a)In the system with the block diagram shown above, calculate the parameter values a and b for a unit time (unit-step) input of ???? (peak time) value of 1 sec and ???? (settling time) value of 2 sec.
b) a) Calculate the ???? (rise time) and ???? (Maximum overshoot) of the system using the parameters you find.
a)In the system with the block diagram shown above, calculate the parameter values a and b...
Topic: Second order system 4. pts) For the linear system with a block diagram shown: a. Find the closed loop transfer function C(s)/R(s) b. Find the value of K and the location of the poles C(s) R(s) for a damping ratio equal to 0.5 S+0.8 c. When the input is a unit-step and the damping ratio is 0.5 Find Peak Time (Tp), Maximum Overshoot (Mp) and Settling Time (Ts)
I need the solution using the simulink and if any codes
available please, thanks
Problem 8: A control system for an automatic fluid dispenser is shown below: 125 pointsl Y(s) K6s + 12) Obtain the Closed-loop Transfer Function for the above block diagram. Simulate the system for a unit step input for the following values of K: 15, 30 and 50 On a single graph, plot the response curves for all three cases, for a simulation time of 20 seconds....
Problem 2 Wis) R(s) U(s) Gol (s) D a (s) E(s) H(s) Given a system as in the diagram above, use MATLAB to solve the problems: Assume we want the closed-loop system rise time to be t, 0.18 sec S + Z H(s) 1 Gpl)s(s+)et s(s 1) s + p a) Assume W(s)-0. Draw the root locus of the system assuming compensator consists only of the adjustable gain parameter K, i.e. Dct (s) Determine the approximate range of values of...
Question three The figure below shows a unit step response of a second order system. From the graph of response find: 1- The rise timet, 2- The peak timet, 3- The maximum overshoot Mp 4- The damped natural frequency w 5. The transfer function. Hence find the damping ratio ζ and the natural frequency ah-Find also the transfer function of the system. r 4 02 15 25 35 45 Question Four For the control system shown in the figure below,...
Question 2 For the system shown below use the MATLAB to find: X + 0.5s+1.3 s+1.2s+1.6s For the previous system if K-1, and the input is sin(2t) find: 1) 2) 3) 4) Peak amplitude Rise time Settling time Steady state value Question 3 For the system shown below If the input is unit step find: 1) 2) 3) 4) Peak amplitude Rise time Settling time Steady state value
Question 2 For the system shown below use the MATLAB to find:...
Problem #9 Determine the values of K and k of the closed-loop system shown in Figure 9 so that the maximum overshot in unit step response is 25 % and the peak time is 2 sec. Assume that J= 1 Kg.m? R(3) - HQ C(s) Figure 9 Problem #10 The open-loop transfer function of a unity feedback system is sis +23 It is specified that the response of the system to step inpur should have a maximum overshoot of 10...
yUCni ias the block diagram shown below. Controller Process Sensor (a) (5%) Sketch the root locus of the closed-loop system. (b) (5%) Determine the range of K that the closed-loop system is stable. (c) (5%) Find the percentage of overshoot and the steady state error due to a unit step input of the open loop system process. (d) (5%) Find the steady-state error due to a unit step input of the closed-loop syste as a function of the design parameter...
Consider the system shown in the following. Determine the value of k such that the damping ratio } is 0.5. Then obtain the rise time ty, peak time tp, maximum overshoot Mp, and settling time ts in the unit-step response. R(S) C(s) 16 $ + 0.8 k
Problem 3 (25%): The closed-loop system has the block diagram shown below. Controlle Process Sensor s + l (a) (5%) Sketch the root locus of the closed-loop system. (b) (5%) Determine the range of K that the closed-loop system is stable. (c) (5%) Find the percentage of overshoot and the steady state error due to a unit step input of the open loop system process. (d) (5%) Find the steady-state error due to a unit step input of the closed-loop...
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B1. Consider the second order system where damping ratio 3-0.6 and natural angular frequency Ww=5 rad/sec. find the rise time tr, peak time tp, maximum overshoot Mp, and settling time ts (2%) when the system is subjected to a unit-step input. I B2. Find the steady-state errors for inputs of 5 u(t), 5t u(t), and 5t.u(t) to the system shown in the following figure. The function u(t) is the unit step. R(S) +...