2004 - IEEE Fellow For contributions to single phase clocking and high speed CMOS circuits.
His primary areas of study are Electronic engineering, CMOS, Electrical engineering, Transistor and Quantum tunnelling. The concepts of his Electronic engineering study are interwoven with issues in Clock signal, Synchronous circuit, Signal and Synchronization. His CMOS study incorporates themes from Electronic circuit, Chip, Very-large-scale integration, Integrated circuit and Dynamic logic.
His Electrical engineering research includes elements of Shaping and Low-power electronics. His study in Transistor is interdisciplinary in nature, drawing from both Hydrogen, Field effect, Duty cycle and Conductive polymer, Polymer. His work carried out in the field of Quantum tunnelling brings together such families of science as Atomic physics, Charge carrier and Analytical chemistry.
Christer Svensson focuses on Electronic engineering, Electrical engineering, CMOS, Transistor and Optoelectronics. His research integrates issues of Sampling, Electronic circuit and Chip in his study of Electronic engineering. In most of his Electrical engineering studies, his work intersects topics such as Low-power electronics.
His biological study spans a wide range of topics, including Voltage, Pipeline, Wideband and Integrated circuit. His work on Optoelectronics is being expanded to include thematically relevant topics such as Field-effect transistor.
His primary areas of investigation include Electronic engineering, Electrical engineering, CMOS, Detector and Amplifier. His Electronic engineering research is multidisciplinary, incorporating perspectives in Sampling, Transistor, Communication channel and Chip. His Transistor research is multidisciplinary, incorporating elements of Capacitance, Power optimization, Design methods and Low-power electronics.
His study in Wideband, Envelope detector, Harmonics, Noise figure and Electronic circuit falls under the purview of Electrical engineering. His work on Effective number of bits as part of his general CMOS study is frequently connected to Fall time, thereby bridging the divide between different branches of science. As part of the same scientific family, Christer Svensson usually focuses on Detector, concentrating on Pixel and intersecting with Photon counting detector, Phase detector characteristic and Pulse wave.
Christer Svensson spends much of his time researching Electronic engineering, Detector, Photon counting, Optics and Electrical engineering. Christer Svensson mostly deals with Logic synthesis in his studies of Electronic engineering. His Detector research incorporates elements of Pixel, Optoelectronics, Frequency modulation and Direct-conversion receiver.
The Optics study combines topics in areas such as Medical physics, Application-specific integrated circuit and Silicon. As part of his studies on Electrical engineering, he often connects relevant subjects like Low-power electronics. His research investigates the connection between CMOS and topics such as Harmonic analysis that intersect with problems in Waveform.
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High-speed CMOS circuit technique
J. Yuan;C. Svensson.
IEEE Journal of Solid-state Circuits (1989)
A hydrogen−sensitive MOS field−effect transistor
I. Lundström;S. Shivaraman;C. Svensson;L. Lundkvist.
Applied Physics Letters (1975)
Negative bias stress of MOS devices at high electric fields and degradation of MNOS devices
Kjell O. Jeppson;Christer M. Svensson.
Journal of Applied Physics (1977)
Impact of CMOS technology scaling on the atmospheric neutron soft error rate
P. Hazucha;C. Svensson.
IEEE Transactions on Nuclear Science (2000)
A hydrogen-sensitive Pd-gate MOS transistor
K. I. Lundström;M. S. Shivaraman;C. M. Svensson.
Journal of Applied Physics (1975)
Power consumption estimation in CMOS VLSI chips
Dake Liu;C. Svensson.
IEEE Journal of Solid-state Circuits (1994)
Field‐effect mobility of poly(3‐hexylthiophene)
A. Assadi;C. Svensson;M. Willander;O. Inganäs.
Applied Physics Letters (1988)
Low frequency noise in MOS transistors—I Theory
S. Christensson;I. Lundström;C. Svensson.
Solid-state Electronics (1968)
Trading speed for low power by choice of supply and threshold voltages
D. Liu;C. Svensson.
IEEE Journal of Solid-state Circuits (1993)
New single-clock CMOS latches and flipflops with improved speed and power savings
Jiren Yuan;C. Svensson.
IEEE Journal of Solid-state Circuits (1997)
Linköping University
Linköping University
Linköping University
Chalmers University of Technology
University of Twente
University of Pavia
University of Waterloo
Ludwig-Maximilians-Universität München
Intel (United States)
University of Milan
Profile was last updated on December 6th, 2021.
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