2023 - Research.com Electronics and Electrical Engineering in Netherlands Leader Award
2022 - Research.com Electronics and Electrical Engineering in Netherlands Leader Award
1997 - IEEE Fellow For contributions to the design and analysis of analog integrated circuits.
Johan H. Huijsing mainly focuses on Electronic engineering, Electrical engineering, CMOS, Operational amplifier and Direct-coupled amplifier. The various areas that Johan H. Huijsing examines in his Electronic engineering study include Instrumentation amplifier, Compensation, Chip and Input offset voltage. His study in Chopper, Electronic circuit, Voltage reference, Capacitor and Bandwidth is carried out as part of his Electrical engineering studies.
His CMOS research incorporates elements of Delta-sigma modulation and Transistor, Bipolar junction transistor, Voltage. His study in Operational amplifier is interdisciplinary in nature, drawing from both Low voltage, Transconductance and Differential amplifier. Johan H. Huijsing works mostly in the field of Direct-coupled amplifier, limiting it down to topics relating to Cascade amplifier and, in certain cases, Capacitive sensing.
Johan H. Huijsing mainly investigates Electronic engineering, Electrical engineering, Operational amplifier, CMOS and Amplifier. His studies deal with areas such as Electronic circuit, Delta-sigma modulation, Instrumentation amplifier, Chopper and Input offset voltage as well as Electronic engineering. In general Electrical engineering, his work in Voltage, Transistor, Capacitor and Bipolar junction transistor is often linked to Offset linking many areas of study.
He has included themes like Low voltage and Differential amplifier in his Operational amplifier study. As part of the same scientific family, Johan H. Huijsing usually focuses on CMOS, concentrating on Chip and intersecting with Flow measurement. His work on Frequency compensation as part of general Amplifier study is frequently connected to Instrumentation, therefore bridging the gap between diverse disciplines of science and establishing a new relationship between them.
Johan H. Huijsing spends much of his time researching Electrical engineering, Electronic engineering, Amplifier, Operational amplifier and Chopper. His study in the field of CMOS, Capacitor and Voltage is also linked to topics like Offset and Temperature measurement. His research integrates issues of Direct-coupled amplifier, Operational transconductance amplifier, Ripple, Instrumentation amplifier and Input offset voltage in his study of Electronic engineering.
His research in Amplifier intersects with topics in Parasitic capacitance, High input and Infrasound. His work carried out in the field of Operational amplifier brings together such families of science as Transfer function and Buffer amplifier. His Chopper study also includes fields such as
Johan H. Huijsing mostly deals with Electronic engineering, Electrical engineering, Instrumentation amplifier, Operational amplifier and Input offset voltage. His Electronic engineering study combines topics from a wide range of disciplines, such as Direct-coupled amplifier, Capacitor, Integrated circuit, Chopper and Amplifier. His Direct-coupled amplifier research is multidisciplinary, relying on both Operational transconductance amplifier, Current sense amplifier and Operational amplifier applications.
His work on CMOS and Noise as part of general Electrical engineering research is frequently linked to Temperature measurement, thereby connecting diverse disciplines of science. His Instrumentation amplifier study incorporates themes from Resistor, Ripple, Open-loop gain and Linearity. His Operational amplifier research focuses on subjects like Control theory, which are linked to Differential amplifier, Fully differential amplifier and Charge amplifier.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
A compact power-efficient 3 V CMOS rail-to-rail input/output operational amplifier for VLSI cell libraries
R. Hogervorst;J.P. Tero;R.G.H. Eschauzier;J.H. Huijsing.
international solid-state circuits conference (1994)
A CMOS smart temperature sensor with a 3/spl sigma/ inaccuracy of /spl plusmn/0.1/spl deg/C from -55/spl deg/C to 125/spl deg/C
M.A.P. Pertijs;A. Niederkorn;Xu Ma;B. McKillop.
international solid-state circuits conference (2005)
A 100-MHz 100-dB operational amplifier with multipath nested Miller compensation structure
R.G.H. Eschauzier;L.P.T. Kerklaan;J.H. Huijsing.
international solid-state circuits conference (1992)
A CMOS nested chopper instrumentation amplifier with 100 nV offset
A. Bakker;K. Thiele;J.H. Huijsing.
international solid-state circuits conference (2000)
Low-voltage operational amplifier with rail-to-rail input and output ranges
J. Fonderie;M.M. Maris;E.J. Schnitger;J.H. Huijsing.
international solid-state circuits conference (1989)
A Chopper Current-Feedback Instrumentation Amplifier With a 1 mHz $1/f$ Noise Corner and an AC-Coupled Ripple Reduction Loop
Rong Wu;Kofi A.A. Makinwa;Johan H. Huijsing.
international solid-state circuits conference (2009)
Micropower CMOS temperature sensor with digital output
A. Bakker;J.H. Huijsing.
IEEE Journal of Solid-state Circuits (1996)
Frequency Compensation Techniques for Low-Power Operational Amplifiers
Rudy G. H. Eschauzier;Johan H. Huijsing.
Compact low-voltage power-efficient operational amplifier cells for VLSI
K.-J. De Langen;J.H. Huijsing.
IEEE Journal of Solid-state Circuits (1998)
A 1.8 $\mu$ W 60 nV $/\surd$ Hz Capacitively-Coupled Chopper Instrumentation Amplifier in 65 nm CMOS for Wireless Sensor Nodes
Qinwen Fan;F. Sebastiano;J. H. Huijsing;K. A. A. Makinwa.
IEEE Journal of Solid-state Circuits (2011)
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