groot, Chris Van Hoof, Refet Firat Yazicioglu:
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
- [j5]Hyejung Kim, Sunyoung Kim, Nick Van Helleputte, Antonio Artés, Mario Konijnenburg, Jos Huisken, Chris Van Hoof, Refet Firat Yazicioglu:
A Configurable and Low-Power Mixed Signal SoC for Portable ECG Monitoring Applications. IEEE Trans. Biomed. Circuits Syst. 8(2): 257-267 (2014) - [j4]Changmoo Kim, Moo-Kyoung Chung, Yeon-Gon Cho, Mario Konijnenburg, Soojung Ryu, Jeongwook Kim:
ULP-SRP: Ultra Low-Power Samsung Reconfigurable Processor for Biomedical Applications. ACM Trans. Reconfigurable Technol. Syst. 7(3): 22:1-22:15 (2014) - [c26]Christian Bachmann, Gert-Jan van Schaik, Ben Busze, Mario Konijnenburg, Yan Zhang, Jan Stuyt, Maryam Ashouei, Guido Dolmans, Tobias Gemmeke, Harmke de Groot:
10.6 A 0.74V 200μW multi-standard transceiver digital baseband in 40nm LP-CMOS for 2.4GHz Bluetooth Smart / ZigBee / IEEE 802.15.6 personal area networks. ISSCC 2014: 186-187 - [c25]Nick Van Helleputte, Mario Konijnenburg, Hyejung Kim, Julia Pettine, Dong-Woo Jee, Arjan Breeschoten, Alonso Morgado, Tom Torfs, Harmke de Groot, Chris Van Hoof, Refet Firat Yazicioglu:
18.3 A multi-parameter signal-acquisition SoC for connected personal health applications. ISSCC 2014: 314-315 - 2013
- [c24]Tobias Gemmeke, Mario Konijnenburg, Christian Bachmann:
In-situ performance monitor employing threshold based notifications (TheBaN). ESSCIRC 2013: 271-274 - [c23]Benjamin Busze, Alex Young, Christian Bachmann, Jing Cao, Johan H. C. van den Heuvel, Martijn Hijdra, Mario Konijnenburg, Kathleen Philips, Arjan Breeschoten, Harmke de Groot:
An energy-aware and scalable UWB Impulse Radio baseband supporting coherent reception. GLOBECOM 2013: 3748-3753 - [c22]Mario Konijnenburg, Yeon-Gon Cho, Maryam Ashouei, Tobias Gemmeke, Changmoo Kim, Jos Hulzink, Jan Stuyt, Mookyung Jung, Jos Huisken, Soojung Ryu, Jungwook Kim, Harmke de Groot:
Reliable and energy-efficient 1MHz 0.4V dynamically reconfigurable SoC for ExG applications in 40nm LP CMOS. ISSCC 2013: 430-431 - 2012
- [j3]Erik Jan Marinissen, Chun-Chuan Chi, Mario Konijnenburg, Jouke Verbree:
A DfT Architecture for 3D-SICs Based on a Standardizable Die Wrapper. J. Electron. Test. 28(1): 73-92 (2012) - [c21]Changmoo Kim, Moo-Kyoung Chung, Yeon-Gon Cho, Mario Konijnenburg, Soojung Ryu, Jeongwook Kim:
ULP-SRP: Ultra low power Samsung Reconfigurable Processor for biomedical applications. FPT 2012: 329-334 - [c20]Xiaoyan Wang, Yikun Yu, Benjamin Busze, Hans W. Pflug, Alex Young, Xiongchuan Huang, Cui Zhou, Mario Konijnenburg, Kathleen Philips, Harmke de Groot:
A meter-range UWB transceiver chipset for around-the-head audio streaming. ISSCC 2012: 450-452 - 2011
- [j2]Maja Vidojkovic, Xiongchuan Huang, Pieter Harpe, Simonetta Rampu, Cui Zhou, Li Huang, Jef van de Molengraft, Koji Imamura, Ben Busze, Frank Bouwens, Mario Konijnenburg, Juan Santana, Arjan Breeschoten, Jos Huisken, Kathleen Philips, Guido Dolmans, Harmke de Groot:
A 2.4 GHz ULP OOK Single-Chip Transceiver for Healthcare Applications. IEEE Trans. Biomed. Circuits Syst. 5(6): 523-534 (2011) - [j1]Jos Hulzink, Mario Konijnenburg, Maryam Ashouei, Arjan Breeschoten, Torfinn Berset, Jos Huisken, Jan Stuyt, Harmke de Groot, Francisco Barat, Johan David, Johan Van Ginderdeuren:
An Ultra Low Energy Biomedical Signal Processing System Operating at Near-Threshold. IEEE Trans. Biomed. Circuits Syst. 5(6): 546-554 (2011) - [c19]Sergej Deutsch, Vivek Chickermane, Brion L. Keller, Subhasish Mukherjee, Mario Konijnenburg, Erik Jan Marinissen, Sandeep Kumar Goel:
Automation of 3D-DfT Insertion. Asian Test Symposium 2011: 395-400 - [c18]Georgios N. Selimis, Mario Konijnenburg, Maryam Ashouei, Jos Huisken, Harmke de Groot, Vincent van der Leest, Geert Jan Schrijen, Marten van Hulst, Pim Tuyls:
Evaluation of 90nm 6T-SRAM as Physical Unclonable Function for secure key generation in wireless sensor nodes. ISCAS 2011: 567-570 - [c17]Maryam Ashouei, Jos Hulzink, Mario Konijnenburg, Jun Zhou, Filipa Duarte, Arjan Breeschoten, Jos Huisken, Jan Stuyt, Harmke de Groot, Francisco Barat, Johan David, Johan Van Ginderdeuren:
A voltage-scalable biomedical signal processor running ECG using 13pJ/cycle at 1MHz and 0.4V. ISSCC 2011: 332-334 - [c16]Maja Vidojkovic, Xiongchuan Huang, Pieter Harpe, Simonetta Rampu, Cui Zhou, Li Huang, Koji Imamura, Ben Busze, Frank Bouwens, Mario Konijnenburg, Juan Santana, Arjan Breeschoten, Jos Huisken, Guido Dolmans, Harmke de Groot:
A 2.4GHz ULP OOK single-chip transceiver for healthcare applications. ISSCC 2011: 458-460 - 2010
- [c15]Erik Jan Marinissen, Chun-Chuan Chi, Jouke Verbree, Mario Konijnenburg:
3D DfT architecture for pre-bond and post-bond testing. 3DIC 2010: 1-8 - [c14]Erik Jan Marinissen, Jouke Verbree, Mario Konijnenburg:
A structured and scalable test access architecture for TSV-based 3D stacked ICs. VTS 2010: 269-274
2000 – 2009
- 2006
- [c13]Xinyue Fan, Will R. Moore, Camelia Hora, Mario Konijnenburg, Guido Gronthoud:
A Gate-Level Method for Transistor-Level Bridging Fault Diagnosis. VTS 2006: 266-271
1990 – 1999
- 1999
- [c12]M. H. Konijnenburg, Hans van der Linden, Ad J. van de Goor:
Fault (In)Dependent Cost Estimates and Conflict-Directed Backtracking to Guide Sequential Circuit Test Generation. Asian Test Symposium 1999: 185-191 - [c11]M. H. Konijnenburg, J. Th. van der Linden, Ad J. van de Goor:
Illegal State Space Identification for Sequential Circuit Test Generation. DATE 1999: 741-746 - [c10]M. H. Konijnenburg, J. Th. van der Linden, Ad J. van de Goor:
Testability of the Philips 80C51 micro-controller. ITC 1999: 820-829 - [c9]Mario Konijnenburg, Hans van der Linden, Jeroen Geuzebroek:
Benchmarking DAT with the ITC'99 ATPG Benchmarks. ITC 1999: 1127 - 1998
- [c8]J. Th. van der Linden, M. H. Konijnenburg, Ad J. van de Goor:
Complete Search in Test Generation for Industrial Circuits with Improved Bus-Conflict Detection. Asian Test Symposium 1998: 212- - 1997
- [c7]M. H. Konijnenburg, J. Th. van der Linden, Ad J. van de Goor:
Sequential Test Generation with Advanced Illegal State Search. ITC 1997: 733-742 - 1996
- [c6]J. Th. van der Linden, M. H. Konijnenburg, Ad J. van de Goor:
Circuit Partitioned Automatic Test Pattern Generation Constrained by Three-State Buses and Restrictors. Asian Test Symposium 1996: 29-33 - [c5]M. H. Konijnenburg, J. Th. van der Linden, Ad J. van de Goor:
Accelerated Compact Test Set Generation for Three-State Circuits. ITC 1996: 29-38 - 1995
- [c4]M. H. Konijnenburg, J. Th. van der Linden, Ad J. van de Goor:
Compact test sets for industrial circuits. VTS 1995: 358-366 - 1994
- [c3]J. Th. van der Linden, M. H. Konijnenburg, Ad J. van de Goor:
Parallel Pattern Fast Fault Simulation for Three-State Circuits and Bidirectional I/O. ITC 1994: 604-613 - [c2]J. Th. van der Linden, M. H. Konijnenburg, Ad J. van de Goor:
Test generation and three-state elements, buses, and bidirectionals. VTS 1994: 114-121 - 1993
- [c1]M. H. Konijnenburg, J. Th. van der Linden, Ad J. van de Goor:
Test Pattern Generation with Restrictors. ITC 1993: 598-605
Coauthor Index
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