Alan F. Lynch scite author profile

In this brief, we consider reactive power and dc voltage tracking control of a three-phase voltage source converter (VSC). This control problem is important in many power system applications including power factor correction for a distribution static synchronous compensator (D-STATCOM). Traditional approaches to this problem are often based on a linearized model of the VSC and proportional-integral (PI) feedback. In order to improve performance, a flatness-based tracking control for the VSC is proposed where the nonlinear model is directly compensated without a linear approximation. Flatness leads to straightforward open-loop control design. A full experimental validation is given as well as a comparison with the industry-standard decoupled vector control. Robustness of the flatness-based control is investigated and setpoint regulation for unbalanced three-phase voltage is considered.

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Flatness-Based Feedback Control of an Automotive Solenoid Valve

Chung

Koch

Lynch

2007

IEEE Trans. Contr. Syst. Technol.

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Alan F. Lynch

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Flatness-Based Feedback Control of an Automotive Solenoid Valve

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