E(t)=u(t)num(z)20den(z)$2+9s+20Zero-OrderHoldDigital ControllerPlantY(t)Fig. 2 A closed-loop sampled-data system with digital controller2. Consider the closed-loop sampled-data system that is given in Fig. 2.a) Design a unity-dc-gain phase-lag compensator that yields a phase margin of 45 degree.Use ww1 = 10.6 rad/sec.b) Start simulink and construct the model that is given in Fig.2. Additionally, in order toplot the Y(t) by using workspace use a clock and a workspace blocks which are named ast, ytSampled. Set the sampling time -1 for all workspace blocks. Use the result of e forDigital Controller. Select an appropriate time for simulation and run it by clicking onthe start button. Plot the Y(t) by using t and ytSampled.c) Plot the Bode diagram of this system and determine the phase and gain margin.d) Repeat a, b and c for ww₁ = 23 rad/sec and ww₁ = 83.6 rad/sec.e) Discuss the effect of the phase-lead compensator for different w₁values (Hint: Considerboth the transient and steady-state responses). Does the increment in the ww₁ destabilizethis system? Explain your answer by proving the mathematical expressions.

To design a lag-lead compensator for the given closed-loop sampled-data system, we first establish…

Answered: E(t)=u(t) num(z) 20 den(z) $2+9s+20…

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter12: Power System Controls

Section: Chapter Questions

Problem 12.3P

See similar textbooks

Similar questions

Q1)(a) An industrial liquid level system represented by a signal flow graph is shown in Figure Q1(a) using Mason's gain formula i) Identify the number of forward paths and the forward path gains i) Identify the individual loops, two non-touching loops and three non-touching loops. C(s) ii) Obtain the transfer function R(s) for the liquid level system - H1 64 G2 G6 Cs) R(S) G5 - H2 Figure Q1(a)
Considering the amplifier gain 13 and the number 2 as N, design a Wien Bridge oscillator circuit with an oscillating frequency ((1 + N) × 1000) Hz. Draw the circuit. Show the process steps. Show the values of the circuit elements in your drawing. I would be very happy if you could be quick :)
4. A DC amplifier has a single-pole response with a pole frequency of fpp 100Hz a low- = 2 x 10³. The amplifier operates in a closed-loop system with frequency gain of A = 0.05. 0 Find the closed-loop low-frequency gain and bandwidth. =
Answer the following with illustration and solutions. 2.) If C1 = C2 = 100pF, determine the output frequencies produced by this arrangement:a. (a) when R1 = R2 = 12kilo-ohms andb. (b) when R1 = R2 = 8kilo-ohms See the example below..
Given the feedback circuit below and assuming the voltage amplifier has gain A₂, input resistance R₁ and output resistance Ro, answer the following questions: + a. Loop gain b. Closed loop gain Re C. Input resistance d. Output resistance Rin м + RE A) Sketch the feedback small signal model of this circuit. (Hint: You may convert the input VIN and source resistance Rs to its Norton current equivalent if needed) B) Find the following in terms of the amplifier parameters and resistances R, and RF: Rout
Design a feedback amplifier with a de gain of 10 V N and a 3-dB bandwidth of at least IO MHz. The available open-loop amplifier has a de gain of 1000 VN and - 20 dB/decade gain rolloff with frequency. Specify the minimum required F3db of the open-loop amplifier. what is the feedback factor needed?
Q8. For the second order system shown below: 1. Range of gain (kl, k2) for which the closed-loop system in is stable should be obtained precisely. 2. Plot the range of the-k, on the real axis and ky on the imaginary axis. 3. Assume (k, k = u-1),compute the ESS. 4. For ramp input(u) and the gain values as in 3, determine the ESS. 5. If ESS #0 in 3 and u(t) = t, modify (k,s+k)/s) controller to make ESS = zero. 6. Verify your results. k,s + k; 1 s+10
An op amp has a dc gain of 100 dB and a unity-gain frequency of 10 MHz. (a) What is the bandwidth of the op amp? (b) If the op amp is used to build a noninverting ampliﬁer with a closed loop gain of 60 dB, what is the bandwidth of the feedback ampliﬁer? (c) Write an expression for the transfer function of the op amp. (d) Write an expression for the transfer function of the noninverting ampliﬁer.
Given the following values and shunt-series feedback circuit below, answer the following question: The closed-loop gain of the circuit is: A. 1499.97 Ω B. 999.87 μS C. −2.49965 D. 0.99996
a) Show that negative feedback can reduce the sensitivity of an amplifier circuit, by deducing the expression of dAc/dAol-
Construct the signal flow graph for the following set of simultaneous equations: X₂ = A21 X₁ + A23 X3, X3 = A31 X1 + A32 X2 + A33 X3, X4 = A42X2 + A43X3. Identify the (a) input node, (b) output node, (c) forward paths, (d) feedback paths, and (e) self-loop.
en Consider a negative feedback network formed of an amplifier where the open loop gain is 1000V/V and the Bandwidth (BW) is 20kHz. if the feedback gain is 0.4, the closed loop bandwidth in MHz is: Single MHz

SEE MORE QUESTIONS

Recommended textbooks for you

Power System Analysis and Design (MindTap Course …

Electrical Engineering

ISBN:

9781305632134

Author:

J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:

Cengage Learning