Unit 11 - Week 7: Quantitative feedback theory (Part 1/2)

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X reviewer3@nptel.iitm.ac.in Courses» Control System Design Announcements Course Ask a Question Progress Mentor FAQ Unit 11 - Week 7: Quantitative feedback theory (Part 1/2) Course outline How to access the portal Prerequisite Assignment MATLAB Download and Introduction Week 7 Assessment The due date for submitting this assignment has passed. As per our records you have not submitted this Due on 2018-09-19, 23:59 IST. assignment. 1) It is required that the response of a plant P(s) varies within a specified limit 1 point when the parameters of the plant change. A 2-DOF control system with a K c (s + z c ) controller C(s) = and a Pre-filter F(s) is designed in order to minimise the effect off (s + p c ) variation in plant properties on the position of a given dominant closed-loop pole, p. MATLAB Learning Modules Week 1: Linear System Theory, Fourier and Laplace Transforms Week 2: Introduction to feedback control, Nyquist stability theory Week 3 : Bode plots, Steps for performing control design, General controllers Week 4: Bode-plot and root-locus based control design A project of While C(s) adds z c close to p and provides adequate gain K c in order to minimise the variation in the dynamic response, F(s) ensures that z c does not cancel p. While C(s) adds z c far away from p and provides adequate gain K c inorder to minimise the variation in the dynamic response, F(s) ensures that z c does not cancel p. While C(s) adds p c close to p and provides adequate gain K c in order to minimise the variation in the dynamic response, F(s) ensures that z c does not cancel p While C(s) adds z c close to p and provides adequate gain K c in order to minimise the variation in the dynamic response, F(s) ensures that p c does not modify p While C(s) adds z c close to p and provides adequate gain K c in order to minimise the variation the dynamic response, F(s) ensures that z c does not cancel p. 2) The transfer function of a plant is given 1 point K p as. Although the nominal gain of the plant is it varies P(s) = K p (s + p 1 )(s + p 2 )(s + p) 0.25K p 4K p between and. Similarly, the open loop pole at p varies from 0.25p to 4p. A 2-DOF 2014 NPTEL - Privacy & Terms - Honor Code - FAQs - In association with Funded by 1 of 12 Wednesday 07 November 2018 10:34 PM

Week 6: 2-Degree of freedom control design for robustness Week 7: Quantitative feedback theory (Part 1/2) Issues connected with 2-Degree of freedom control design using root-locus Introduction to Nichols plot Feedback control design using Nichols plot Quiz : Week 7 Assessment Week 8 : Quantitative feedback theory (Part 2/2) Lecture Notes(Week 1-8) Week 9: Fundamental properties of feedback systems Week 10 :Nonminimum phase system Week 11: Unstable systems Week 12 Describing functions Assignment solutions 3) What is the issue associated with Bode plot as a tool to design a controller if, apart from 1 point reference tracking, one also desire to reject both the input and output disturbances in case of an uncertain plant. There will be bundle of bode plots for an uncertain plant and deciding on which one to choose for designing a controller to meet the performance specifications would be problematic. The phase plots of the Bode plot will be inaccurate. Magnitude Bode plots will not be straight lines Bode plots cannot be employed to reject disturbances. There will be bundle of bode plots for an uncertain plant and deciding on which one to choose for design a controller to meet the performance specifications would be problematic. 4) What are the advantages of the Nichols plot over Nyquist plot when it comes to feedback 1 point control? C(s) = C(s) = C(s) = C(s) = C(s) = Multiplying the controller transfer function with the plant's transfer function does not change either the shape or orientation of the region within which an uncertain plant's transfer function assumes values. It is easier to define gain and phase margin in Nichols plot The shape of Nichols plot of an open loop transfer function is less complex compared to its Nyquist plot. The Nichols plot provides more information about performance than the Nyquist plot. KPowered c (s + by z c )(s + z c ) (s + p c ) 2 K c (s + p 1 )(s + z c )(s + z c ) K c (s + p c ) s(s + p c ) 2 s(s + p c ) 2 K c (s + z c )(s + z c ) s(s + p c ) 2 K c (s + p 1 )(s + z c )(s + z c ) s(s + p c ) 2 Multiplying the controller transfer function with the plant's transfer function does not change either the shape or orientation of the region within which an uncertain plant's transfer function assumes values. 5) 1 point The transfer function of a plant is given as. Identify the Nichols plot of the given plant when K p =1: P(s) = K p s(s + 1)(s/2 + 1) 2 of 12 Wednesday 07 November 2018 10:34 PM

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6) For the plant given in previous question (Q5), identify the Nichols plot of the given plant 1 point when K p =10: 5 of 12 Wednesday 07 November 2018 10:34 PM

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7) Figure shows the plot of input disturbance rejection bound and stability bound of a plant at 1 point a particular frequency ' ω 0 ' on the Nichols plot. Identify the region (shaded with lines) where loop gain 'L' should lie to simultaneously satisfy input disturbance rejection and stability requirement at frequency 7 of 12 Wednesday 07 November 2018 10:34 PM

' ω 0 ' 8 of 12 Wednesday 07 November 2018 10:34 PM

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8) The Nichols plots of three systems (i-iii) have been given below. Identify which of the three 1 point result in a stable closed-loop system. 10 of 12 Wednesday 07 November 2018 10:34 PM

i and ii ii and iii iii and i i, ii and iii iii and i 9) In order to depict closed-loop stability of a feedback control system, which of the following 1 point entity is conventionally specified in the Nichols plot? Maximum value of the transmission function ( T max ) Gain Margin Phase Margin Magnitude of loop gain at the phase cross-over frequency Maximum value of the transmission function ( T max ) 10) In order to plot the stability bounds what all frequencies should be considered? 1 point Frequencies within the gain cross-over frequency of the open loop transfer function All frequencies within which performance specifications will have to be met Frequencies higher than ones at which performance specifications will have to be met Both b and c. Both b and c. Previous Page End 11 of 12 Wednesday 07 November 2018 10:34 PM

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