Consider the system shown in Figure 1. Using the Routh-Hurwitz Criterion, determine the range of K...
Determine if the following systems are stable or unstable and find the range of K using the Routh-Hurwitz criterion
(20 pts) System Design Using Routh-Hurwitz Criterion: one of the reasons we learn Routh-Hurwitz Criterion is that it can help us select the system parameters to make the system stable. In this problem, we will go over this process. Considering a system with the following transfer function: 1. s +2 G(s) = s4 +5s3 2s2 +s + K 1.1 Work out the Routh-Hurwitz table. Note in this case, you will have the unknown parameter K in the table. 1.2 Based...
control systems 1) Using Routh Hurwitz Stability Criteria, determine whether the following system of equation is stable or not. a) S4+253+3S2+45+5=0 2) Using the Routh Hurwitz stability criterion, determine the range of K for stability of the following characteristic equation. a) s4+2s8+(4+K)s2+9s+25=0 3)Sketch the root-locus of the following systems a) G(s)H(s) = s(s+1)(s+2) b) G(s)H(s) = 52(8+3.6) K(5+1)
4) Using the Routh-Hurwitz Criterion, determine whether the following Polynomials are Stable or Unstable. Please Show Supporting Work: 1) H(s) = s? + 10s + 5 = 0 Stable Unstable 11) H(s) = s4 +53 + 5s2 + 20s + 10 = 0 Stable Unstable 111) H(s) = 83 + 4Ks2 + (5 + K)s + 10 = 0 The Range of K for a Stable System is: a. b. K > 0.46 K< 0.46 0<K <0.46 Unstable for all...
3) Using Routh-Hurwitz method find the range of value(s) for K for which the system with the following characteristic equation is stable.
2. Using the Routh-Hurwitz criterion, find out how many closed-loop poles of the system shown in the Figure lie in the left half-plane, in the right half-plane, and on the jw-axis. R(s) C(s) 507 s* + 3s +102 + 30s +169 S
17. Using the Routh-Hurwitz criterion, find out how many closed-loop poles of the system shown in Figure P6.5 lie in the left half-plane, in the right half- plane, and on the jw-axis. R(S) + C(s) 507 $++ 333 + 10s- +30s + 169 S
Question 2: By using Routh Hurwitz tabulation method, determine whether the unity feedback system of Figure 2 is stable if 240 G(s)- R(S) + G(S) Figure 2 a. How many poles are in the right half-plane, left-half in the system? b. Verify the system stability by using vissim simulation
Consider the unity feedback system shown below with 20 G(s)- R(s) + Es) C(s) Using Routh-Hurwitz criterion, determine where the closed-loop poles are located (i.e., right half-plane, left half-plane, jo-axis)
QS. (a) A system has the transfer function 5+1 G(s) s'+33-10s - 24 Use the Routh-Hurwitz stability check to determine whether this system is stable or not stable, and state why. [10 marks] (b) Consider the system shown in Figure 5.1, where R(s) is the system input, Y(s) is the system output, K, represents a proportional controller, G(s)=- s? +45 +8 1 and - 5 R(5) Y(s) K G(s) H(s) ) Figure 5.1 Determine the range of values of the...