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Nip rolls Bridle Surface winder Center-driven feedback Figure 5 Question 2 (20 marks) The feed forward transfer functio...
new question as i don’t have extra information and better quality of the pic for previous...
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...
Question 4 (a) A feedback control system with a proportional controller is shown in Figure Q4...
Question 4 (a) A feedback control system with a proportional controller is shown in Figure Q4 (a). (i) Sketch the root locus of the system, (ii) Design the proportional controller (choose the value of K) such that the damping ratio does not exceed 0.5 and the time constant is less than 1 second. [All necessary steps of root locus construction and controller design must be shown). C(s) R(S) + s(s+4)(s + 10) Figure Q4 (a). A feedback control system [11...
QUESTION a) With appropriate diagram explain the following compensator arrangements i. Cascade ii. Minor Loop Feedback...
QUESTION a) With appropriate diagram explain the following compensator arrangements i. Cascade ii. Minor Loop Feedback iii. Output Feedback (6 marks) b) Design a suitable lead compensator for a system with unity feedback and having open loop transfer function: Gis) = $(5+10) Determine the gain k meet the following specifications: Damping ratio { = 0.5 b. Undamped natural frequency w Hence determine the settling time, peak overshoot and peak time for a unit step input (10 marks). c) Sketch the...
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise...
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2b). i Determine the value in so that the damping ratio of the system is 0.5. (1 % marks) From the result obtained in , evaluate the transient response characteristics (rise...
(b) The unity feedback system is given as in Figure Q3 (b). (i) Determine the closed...
(b) The unity feedback system is given as in Figure Q3 (b). (i) Determine the closed loop transfer function of the system. (2 marks) 2 CONFIDENTIAL CONFIDENTIAL BEJ 20503/BEH 30603/BEF33003 (ii) Calculate the damping ratio š, peak time Tp, rise time Tr, percentage of overshoot%\ls and settling time Ts (5% criterion) of the system. (11 marks) Investigate the characteristic of the system response. (1 marks) (iii) R(s)+ E(s) C(s) 25 s(s + 6) Figure Q3(b)
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise...
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). Determine the value K, so that the damping ratio of the system is 0.5. (1 % marks) i. From the result obtained in (), evaluate the transient response characteristics (rise...
question 2 Question 2 a) Consider the control system in Figure 2(a). Determine the transient response...
question 2
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). Determine the value Kin so that the damping ratio of the system is 0.5. (1 % marks) it. From the result obtained in 0. evaluate the transient response...
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise...
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). i Determine the value Kso that the damping ratio of the system is 0.5. (1 % marks) i. From the result obtained in (), evaluate the transient response characteristics (rise...
a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak...
a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). i Determine the value K, so that the damping ratio of the system is 0.5. (1 % marks) ii. From the result obtained in (), evaluate the transient response characteristics (rise time,...
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...
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...
Question 4 (a) A feedback control system with a proportional controller is shown in Figure Q4 (a). (i) Sketch the root locus of the system, (ii) Design the proportional controller (choose the value of K) such that the damping ratio does not exceed 0.5 and the time constant is less than 1 second. [All necessary steps of root locus construction and controller design must be shown). C(s) R(S) + s(s+4)(s + 10) Figure Q4 (a). A feedback control system [11...
QUESTION a) With appropriate diagram explain the following compensator arrangements i. Cascade ii. Minor Loop Feedback iii. Output Feedback (6 marks) b) Design a suitable lead compensator for a system with unity feedback and having open loop transfer function: Gis) = $(5+10) Determine the gain k meet the following specifications: Damping ratio { = 0.5 b. Undamped natural frequency w Hence determine the settling time, peak overshoot and peak time for a unit step input (10 marks). c) Sketch the...
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2b). i Determine the value in so that the damping ratio of the system is 0.5. (1 % marks) From the result obtained in , evaluate the transient response characteristics (rise...
(b) The unity feedback system is given as in Figure Q3 (b). (i) Determine the closed loop transfer function of the system. (2 marks) 2 CONFIDENTIAL CONFIDENTIAL BEJ 20503/BEH 30603/BEF33003 (ii) Calculate the damping ratio š, peak time Tp, rise time Tr, percentage of overshoot%\ls and settling time Ts (5% criterion) of the system. (11 marks) Investigate the characteristic of the system response. (1 marks) (iii) R(s)+ E(s) C(s) 25 s(s + 6) Figure Q3(b)
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). Determine the value K, so that the damping ratio of the system is 0.5. (1 % marks) i. From the result obtained in (), evaluate the transient response characteristics (rise...
question 2
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). Determine the value Kin so that the damping ratio of the system is 0.5. (1 % marks) it. From the result obtained in 0. evaluate the transient response...
Question 2 a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). i Determine the value Kso that the damping ratio of the system is 0.5. (1 % marks) i. From the result obtained in (), evaluate the transient response characteristics (rise...
a) Consider the control system in Figure 2(a). Determine the transient response characteristics (rise time, peak time, maximum overshoot and settling time) and the steady state error for the system. (2 marks) b) To improve the relative stability, the tachometer feedback are employed as shown in Figure 2(b). i Determine the value K, so that the damping ratio of the system is 0.5. (1 % marks) ii. From the result obtained in (), evaluate the transient response characteristics (rise time,...
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...
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