12: Control Systems – Loopshaping

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Page ID: 47292

Franz S. Hover & Michael S. Triantafyllou
Massachusetts Institute of Technology via MIT OpenCourseWare

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12.1: Introduction to Loopshaping
Overview of the steps of loopshaping; establishes chapter's focus on single-input, single-output systems.
12.2: Roots of Stability – Nyquist Criterion
Application of the mapping theorem to a feedback system, and its translation to the Nyquist stability criterion. Measuring robustness of the model on the Nyquist plot.
12.3: Design for Nominal Performance
Performance requirements of a nominal-plant model feedback controller, in terms of the Nyquist plot.
12.4: Design for Robustness
Using the multiplicative uncertainty to reduce the degree of a plant model's degradation over time.
12.5: Robust Performance
Determining whether a system performs well, in terms of both robustness and nominal performance, through graphical and numerical methods.
12.6: Implications of Bode’s Integral
The relationship between slope steepness in the crossover region and phase loss/phase margin for a loop transfer function, as demonstrated through Bode's Integral.
12.7: The Recipe for Loopshaping
Steps for obtaining the compensator component \(C\) of the open loop transfer function \(PC\) discussed in the previous sections.

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