Question 3 (15pts): Mechanics of Pole Placement Consider the system in Figure-2 Figure-2 write a set...
Problem 2 design of state feedback controller using pole placement for multi-input systems. Consider the system-Ar-Bu with 1. design a state feedback control u-Kr, or the gain K, to place the closed loop poles at -2,-3,-4 2. Exploiting the structure of A and B, find a different feedback gain that place the poles in the same location. This steps shows that there are several ways to design K; by inspection for instance. 3. Use the Matlab command 'place' to generate...
Problem 3. Consider the system -2 01 Design feedback control u =-Kx such that the closed-loop poles are at s=-2+)2 and s=-2-j2. Assume K= [k1
Problem 3. Consider the system -2 01 Design feedback control u =-Kx such that the closed-loop poles are at s=-2+)2 and s=-2-j2. Assume K= [k1
Consider a unity feedback control architecture where P(s) =
1/s^2 and C(s) = K * ((s + z)/(s + p)) . It is desired to design
the controller to place the dominant closed-loop poles at sd = −2 ±
2j. Fix the pole of the compensator at −20 rad/sec and use root
locus techniques to find values of z and K to place the closed–loop
poles at sd .
Problem 4 (placing a zero) Consider a unity feedback control architecture...
Problem 2 We have seen in class an algorithm for the design of state feedback controller using pole placement for multi-input systems. Consider the system-A Bu with 0 0 4 1. Using the algorithm seen in class, design a state feedback control K, or the gain K, to place the closed loop poles at-2,-3,-4. 2. Exploiting the structure of A and B, find a different feedback gain that place the poles in the same location. This steps shows that there...
could you please answer this question
QUESTION 2 Consider a system with an open-loop trans fer function given by Y(s) s+7 U(s) s2 +3s-8 (a) (8 marks) Derive a state-space model for the system in canonical form. (b) (4 marks) Check the observability of the system. (c) 8 marks) Design a suitable full-order state observer for the system. Explain your choice of the observer's poles. d) (10 marks) Design a PI controller for the system so the output of the...
Consider the following transfer function of a linear control
system
Determine the state feedback gain matrix that places the closed
system at s=-32, -3.234 ± j3.3.
Design a full order observer which produces a set of desired
closed loop poles at s=-16, -16.15±j16.5
Assume X1 is measurable, design a reduced order observer with
desired closed loop poles at -16.15±j16.5
We were unable to transcribe this image1 Y(s) U(s) (s+1)(s2+0.7s+2) Consider the following transfer function of a linear control system (a)...
Consider the following transfer function of a linear control
system
1- Determine the state feedback gain matrix that places the
closed system at s=-32, -3.234 ± j3.3.
2- Design a full order observer which produces a set of desired
closed loop poles at s=-16, -16.15±j16.5
3-Assume X1 is measurable, design a reduced order observer with
desired closed loop poles at -16.15±j16.5
We were unable to transcribe this image1 Y(s) U(s) (s+1)(s2+0.7s+2) Consider the following transfer function of a linear control...
(d) Consider the system shown in Figure 3(d), it is desired to determine the values of K1, K2 and K3 such that the dominant closed-loop poles are located at s-1+j2 design a PID controller by 9] Plant PID R(s) Y(s) (s+K, Xs+K,) 2 K X s2s1.25 S Figure Q3(d)
Question 5 The root locus of a system is provided in the following figure. C(s) R(s) + (s-2%s -I) 2.00 1.50 1.00 . 50 -.50 -2.00 2.00 -2.00 1.00 1.00 Real (a) Find the location of closed-loop system poles (design poles) to provide S -0.707 (use the provided scaled graph to avoid numerical calculations). (b) Find the value of K corresponding to the design poles. (c) Find the value of settling time corresponding to the design poles. (d) It is...
Consider the LTI system. Design a state-feedback control law of
the form u(t)= -kx(t) such that x(t) goes to zero faster than
e^-t;
Problem 1: (15 points) Consider the LTI system 3 -1 (t)1 3 0 (t)2ut 0 0-1 Desig lim sate-feedback control law of the form u(t)ka(t) such that (t goes to zero faster than e i.e. Hint: fhink of where you want to place the eigenvalues of the closed-loop system.