Research Areas
Biography and Research Information
OverviewAI-generated summary
Roderick A. Gomez Jimenez's research focuses on the design and optimization of power electronic converters and transformers, particularly those operating at medium voltages and high frequencies. His work has explored the analysis of current resonances caused by parasitic capacitances in medium-voltage, medium-frequency transformers and the design of nanocrystalline versions of these transformers for grid-connected applications. He has also investigated optimization algorithms for dual-active bridge converters, specifically using parallel power modules.
Further contributions include the design optimization and experimental validation of gate drivers for 10 kV SiC MOSFETs. Gomez Jimenez also studies non-dissipative regenerative snubbers for isolated DC-DC Cuk converters and the implications of high-frequency effects on magnetics and converter performance for power electronic converter design. His research is supported by collaborations with other researchers at the University of Arkansas at Fayetteville, including Juan Carlos Balda and David A. Porras Fernandez.
Metrics
- h-index: 3
- Publications: 6
- Citations: 29
Selected Publications
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High-Frequency Effects on Magnetics and Converter Performance: Implications for Power Electronic Converter Design (2024)
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Non-Dissipative Regenerative Snubber for Isolated DC-DC Cuk Converter (2023)
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Optimization Design Algorithm for Dual-Active Bridge Converters Using Parallel Power Modules (2022)
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Design Optimization and Experimental Validation of Gate Driver for 10 kV SiC MOSFET (2022)
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Analysis of Current Resonances due to Winding Parasitic Capacitances in Medium-Voltage Medium-Frequency Transformers (2022)
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Design of Nanocrystalline Medium-Voltage Medium-Frequency Three-Phase Transformers for Grid-Connected Applications (2021)
Collaboration Network
Top Collaborators
- Analysis of Current Resonances due to Winding Parasitic Capacitances in Medium-Voltage Medium-Frequency Transformers
- Design of Nanocrystalline Medium-Voltage Medium-Frequency Three-Phase Transformers for Grid-Connected Applications
- Optimization Design Algorithm for Dual-Active Bridge Converters Using Parallel Power Modules
- Non-Dissipative Regenerative Snubber for Isolated DC-DC Cuk Converter
- High-Frequency Effects on Magnetics and Converter Performance: Implications for Power Electronic Converter Design
- Design of Nanocrystalline Medium-Voltage Medium-Frequency Three-Phase Transformers for Grid-Connected Applications
- Optimization Design Algorithm for Dual-Active Bridge Converters Using Parallel Power Modules
- Non-Dissipative Regenerative Snubber for Isolated DC-DC Cuk Converter
- Optimization Design Algorithm for Dual-Active Bridge Converters Using Parallel Power Modules
- Non-Dissipative Regenerative Snubber for Isolated DC-DC Cuk Converter
- High-Frequency Effects on Magnetics and Converter Performance: Implications for Power Electronic Converter Design
- Analysis of Current Resonances due to Winding Parasitic Capacitances in Medium-Voltage Medium-Frequency Transformers
- Design of Nanocrystalline Medium-Voltage Medium-Frequency Three-Phase Transformers for Grid-Connected Applications
- Design of Nanocrystalline Medium-Voltage Medium-Frequency Three-Phase Transformers for Grid-Connected Applications
- Analysis of Current Resonances due to Winding Parasitic Capacitances in Medium-Voltage Medium-Frequency Transformers
- Design Optimization and Experimental Validation of Gate Driver for 10 kV SiC MOSFET
- Design Optimization and Experimental Validation of Gate Driver for 10 kV SiC MOSFET
- Design Optimization and Experimental Validation of Gate Driver for 10 kV SiC MOSFET
- Design Optimization and Experimental Validation of Gate Driver for 10 kV SiC MOSFET
- Design Optimization and Experimental Validation of Gate Driver for 10 kV SiC MOSFET
- High-Frequency Effects on Magnetics and Converter Performance: Implications for Power Electronic Converter Design