Your search keyword '"Mantooth, Homer Alan"' showing total 4 results

1. Datasheet-Driven Compact Model of Silicon Carbide Power MOSFET Including Third-Quadrant Behavior.

Author

Rashid, Arman Ur, Hossain, Md Maksudul, Emon, Asif Imran, and Mantooth, Homer Alan

Subjects

METAL oxide semiconductor field-effect transistors, ELECTRIC current rectifiers, POWER electronics, CONVERTERS (Electronics), SILICON carbide, SEMICONDUCTOR devices, PIN diodes

Abstract

This article presents a simulation model of silicon carbide (SiC) power MOSFET that accurately predicts both the static and dynamic third-quadrant behavior without compromising the first-quadrant's accuracy. Unlike existing models, this model features an asymmetric third-quadrant behavior for MOSFET characteristics necessary for the accurate synchronous rectifier simulations. Moreover, it includes the gate-dependent body diode behavior, essential for the accurate prediction of freewheeling high-side device behavior in half-bridge configurations with significant gate voltage oscillation. The model also includes reverse recovery characteristics for the accurate overshoot and power loss prediction. Despite having these added features, the model demonstrates good convergence and efficiency due to the replacement of conditional piecewise equations with continuous ones consisting of weighted variables. The model's convergence capability and efficiency have been verified by simulating a five-level cascaded H-bridge multilevel inverter. The model's superior efficiency and accuracy have been validated by comparing it with an established SiC power MOSFET model. Also, an easy-to-follow parameter extraction procedure is documented that only requires data commonly available in commercial datasheets for broader utility. Considering accuracy, efficiency, and convenience, the model is useful for all power electronics converter applications. [ABSTRACT FROM AUTHOR]

Published

2021

2. Adaptive Multi-Level Active Gate Drivers for SiC Power Devices.

Author

Zhao, Shuang, Dearien, Audrey, Wu, Yuheng, Farnell, Chris, Rashid, Arman Ur, Luo, Fang, and Mantooth, Homer Alan

Subjects

SILICON carbide, TRAJECTORY optimization, GATES, SILICON nanowires, SEMICONDUCTOR devices, LOGIC circuits

Abstract

State-of-the-art silicon carbide (SiC) power devices provide superior performance over silicon devices with much higher switching frequencies/speed and lower losses. High switching speed is preferred for achieving low switching loss, yet high dv/dt and di/dt can result in high EMI emission during switching transients. These switching dynamics can be controlled by the device gate driving strategy. The multi-level active gate driver (AGD) approach is able to tradeoff the switching losses with the dv/dt and di/dt for each switching transient. A novel three-level (3-L) AGD for SiC power mosfet trajectory control is introduced. Its turn-off profile has a shorter turn-off delay compared to any existing methodology. Accordingly, a comprehensive datasheet-driven trajectory model for the online model-based optimization of the 3-L turn-off is introduced. The main factors that impact the 3-L turn-off performance are analyzed with this model. The experimental results of double pulse tests validate the approach. Additionally, the benefits of the proposed 3-L AGD method over two-stage turn-off and conventional gate drivers on the market are illustrated through experiments. [ABSTRACT FROM AUTHOR]

Published

2020

3. A Datasheet Driven Unified Si/SiC Compact IGBT Model for N-Channel and P-Channel Devices.

Author

Perez, Sonia, Kotecha, Ramchandra M., Rashid, Arman Ur, Hossain, Md Maksudul, Vrotsos, Tom, Francis, Anthony Matthew, Mantooth, Homer Alan, Santi, Enrico, and Hudgins, Jerry L.

Subjects

INSULATED gate bipolar transistors, ELECTRIC circuit design & construction, DC-AC converters, ELECTRON tube grids, POWER electronics

Abstract

This paper presents a unified physics-based insulated-gate bipolar transistor (IGBT) compact model for circuit simulation that predicts the performance of both Si and SiC, n- and p-channel devices. The model can predict the detailed switching waveforms of these technologies based on its charge-based formulation. Further, this compact IGBT model is presented alongside a unique datasheet-driven parameter extraction process. The parameter extraction process enables users to quickly extract model parameters from data typically published without the need of taking physical measurements. The model has been validated with both Si and SiC devices for static and dynamic characteristics. The SiC IGBTs used for validation are a 12.5-kV n-channel device and a 13-kV p-channel device, while the Si IGBT chosen was IXDH30N120 from IXYS Corp. (Milpitas, CA, USA). This is the only IGBT model that predicts the performance of both n- and p-channel, Si and SiC devices, providing more freedom for the development of complex power electronics circuit designs. The convergence of the model has been verified by implementing a complex circuit consisting of both a dc–dc converter and a dc–ac inverter. The results presented here show that the unified model can be used to describe the behavior of a wide range of Si and SiC IGBT circuits. This paper is accompanied by a Verilog-A source code and a power point file demonstrating the model parameter extraction sequence. [ABSTRACT FROM AUTHOR]

Published

2019

4. A SiC NMOS Linear Voltage Regulator for High-Temperature Applications.

Author

Valle-Mayorga, Javier A., Rahman, Ashfaqur, and Mantooth, Homer Alan

Subjects

INTEGRATED circuits, SILICON carbide, VOLTAGE regulators, HIGH temperatures, METAL oxide semiconductor field-effect transistors, WIDE gap semiconductors

Abstract

The first SiC integrated circuit linear voltage regulator is reported. The voltage regulator uses a 20-V supply and generates an output of 15 V, adjustable down to 10 V. It was designed for loads of up to 2 A over a temperature range of 25-225 °C. It was, however, successfully tested up to 300 °C. The voltage regulator demonstrated load regulations of 1.49% and 9% for a 2-A load at temperatures of 25 and 300 °C, respectively. However, the load regulation is less than 2% up to 300 °C for a 1-A load. The line regulation with a 2-A load at 25 and 300 °C was 17 and 296 mV/V, respectively. The regulator was fabricated in a Cree 4H-SiC 2-μm experimental process and consists of 1000, 32/2-μm NMOS depletion MOSFETs as the pass device, an integrated error amplifier with enhancement MOSFETs, and resistor loads, and uses external feedback and compensation networks to ensure operational integrity. It was designed to be integrated with high-voltage vertical power MOSFETs on the same SiC substrate. It also serves as a guide to future attempts for voltage regulation in any type of integrated SiC circuitry. [ABSTRACT FROM AUTHOR]

Published

2014