Rui P. Martins

What is he best known for?

The fields of study he is best known for:

• Electrical engineering
• Amplifier
• Quantum mechanics

His primary areas of study are Electronic engineering, Electrical engineering, CMOS, Successive approximation ADC and Power. The Electronic engineering study combines topics in areas such as Low-pass filter, Capacitive sensing, Chip, Switched capacitor and Attenuation. His research investigates the link between Electrical engineering and topics such as Energy harvesting that cross with problems in Charge pump, ISM band, Gain stage and Cover.

His studies in CMOS integrate themes in fields like Low voltage, Converters, Offset calibration, Sensitivity and Transistor. His Successive approximation ADC study combines topics in areas such as Spurious-free dynamic range, Preamplifier, Interleaving, Dissipation and Calibration. His Power research includes elements of Microprocessor, Phase, Enhanced Data Rates for GSM Evolution and Control theory.

His most cited work include:

• A 10-bit 100-MS/s Reference-Free SAR ADC in 90 nm CMOS (455 citations)
• Miniaturized microstrip lowpass filter with wide stopband using double equilateral U-shaped defected ground structure (153 citations)
• Transceiver architecture selection: Review, state-of-the-art survey and case study (137 citations)

What are the main themes of his work throughout his whole career to date?

His main research concerns Electronic engineering, CMOS, Electrical engineering, Capacitor and Voltage. Rui P. Martins has included themes like Power, Comparator, Successive approximation ADC and Operational amplifier in his Electronic engineering study. As a member of one scientific family, Rui P. Martins mostly works in the field of CMOS, focusing on Voltage-controlled oscillator and, on occasion, Phase-locked loop.

His Electrical engineering study frequently draws connections to other fields, such as Energy harvesting. His research in Capacitor intersects with topics in Capacitance, Converters and Control theory. His study looks at the relationship between Optoelectronics and fields such as Microfluidics, as well as how they intersect with chemical problems.

He most often published in these fields:

• Electronic engineering (57.36%)
• CMOS (49.23%)
• Electrical engineering (37.58%)

What were the highlights of his more recent work (between 2019-2021)?

• CMOS (49.23%)
• Electrical engineering (37.58%)
• Electronic engineering (57.36%)

In recent papers he was focusing on the following fields of study:

His primary areas of investigation include CMOS, Electrical engineering, Electronic engineering, Voltage and Capacitor. His CMOS research integrates issues from Power, Rectifier, Voltage-controlled oscillator and Phase noise. His work focuses on many connections between Electrical engineering and other disciplines, such as Electrical efficiency, that overlap with his field of interest in Maximum power transfer theorem.

The various areas that Rui P. Martins examines in his Electronic engineering study include Amplifier and Successive approximation ADC. He has researched Voltage in several fields, including Topology and Energy conversion efficiency. His biological study deals with issues like Converters, which deal with fields such as Duty cycle.

Between 2019 and 2021, his most popular works were:

• A digital microfluidic system with 3D microstructures for single-cell culture (7 citations)
• A digital microfluidic system with 3D microstructures for single-cell culture (7 citations)
• A 1.6-GS/s 12.2-mW Seven-/Eight-Way Split Time-Interleaved SAR ADC Achieving 54.2-dB SNDR With Digital Background Timing Mismatch Calibration (6 citations)

In his most recent research, the most cited papers focused on:

• Electrical engineering
• Quantum mechanics
• Amplifier

Rui P. Martins focuses on CMOS, Electronic engineering, Capacitor, Voltage and Electrical engineering. Rui P. Martins interconnects Inductor, NMOS logic and Topology in the investigation of issues within CMOS. His Electronic engineering study incorporates themes from Signal-to-noise ratio and Successive approximation ADC, Effective resolution bandwidth.

His Capacitor research is multidisciplinary, incorporating elements of Rectifier, Logic gate, Linearity, Noise shaping and Bandwidth. His research in the fields of Buck converter overlaps with other disciplines such as Cell culture, Microstructure and Pulmonary surfactant. DBc is the focus of his Electrical engineering research.

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