Abstract
Three pulse-width-modulation (PWM) digital control approaches are evaluated to provide the current sharing between phases in high-power dual-interleaved DC-DC converters. The implementation of a digital peak current, multi-sample averaged current and an enhanced single-sample averaged current control in a TMS320F28377D is described. A summary of stability requirements is provided for designing the controllers and experimental results from a 60 kW, 75 kHz silicon carbide DC-DC converter are used to evaluate the steady-state and dynamic performance of the three control methods. Overall the best performance in terms of tracking and speed of response was achieved by the enhanced single-sample method. The multi-sampled technique provided the highest tracking accuracy, but at the expense of the slowest dynamic response. The fastest dynamic response was achieved by the digital peak current control, but this method is limited by poor noise immunity and instability for duty ratios in the region of 0.5.
Original language | English |
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Pages (from-to) | 391-398 |
Number of pages | 8 |
Journal | IET Power Electronics |
Volume | 11 |
Issue number | 2 |
Early online date | 30 Nov 2017 |
DOIs | |
Publication status | Published - 20 Feb 2018 |
Keywords
- DC-DC power convertors
- PWM power convertors
- TMS320F28377D
- control engineering computing
- current sharing
- digital PWM control strategies
- digital control
- digital peak current control
- digital pulse-width-modulation control strategies
- duty ratios
- dynamic response
- electric current control
- enhanced single-sample averaged current control
- enhanced single-sample method
- high-power dual-interleaved DC-DC converters
- microcontrollers
- multisample averaged current
- multisampled technique
- power engineering computing
- silicon carbide DC-DC converter
- stability requirements