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(2.) Consider the simplified satellite altitude control problem shown below. Design an appropriate controller to meet...
SOLVE USING MATLAB A servomechanism position control has the plant transfer function 10 s(s +1) (s 10) You are to desig...
SOLVE USING MATLAB
A servomechanism position control has the plant transfer function 10 s(s +1) (s 10) You are to design a series compensation transfer function D(s) in the unity feedback configuration to meet the following closed-loop specifications: . The response to a reference step input is to have no more than 16% overshoot. . The response to a reference step input is to have a rise time of no more than 0.4 sec. The steady-state error to a unit...
Lag Compensator Design Using Root-Locus 2. Consider the unity feedback system in Figure 1 for G(s...
Lag Compensator Design Using Root-Locus 2. Consider the unity feedback system in Figure 1 for G(s)- s(s+3(s6) Design a lag compensation to meet the following specifications The step response settling time is to be less than 5 sec. . The step response overshoot is to be less than 17% . The steady-state error to a unit ramp input must not exceed 10%. Dynamic specifications (overshoot and settling time) can be met using proportional feedback, but a lag compensator is needed...
Consider the same plant G(s) Design a controller so that if you desire an angle of...
Consider the same plant G(s) Design a controller so that if you desire an angle of r 1 rad, s(s+10) (s+20) (R the actual angle of the motor y(t) has an overshoot less than or equal to 20% and a settling time less than or equal to 0.3s as it is settling down to the steady state angle. Write down the steps you followed in the sisotool (or otherwise), include: i. ii. iii. iv. Your error calculations and calculations for...
QUICK UPVOTE: As a control system engineer you have been asked to design a controller that...
QUICK UPVOTE:
As a control system engineer you have been asked to design a controller that would improve the error and the transient response for the unity feedback system below. The proposed solution must be cost-effective, so consider a passive network-based compensator. The transient response of the closed-loop transfer function to a ramp input has a 30% overshoot (%OS = 30) and a settling time Ts= 2.73 seconds. You need to decrease the peak time by a factor of 2,...
Problem 4. Consider the control system shown below with plant G(s) that has time con- stants...
Problem 4. Consider the control system shown below with plant G(s) that has time con- stants T1 = 2, T2 = 10, and gain k = 0.1. 4 673 +1679+1) (1.) Sketch the pole-zero plot for G(s). Is one of the poles more dominant? Using MATLAB, simulate the step response of the plant itself, along with G1(s) and G2(s) as defined by Gl(s) = and G2(s) = sti + 1 ST2+1 (2.) Design a proportional gain C(s) = K so...
4. You want to design an orientation controller for a satellite system whose thrusters provide a...
4. You want to design an orientation controller for a satellite system whose thrusters provide a torque T to modify the angular position 0 with transfer function (s) 0.1 G(s) T(s) $2 Y() R(s) G(s) C(s) You want to add damping to the system to minimize any oscillations (%OS < 5%) but still maintain a 1% settling time of less than 60 s to a unit step input. I(a) Sketch the allowable pole locations in the complex plane to meet...
Control System Designs: Have to use Root Locus. The desired point s(desired) is -4.5+j3.3.
Control System Designs: Have to use Root Locus. The desired
point s(desired) is -4.5+j3.3.
b. (10pts)Design a PID controller to meet all the following design specifications: i) Po 35% (0.35 ç) ii) ts S 3sec ii) The steady-state error is zero for the unit step input. for m 1, b-0.1 and k-1 k /m X (s1 Xdeire (s) k s +(b/m)s +(k/m)
b. (10pts)Design a PID controller to meet all the following design specifications: i) Po 35% (0.35 ç) ii)...
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 trans...
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...
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 l...
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)...
3. Consider the tilt control block diagram shown below R(s) DesiredG(s) 12 s(s+10)(s+70) Y(s) Til...
3. Consider the tilt control block diagram shown below R(s) DesiredG(s) 12 s(s+10)(s+70) Y(s) Tilt tilt Design specifications require an overshoot of less than 5% and a settling time of less than 0.6 seconds. (a) Use MATLAB to sketch the root locus (rlocus command) with a proportional controller and use the root locus to determine a value for K (if any) that will satisfy the design requirements (b) Design a lead compensator Ge(s) to satisfy the design specifications. You can...
SOLVE USING MATLAB
A servomechanism position control has the plant transfer function 10 s(s +1) (s 10) You are to design a series compensation transfer function D(s) in the unity feedback configuration to meet the following closed-loop specifications: . The response to a reference step input is to have no more than 16% overshoot. . The response to a reference step input is to have a rise time of no more than 0.4 sec. The steady-state error to a unit...
Lag Compensator Design Using Root-Locus 2. Consider the unity feedback system in Figure 1 for G(s)- s(s+3(s6) Design a lag compensation to meet the following specifications The step response settling time is to be less than 5 sec. . The step response overshoot is to be less than 17% . The steady-state error to a unit ramp input must not exceed 10%. Dynamic specifications (overshoot and settling time) can be met using proportional feedback, but a lag compensator is needed...
Consider the same plant G(s) Design a controller so that if you desire an angle of r 1 rad, s(s+10) (s+20) (R the actual angle of the motor y(t) has an overshoot less than or equal to 20% and a settling time less than or equal to 0.3s as it is settling down to the steady state angle. Write down the steps you followed in the sisotool (or otherwise), include: i. ii. iii. iv. Your error calculations and calculations for...
QUICK UPVOTE:
As a control system engineer you have been asked to design a controller that would improve the error and the transient response for the unity feedback system below. The proposed solution must be cost-effective, so consider a passive network-based compensator. The transient response of the closed-loop transfer function to a ramp input has a 30% overshoot (%OS = 30) and a settling time Ts= 2.73 seconds. You need to decrease the peak time by a factor of 2,...
Problem 4. Consider the control system shown below with plant G(s) that has time con- stants T1 = 2, T2 = 10, and gain k = 0.1. 4 673 +1679+1) (1.) Sketch the pole-zero plot for G(s). Is one of the poles more dominant? Using MATLAB, simulate the step response of the plant itself, along with G1(s) and G2(s) as defined by Gl(s) = and G2(s) = sti + 1 ST2+1 (2.) Design a proportional gain C(s) = K so...
4. You want to design an orientation controller for a satellite system whose thrusters provide a torque T to modify the angular position 0 with transfer function (s) 0.1 G(s) T(s) $2 Y() R(s) G(s) C(s) You want to add damping to the system to minimize any oscillations (%OS < 5%) but still maintain a 1% settling time of less than 60 s to a unit step input. I(a) Sketch the allowable pole locations in the complex plane to meet...
Control System Designs: Have to use Root Locus. The desired
point s(desired) is -4.5+j3.3.
b. (10pts)Design a PID controller to meet all the following design specifications: i) Po 35% (0.35 ç) ii) ts S 3sec ii) The steady-state error is zero for the unit step input. for m 1, b-0.1 and k-1 k /m X (s1 Xdeire (s) k s +(b/m)s +(k/m)
b. (10pts)Design a PID controller to meet all the following design specifications: i) Po 35% (0.35 ç) ii)...
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...
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)...
3. Consider the tilt control block diagram shown below R(s) DesiredG(s) 12 s(s+10)(s+70) Y(s) Tilt tilt Design specifications require an overshoot of less than 5% and a settling time of less than 0.6 seconds. (a) Use MATLAB to sketch the root locus (rlocus command) with a proportional controller and use the root locus to determine a value for K (if any) that will satisfy the design requirements (b) Design a lead compensator Ge(s) to satisfy the design specifications. You can...
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