Because of their reduced switching losses, DC-to-DC resonant converters have been used extensively in the design of smaller size and lighter weight power supplies. The steady state and dynamic behaviors of both the conventional series and parallel resonant converters have been thoroughly analyzed and small-signal models around given nominal operating points have been obtained. These models have been used in the past to design controllers that attempted to keep the output voltage constant in the presence of input perturbations. However, these controllers did not take into account neither load nor components variations, and this could lead to instability in the face of component or load changes. Moreover, prediction of the frequency range for stability was done a posteriori, either experimentally or by a trial and error approach. In this paper we use /spl mu/-synthesis to design a robust controller for a series resonant converter. In addition to robust stability the design objectives include rejection of disturbances at the converter input while keeping the control input and the settling time within values compatible with a practical implementation.<<ETX>>
[1]
John C. Doyle.
Analysis of Feedback Systems with Structured Uncertainty
,
1982
.
[2]
V. Vorperian.
Analysis of Resonant Converters
,
1984
.
[3]
S. Skogestad,et al.
Performance weight selection for H-infinity and μ-control methods
,
1991
.
[4]
C. Q. Lee,et al.
Steady state analysis of the parallel resonant converter with LLCC-type commutation network
,
1989,
20th Annual IEEE Power Electronics Specialists Conference.
[5]
J. G. Kassakian,et al.
High-frequency high-density converters for distributed power supply systems
,
1988
.
[6]
Sigurd Skogestad,et al.
Robust controller design for uncertain time delay systems
,
1993
.
[7]
P. Lundstrom,et al.
Uncertainty weight selection for H-infinity and mu-control methods
,
1991,
[1991] Proceedings of the 30th IEEE Conference on Decision and Control.