What is he best known for?
The fields of study he is best known for:
- Electrical engineering
- Transistor
- Amplifier
His scientific interests lie mostly in Electrical engineering, Electronic engineering, CMOS, Field-effect transistor and MOSFET.
His work on Very-large-scale integration as part of general Electronic engineering study is frequently linked to Linear regression, therefore connecting diverse disciplines of science.
Kwyro Lee has included themes like Capacitive sensing, NMOS logic, Logic gate and Local oscillator in his CMOS study.
His Field-effect transistor research integrates issues from Optoelectronics, Condensed matter physics, Doping, Fermi gas and Analytical chemistry.
His studies deal with areas such as Algorithm, Computational physics and Capacitor as well as MOSFET.
As part of one scientific family, Kwyro Lee deals mainly with the area of Noise figure, narrowing it down to issues related to the Transconductance, and often Gilbert cell.
His most cited work include:
- Highly linear receiver front-end adopting MOSFET transconductance linearization by multiple gated transistors (298 citations)
- Model for modulation doped field effect transistor (188 citations)
- Semiconductor Device Modeling For VLSI (182 citations)
What are the main themes of his work throughout his whole career to date?
Kwyro Lee mainly investigates Electronic engineering, Electrical engineering, CMOS, Optoelectronics and Transistor.
The study incorporates disciplines such as Low-noise amplifier, Y-factor, Noise figure, Noise temperature and Signal in addition to Electronic engineering.
Amplifier, Voltage, Phase noise, Radio frequency and MOSFET are among the areas of Electrical engineering where he concentrates his study.
His CMOS study combines topics in areas such as Voltage-controlled oscillator, Tuner, NMOS logic and Gate oxide.
His Optoelectronics research includes elements of Field-effect transistor, Low voltage and Nitride.
His Field-effect transistor research incorporates elements of Threshold voltage, Transconductance and Doping.
He most often published in these fields:
- Electronic engineering (46.38%)
- Electrical engineering (45.65%)
- CMOS (30.43%)
What were the highlights of his more recent work (between 2007-2018)?
- Electronic engineering (46.38%)
- Electrical engineering (45.65%)
- CMOS (30.43%)
In recent papers he was focusing on the following fields of study:
Kwyro Lee spends much of his time researching Electronic engineering, Electrical engineering, CMOS, Noise figure and Low-noise amplifier.
His research in Electronic engineering intersects with topics in Loop gain, Signal, Tuner, Capacitor and Common gate.
His study focuses on the intersection of Electrical engineering and fields such as Silicon on insulator with connections in the field of RF switch and MOSFET.
Kwyro Lee interconnects RF front end, Radio frequency, Bandwidth and Wideband in the investigation of issues within CMOS.
In his study, which falls under the umbrella issue of Noise figure, Current mirror and Noise spectral density is strongly linked to Direct-coupled amplifier.
His research integrates issues of Noise, Noise temperature and Differential amplifier in his study of Low-noise amplifier.
Between 2007 and 2018, his most popular works were:
- A Wideband CMOS Low Noise Amplifier Employing Noise and IM2 Distortion Cancellation for a Digital TV Tuner (115 citations)
- A CMOS Active Feedback Balun-LNA With High IIP2 for Wideband Digital TV Receivers (69 citations)
- Low noise capacitive sensor for multi-touch mobile handset's applications (54 citations)
In his most recent research, the most cited papers focused on:
- Electrical engineering
- Semiconductor
- Transistor
Kwyro Lee focuses on Electronic engineering, Electrical engineering, Noise figure, Low-noise amplifier and Amplifier.
Particularly relevant to CMOS is his body of work in Electronic engineering.
His work carried out in the field of CMOS brings together such families of science as Transmitter, Radio frequency, Filter and Transceiver.
His Electrical engineering research includes themes of Liquid-crystal display and Noise.
The various areas that Kwyro Lee examines in his Low-noise amplifier study include Direct-coupled amplifier, Loop gain, Fully differential amplifier, Common gate and Common source.
His Effective input noise temperature research incorporates themes from Noise temperature, Y-factor, Transconductance and Gain compression.
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