Research Groups

Prof. Erickson鈥檚 research group focus on modeling and design of power electronics components and systems. 

His research has spanned numerous areas within power electronics, and has included collaboration with many students and colleagues. Research results are arranged in the following broad topics: 

Solar and Wind

  • IEEE Applied Power Electronics Conference
  • IEEE Transactions on Power Electronics
  • 38th IEEE Photovoltaic Specialists Conference
  • IEEE Transactions on Power Electronics

Electric Vehicles

  • IEEE Transactions on Power Electronics
  • IEEE Energy Conversion Congress and Exposition
  • IEEE Transactions on Power Electronics
  • IEEE Applied Power Electronics Conference 

Rectifiers

Resonant Converters

PWM Converters

Prof. Maksimovic鈥檚 research group focuses on achieving significant system-level advances in energy efficiency and renewable energy sources via smart power electronics. 

Power electronics is the technology that ties wind turbines and photovoltaics to the electric power grid, propels hybrid and electric vehicles, powers a countless variety of electronic systems, and makes it possible to operate battery-powered mobile devices for many hours. In the Colorado Power Electronics Center, we are exploring ways to achieve significant system-level advances in energy efficiency and renewable energy sources via smart power electronics. Current research project topics include:
  • Modular Wide-Bandgap String Inverters for Low-Cost Medium-Voltage Transformerless PV Systems, a project sponsored by DOE Solar Energy Technology Office in the The project aims to develop a new PV architecture comprised of stackable modules with distributed controls. Team: U of Washington, CU-Boulder, NREL, Wolfspeed.
  • A High-voltage, High-reliability Scalable Architecture for Electric Vehicle Power Electronics, a project sponsored by has objectives to develop new composite SiC power converter technology that achieves high power and voltage conversion at ultra high efficiency and power density. The technology will be demonstarted on a multifunctional power system for electric vehicles. Team: CU-Boulder, Toyota, Wolfspeed, NREL.
  • A Disruptive Approach to Electric Vehicle Power Electronics, a project sponsored by to develop a new modular power conversion approach that utilizes both silicon and wide band gap devices to address the fundamental power conversion, loss, and component stress mechanisms. Industry partner:
  • Integrated power converters for photovoltaic (PV) modules in PV power systems, an Team: CU-Boulder, NREL, Nuvotronics. The project goals are to show how sub-module integrated DC-DC converters can substantially improve efficiency and reduce cost in all PV systems, including various types of PV modules in residential, commercial or utility-scale systems.
  • Robust cell-level modeling and control of large battery packs, an Team: USU, CU-Boulder, UCCS, NREL, Ford. Our objectives are to demonstrate substantial improvements in battery packs using distributed intelligent power electronics performing advanced cell-level management and control algorithms.

    Prof. Hodge's research focuses on the modeling and simulation of power and energy systems, with an emphasis on the operational and planning challenges posed by the integration of renewable energy sources, such as wind and solar power.

    Projects 

    Publications