Showing posts with label WBG. Show all posts
Showing posts with label WBG. Show all posts

Aug 4, 2020

[paper] SiC MOSFET SPICE Model

Lefdal Hove, Haavard, Ole Christian Spro, Giuseppe Guidi
and Dimosthenis Peftitsis
Improved SiC MOSFET SPICE Model to Avoid Convergence Errors
Materials Science Forum 1004 (July 2020): 856–64
DOI: 10.4028/www.scientific.net/msf.1004.856

Abstract: This paper presents improvements to a SPICE model for a commercially available SiC MOSFET to avoid convergence errors while still providing reliable simulation results. Functionality in the internal part of the model that shapes the transconductance of the device according to its junction temperature and gate-source voltage dependency has been improved to provide a continuous characteristic rather than the initial discontinuous performance. Furthermore, the output characteristics from the initial and the proposed model have been compared to lab measurements of an actual device. The results show that the proposed and initial model provide equally reliable simulation results. However, the proposed model does not run into convergence problems.

References 
[1] X. She, A. Huang, O. Lucia, and B. Ozpineci, Review of Silicon Carbide Power Devices and Their Applications, IEEE Transactions on Industrial Electronics, vol. 64, no. 10, p.8193–8205, (2017).
[2] J. Rabkowski, D. Peftitsis, and H. P. Nee, Silicon carbide power transistors: A new era in power electronics is initiated, IEEE Industrial Electronics Magazine, vol. 6, no. 2, p.17–26, (2012).
[3] A. Stefanskyi, L. Starzak, A. Napieralski, and M. Lobur, Analysis of SPICE models for SiC MOSFET power devices,, 2017 14th CADSM 2017 - Proceedings, p.79–81, (2017).
[4] H. L. Hove, O. C. Spro, D. Peftitsis, G. Guidi, and K. Ljøkelsøy, Minimization of dead time effect on bridge converter output voltage quality by use of advanced gate drivers, 2019 10th ICPE 2019 ECCE Asia, (2019).
[5] N. Mohan, T. Undeland, and W. Robbins, Power Electronics; Converters, Applications, and Design, third ed., Wiley, (2003).
[6] C. Enz, F. Krummenacher, and E. Vittoz, An Analytical MOS Transistor Model Valid in All Regions of Operation and Dedicated to Low-Voltage and Low-Current Application, Analog Integrated Circuits and Signal Processing, vol. 8, p.83–114, (1995).
[7] M. Bucher, C. Lallement, C. Enz, F. Théodoloz, and F. Krummenacher, The EPFL-EKV MOSFET Model Equations for Simulation Technical Report V2.6,, EPFL, Lausanne, Switzerland, (1999).
[8] B. N. Pushpakaran, S. B. Bayne, G. Wang, and J. Mookken, Fast and accurate electro-thermal behavioral model of a commercial SiC 1200V, 80 mΩ power MOSFET,, Digest of Technical Papers IEEE IPPC, vol. 2015-Octob, p.1–5, (2015).

Jun 16, 2020

[slides] (Ultra-) Wide-Bandgap Devices

(Ultra-) Wide-Bandgap Devices: Reshaping the Power Electronics Landscape
Presenter Dr. Yuhao Zhang, Assistant Professor,
Center for Power Electronics Systems, Virginia Tech
IEEE EDS SCV-SF Seminar 
Friday, June 12, 2020 at 12PM – 1PM PDT

Abstract: Power electronics is the application of solid-state electronics for the control and processing of electrical energy. It is used ubiquitously in consumer electronics, electric vehicles, data centers, renewable energy systems, and smart grid. The power semiconductor device, as the cornerstone technology in power electronics, is key to improving the efficiency, cost and form factor of power electronic systems.  Recently, the power electronics landscape has been significantly reshaped with the production and application of power devices based on wide-bandgap (WBG) semiconductors, such as gallium nitride (GaN) and silicon carbide (SiC). Besides advancing the performance of traditional power systems, WBG devices have also enabled many emerging applications that are beyond the realm of silicon (Si) as well as changed the manufacturing paradigm of power electronics. On the horizon is the power devices based on ultra-wide-bandgap (UWBG) materials, which promises superior performance over GaN and SiC and is at the relatively early stage of research development.  This talk will provide a comprehensive overview of major WBG and UWBG power device technologies, spanning materials, devices, reliability and applications. Some research projects in the PI’s group in collaboration with industry will also be introduced.
FIG: WBG Semiconductor: Superior Power Semiconductor Over Si

The seminar presentation is now available on our IEEE EDS SCV-SF webpage:
http://site.ieee.org/scv-eds/files/2020/06/SCV_SF_EDS_Yuhao_Zhang_excerpt.pdf

More information at the IEEE EDS Santa Clara Valley-San Francisco Chapter Home Page. Subscribe or Invite your friends to sign up for our mailing list and get to hear about exciting electron-device relevant talks. We, EDS SCV-SF, promise no spam and try to minimize email. You can (un)subscribe easily.