4. The transfer function of temperature control system is given by a 1 G (8) (0.5s1)...
Question 6 Consider the system shown in Figure 4. The open-loop transfer function is given by G() = - 2 (3+1)(0.59+1) Figure 4 Control diagram for Question 6 With the help of Matlab, design a compensator ab, design a compensator so that the static velocity error constant Kv is 5 sec, the phase margin is at least 45°, and the gain margin is at least 10 dB. [20]
design a lead compensator For the system with the following open loop transfer function, G(S) (05s+1 Design a lead compensator so that the velocity error constant 20 sec and the phase margin is at least 50° For the system with the following open loop transfer function, G(S) (05s+1 Design a lead compensator so that the velocity error constant 20 sec and the phase margin is at least 50°
new question as i don’t have extra information and better quality of the pic for previous question Question 2 (20 marks) The feed forwand transfer function of an automated manufacturing process is given by K(s+3) 1-1S(5)9 where K is the proportional controller gain. The root locus is shown in Figure 6 a) Determine the range of values of K for which the closed loop system will exhibis a (10 marks) b) Determine a value of K that gives a damping...
The transfer function of the given physical system is 2500 Gp(s)-T-1000 Part 3 1. Frequency response (a) Draw the bode plot of open-loop transfer function when K (b) Use bode plot of open-loop transfer function to determine the type of system (do not use transfer function) (c) For what input the system will have constant steady-state error (d) for the unit input in item (c) calculate the constant steady-state error.(Use bode plot to calculate the error.) (e) Design a lead...
1 Consider the system shown as below. Draw a Bode diagram of the open-loop transfer function G(s). Determine the phase margin, gain-crossover frequency, gain margin and phase-crossover frequency, (Sketch the bode diagram by hand) 2 Consider the system shown as below. Use MATLAB to draw a bode diagram of the open-loop transfer function G(s). Show the gain-crossover frequency and phase-crossover frequency in the Bode diagram and determine the phase margin and gain margin. 3. Consider the system shown as below. Design a...
Consider the transfer function of a DC motor given by G(s) = 1 / s(s+2) 3. Consider the transfer function of a DC motor given by 1 G(s) s (s2) The objective of this question is to consider the problem of control design for this DC motor, with the feedback control architecture shown in the figure below d(t r(t) e(t) e(t) C(s) G(s) Figure 4: A feedback control system (a) Find the magnitude and the phase of the frequency response...
Q.4 A position control system is shown in Figure Q4. Assume that K(s) = K, the plant 50 s(0.2s +1) transfer function is given by G(s) s02s y(t) r(t) Figure Q4: Feedback control system. (a) Design a lead compensator so that the closed-loop system satisfies the following specifications (i) The steady-state error to a unit-ramp input is less than 1/200 (ii) The unit-step response has an overshoot of less than 16% Ts +1 Hint: Compensator, Dc(s)=aTs+ 1, wm-T (18 marks)...
A linear system is described by the transfer function G(o) Determine the location of the pole in a minimum-beta lead compensator design for this system 10 which will yield a phase margin of 65.5 degrees at a magnitude crossover of 5.4 rad/sec. A linear system is described by the transfer function G(o) Determine the location of the pole in a minimum-beta lead compensator design for this system 10 which will yield a phase margin of 65.5 degrees at a magnitude...
Probleni 4 The transfer function of the process of a unity-feedback system 1 G, (s) = 2500K s(s+25) Design a phase-lead controller with the transfer function Ge (s) 1+aTs 1+Ts So that i. The steady-state error due to a unit ramp should be less than or ii. The phase margin of the system should be greater than 45 equal to 1 percent.
Consider a unity-feedback control system with a PI controller Gpr(s) and a plant G(s) in cascade. In particular, the plant transfer function is given as 2. G(s) = s+4, and the PI controller transfer function is of the forrm KI p and Ki are the proportional and integral controller gains, respectively where K Design numerical values for Kp and Ki such that the closed-loop control system has a step- response settling time T, 0.5 seconds with a damping ratio of...