Block diagram of the system is given below. Design the C(s) block as PI (Proportional-Integral) controller such that it makes the system stable, damping coefficient of the characteristic equation=0.7, natural frequency=100 rad/sec. Sketch the output of the system vs time. (Input is unit step)
Block diagram of the system is given below. Design the C(s) block as PI (Proportional-Integral) controller...
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...
Problem 3: (30 Consider a block diagram which represents the satellite control system with a controller Ge(s) (a) Assuming no initial conditions, find the output response y(t) when the impulse input is applied to the system, where Gc(s) is a proportional gain K. (10) (b) Design a lead-compensator Ge(s) for which the complex pole of the closed-loop system has 0.5 of damping ratio () and 2 rad/s of undamped natural frequency (on) (The zero of a lead-compensator is given as...
A PI controller has a proportional gain of 2 with integral time constant 0.5 seconds. Write down the Pl controller transfer function and draw the unity feedback system block diagram where the above Pl is controlling plant Gp (s).
Problem 2. (40 points) The following figure shows the block diagram of a feedback closed loop control system. Ysp(s) - Es) | U(s) Y(s) S +5 1 Ge(s) Q"46:0) " ** 52_1 (a) Find the range of controller settings that yield stable closed-loop system for: (i) A proportional-only (P) controller. (ii) A proportional-integral (PI) controller. (b) For the PI control, modify the block diagram to eliminate proportional kick.
PD & PID controller design Consider a unity feedback system with open loop transfer function, G(s) = 20/s(s+2)(8+4). Design a PD controller so that the closed loop has a damping ratio of 0.8 and natural frequency of oscillation as 2 rad/sec. b) 100 Consider a unity feedback system with open loop transfer function, aus. Design a PID controller, so that the phase margin of (S-1) (s + 2) (s+10) the system is 45° at a frequency of 4 rad/scc and...
2a. Determine a proper controller so that the feedback control system below will have the damping ratio of < = 0.7 and the natural frequency of n = 10.0 rad/sec. Your choices are: Proportional controller, K Lead controller, 17, a < 1 Lag controller, v a > 1 Proportional + Derivative controller, K (1 + Tas) Proportional + Integral + Derivative controller, K(1+1/(Ts) + Tas) Or Lead Lag controller If the resulting feedback control system has an order greater than...
4.35 Consider the feedback control system with the plant transfer function G(s) = (5+0.1)(5+0.5) (a) Design a proportional controller so the closed-loop system has damping of 5 = 0.707. Under what conditions on kp is the closed-loop system stable? (b) Design a PI controller so that the closed-loop system has no over- shoot. Under what conditions on (kp, kt) is the closed-loop system is stable? (©) Design a PID controller such that the settling time is less than 1.7 sec.
Design a PI controller to drive the step-response error to zero for the negative unity feedback system shown in Fig. 1, where G(s) S+1(s+3)(s+10) The system operates with a damping factor of 0.4. * Design a PI controller whose compensator zero located at -0.1 Use MATLAB or any other computer program to simulate the step response * to closed-loop system Design a PI controller to drive the step-response error to zero for the negative unity feedback system shown in Fig....
PROBLEM 4 Suppose that a system is shown in Figure 4. There are three controllers that might be incorporated into this system. 1. Ge (s)-K (proportional (P) controller) 2. GS)K/s (integral (I) controller) 3. G (s)K(1+1/s) (proportional, integral (PI) controller) The system requirements are T, < 10 seconds and P0 10% for a unit step response. (a) For the (P) controller, write a piece of MATLAB code to plot root locus for 0<K<,and find the K value so that the...
Question 1 (60 points) Consider the following block diagram where G(s)- Controller R(s) G(s) (a) Sketch the root locus assuming a proportional controller is used. [25 points] (b) Design specifications require a closed-loop pole at (-3+j1). Design a lead compensator to make sure the root locus goes through this point. For the design, pick the pole of the compensator at-23 and analytically find its zero. (Hint: Lead compensator transfer function will be Ge (s)$+23 First plot the poles and zeros...