Time-Domain Design of Digital Compensators for PWM DC-DC Converters

A time-domain design method for the digital controller of pulsewidth modulation dc-dc converters was developed. The proposed approach is based on the fact that the closed-loop response of a digitally controlled system is largely determined by the first few samples of the compensator. This concept is...

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Bibliographic Details
Published in:IEEE transactions on power electronics 2012-01, Vol.27 (1), p.284-293
Main Authors: Peretz, M. M., Ben-Yaakov, S.
Format: Article
Language:English
Subjects:
Applied sciences
Circuit properties
Closed-loop performance
Compensators
Control systems
Controllers
Converters
DC-DC power converters
Design engineering
Design methodology
Digital
Digital circuits
digital control
digital signal processing
discrete-time analysis
Electric currents
Electric, optical and optoelectronic circuits
Electrical engineering. Electrical power engineering
Electrical machines
Electronic circuits
Electronics
Equations
Exact sciences and technology
Frequency domain analysis
PID control
Power electronics, power supplies
Proportional integral derivative
Pulse duration modulation
Pulse width modulation
pulse width modulation converters
Regulation and control
Signal convertors
stability analysis
Time domain analysis
Transfer functions
voltage-mode control
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Summary:A time-domain design method for the digital controller of pulsewidth modulation dc-dc converters was developed. The proposed approach is based on the fact that the closed-loop response of a digitally controlled system is largely determined by the first few samples of the compensator. This concept is used to fit a digital PID template to the desired response. The proposed controller design method is carried out in the time domain and, thus, bypasses errors related to the transformation from the continuous to discrete domain and to discretization. The method was tested by simulations and experimentally. Digital PID controllers for experimental buck- and boost-type converters were designed according to the proposed method and implemented on a TMS320LF2407 DSP core. The measured closed-loop attributes were found to be in good agreement with the design goals. The study was further expanded to investigate the possible realistic closed-loop performance that can be obtained from a system that is controlled by a PID template controller, as well as the stability boundaries of the proposed time-domain controller design approach. The results of the study delineate a normalized map of deviation from the target closed-loop performance goals possible for PID control of switch-mode converters and the areas in which the use of this control law is feasible.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2011.2160358