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Jean-Baptiste Kammerer
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2020 – today
- 2023
- [c26]Denis Rideau, Wilfried Uhring, R. A. Bianchi, Rémi Helleboid, Gabriel Mugny, Jérémy Grebot, Jean-Robert Manouvrier, R. Neri, F. Brun, Mohammadreza Dolatpoor Lakeh, Sven Rink, Jean-Baptiste Kammerer, Christophe Lallement, E. Lacombe, Dominique Golanski, Bruce Rae, T. M. Bah, F. Twaddle, V. Quenette, G. Marchand, Christel Buj, R. Fillon, Y. Henrion, Isobel Nicholson, Megan Agnew, M. Basset, R. Perrier, M. Al-Rawhani, Bastien Mamdy, S. Pellegrin, Gilles Gouget, P. Maciazek, Andre Juge, A. Dartigues, Hélène Wehbe-Alause:
Direct Measurements and Modeling of Avalanche Dynamics and Quenching in SPADs. ESSDERC 2023: 144-147 - 2022
- [c25]Sven Rink, V. Quenette, Jean-Robert Manouvrier, Andre Juge, Gilles Gouget, Denis Rideau, R. A. Bianchi, Dominique Golanski, Bastien Mamdy, Jean-Baptiste Kammerer, Wilfried Uhring, Christophe Lallement, Sara Pellegrini, Megan Agnew, Bruce Rae:
A self-sustaining Single Photon Avalanche Diode Model. ESSDERC 2022: 281-284 - [c24]Hugo Nicolas, Joris Pascal, Luc Hébrard, Jean-Baptiste Kammerer, Ricardo C. Sousa, Ariam Mora-Hernández, Ioan Lucian Prejbeanu:
A Magnetic Sensor Based on a Nanometric Spin Transfer Torque Magnetic Tunnel Junction Suitable for Monolithic Integration. IEEE SENSORS 2022: 1-4 - [c23]Jean-Baptiste Kammerer, Maroua Garci, Achraf Kaïd, Fabrice Roqueta:
Multidomain Modeling for Reliability Evaluation of Devices and Microsystems Using Verilog-A. MIXDES 2022: 51-56 - 2021
- [j8]Enagnon Aguénounon, Safa Razavinejad, Jean-Baptiste Schell, Mohammadreza Dolatpoor Lakeh, Wassim Khaddour, Foudil Dadouche, Jean-Baptiste Kammerer, Laurent Fesquet, Wilfried Uhring:
Design and Characterization of an Asynchronous Fixed Priority Tree Arbiter for SPAD Array Readout. Sensors 21(12): 3949 (2021) - [j7]Mohammadreza Dolatpoor Lakeh, Jean-Baptiste Kammerer, Enagnon Aguénounon, Dylan Issartel, Jean-Baptiste Schell, Sven Rink, Andreia Cathelin, Françis Calmon, Wilfried Uhring:
An Ultrafast Active Quenching Active Reset Circuit with 50% SPAD Afterpulsing Reduction in a 28 nm FD-SOI CMOS Technology Using Body Biasing Technique. Sensors 21(12): 4014 (2021) - [c22]Mohammadreza Dolatpoor Lakeh, Jean-Baptiste Kammerer, Jean-Baptiste Schell, Dylan Issartel, Françis Calmon, Andreia Cathelin, Wilfried Uhring:
An Active Quenching Circuit for a Native 3D SPAD Pixel in a 28 nm CMOS FDSOI Technology. NEWCAS 2021: 1-4 - 2020
- [c21]Mohammadreza Dolatpoor Lakeh, Jean-Baptiste Kammerer, Wilfried Uhring, Jean-Baptiste Schell, Françis Calmon:
An Ultrafast Active Quenching Circuit for SPAD in CMOS 28nm FDSOI Technology. IEEE SENSORS 2020: 1-4 - [c20]Laurent Malané, Jean-Baptiste Kammerer, Luc Hébrard, Vinciane Chereau:
Compact Model of Ring-Core Sensing Element of 2D Fluxgate Magnetometer. IEEE SENSORS 2020: 1-4 - [c19]Laurent Malané, Jean-Baptiste Kammerer, Lux Hébrard, Vinciane Chereau:
Design methodology of square wave excited ring core for fluxgate sensor. IEEE SENSORS 2020: 1-4 - [c18]Mathieu Hugoud, Wilfried Uhring, Jean-Baptiste Kammerer, Jean-Baptiste Schell:
A High Dynamic Range High Speed Pixel Operating at 100 Million Frames Per Second. NEWCAS 2020: 291-294
2010 – 2019
- 2019
- [j6]Morgan Madec, Luc Hébrard, Jean-Baptiste Kammerer, Alexi Bonament, Elise Rosati, Christophe Lallement:
Multiphysics Simulation of Biosensors Involving 3D Biological Reaction-Diffusion Phenomena in a Standard Circuit EDA Environment. IEEE Trans. Circuits Syst. I Regul. Pap. 66-I(6): 2188-2197 (2019) - 2018
- [j5]Elise Rosati, Morgan Madec, Jean-Baptiste Kammerer, Luc Hébrard, Christophe Lallement, Jacques Haiech:
Efficient Modeling and Simulation of Space-Dependent Biological Systems. J. Comput. Biol. 25(8): 917-933 (2018) - [c17]Jean-Baptiste Kammerer, Octavian Maciu, Imane Malass, Jean-Pierre Le Normand, Wilfried Uhring:
Skew Reduction on a long transmission line using multiple local DLLs for high-speed imagery. NEWCAS 2018: 121-124 - [c16]Wilfried Uhring, Laurent Millet, Bertrand Misischi, Fatah Rarbi, Fabrice Guellec, Daniel Dzahini, Octavian Maciu, Jean-Baptiste Kammerer, Gilles Sicard:
A Scalable Architecture for Multi Millions Frames per Second CMOS Sensor With Digital Storage. NEWCAS 2018: 252-255 - 2016
- [c15]Octavian Maciu, Wilfried Uhring, Jean-Baptiste Kammerer, Jean-Pierre Le Normand, Norbert Dumas, Foudil Dadouche, Luc Hébrard:
Sub-nanosecond gated photon counting for high spatial resolution CMOS imagers. NEWCAS 2016: 1-4 - 2015
- [j4]Maroua Garci, Jean-Baptiste Kammerer, Luc Hébrard:
Towards electro-thermo-mechanical simulation of integrated circuits in standard CAD environment. Microelectron. J. 46(12): 1121-1128 (2015) - [c14]Simon Paulus, Jean-Baptiste Kammerer, Joris Pascal, Calogero Bona, Luc Hébrard:
On-chip analog PI controller for calibration of Rogowski coils. ICM 2015: 103-106 - [c13]Elise Rosati, Morgan Madec, Jean-Baptiste Kammerer, Abir Rezgui, Christophe Lallement, Jacques Haiech:
Verilog-A compact space-dependent model for biology. MIXDES 2015: 171-176 - [c12]Simon Paulus, Jean-Baptiste Kammerer, Joris Pascal, Luc Hébrard:
Continuous calibration of Rogowski coil current transducer. NEWCAS 2015: 1-4 - 2014
- [j3]Jean-Christophe Krencker, Jean-Baptiste Kammerer, Yannick Hervé, Luc Hébrard:
Electro-thermal high-level modeling of integrated circuits. Microelectron. J. 45(5): 491-499 (2014) - [c11]Simon Paulus, Jean-Baptiste Kammerer, Joris Pascal, Luc Hébrard:
Integrated front-end for on line continuous calibration of Rogowski coil current transducer. ICECS 2014: 391-394 - [c10]Maroua Garci, Jean-Baptiste Kammerer, Luc Hébrard:
Towards multiphysics simulations of integrated circuits. ICECS 2014: 830-833 - [c9]Maroua Garci, Jean-Baptiste Kammerer, Luc Hébrard:
Compact modeling and electro-thermal simulation of hot carriers effect in analog circuits. NEWCAS 2014: 125-128 - [c8]Morgan Madec, Laurent Osberger, Jean-Baptiste Schell, Jean-Baptiste Kammerer, Christophe Lallement, Luc Hébrard:
Compact modeling of offset sources in vertical hall-effect devices. NEWCAS 2014: 253-256 - 2013
- [c7]Jean-Baptiste Schell, Jean-Baptiste Kammerer, Luc Hébrard, Elodie Breton, Daniel Gounot, Loïc Cuvillon, Michel de Mathelin:
Towards a Hall effect magnetic tracking device for MRI. EMBC 2013: 2964-2967 - [c6]Morgan Madec, Jean-Baptiste Schell, Jean-Baptiste Kammerer, Christophe Lallement, Luc Hébrard:
An improved compact model of the electrical behaviour of the 5-contact vertical hall-effect device. NEWCAS 2013: 1-4 - 2012
- [c5]Morgan Madec, Jean-Baptiste Schell, Jean-Baptiste Kammerer, Christophe Lallement, Luc Hébrard:
Compact modeling of vertical hall-effect devices: Electrical behavior. NEWCAS 2012: 213-216 - [c4]Jean-Baptiste Schell, Jean-Baptiste Kammerer, Luc Hébrard, Elodie Breton, Daniel Gounot, Loïc Cuvillon, Michel de Mathelin:
CMOS 3D Hall probe for magnetic field measurement in MRI scanner. NEWCAS 2012: 517-520
2000 – 2009
- 2009
- [j2]Benoit Dubois, Jean-Baptiste Kammerer, Luc Hébrard, Francis Braun:
Modelling of hot-carrier degradation and its application for analog design for reliability. Microelectron. J. 40(9): 1274-1280 (2009) - 2007
- [c3]Benoit Dubois, Jean-Baptiste Kammerer, Luc Hébrard, Francis Braun:
Analytical Modeling of Hot-Carrier Induced Degradation of MOS Transistor for Analog Design for Reliability. ISQED 2007: 53-58 - 2006
- [c2]Fabien Prégaldiny, Jean-Baptiste Kammerer, Christophe Lallement:
Compact Modeling and Applications of CNTFETs for Analog and Digital Circuit Design. ICECS 2006: 1030-1033 - 2005
- [j1]Luc Hébrard, Jean-Baptiste Kammerer, Francis Braun:
A Chopper Stabilized Biasing Circuit Suitable for Cascaded Wheatstone-Bridge-Like Sensors. IEEE Trans. Circuits Syst. I Regul. Pap. 52-I(8): 1653-1665 (2005) - 2002
- [c1]Jean-Baptiste Kammerer, Luc Hébrard, Vincent Frick, Philippe Poure, Francis Braun:
Design and modelling of a voltage controlled N-well resistor using the MOS tunneling diode structure. ICECS 2002: 1123-1126
Coauthor Index
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