Problem 1: For a second order system with no zeros, the table shows some values of Percent Overshoot PO corresponding to the Damping Ratio : 3/4 2/3 3/5 1/2 2/5 1/3 1/4 1/8 2.84% 6.02% 9.5% 16.3% 25.38% 32.93% 44.43% 67.31% Let P(s) 1 + 5)² D) 163% You will design a constants controller C(s) = K Find the closed-loop transfer function. Then find the range of K such that the closed-loop system is BIBO stable Hyr = PC K 1+ PC s² +10s +25+ K BIBO stable for -25 < K <∞ i.e., K>-25 Find the range of K so that the percent overshoot PO of the step response is not more than

Problem 1: For a second order system with no zeros, the table shows some values of Percent Overshoot PO corresponding to the Damping Ratio : 3/4 2/3 3/5 1/2 2/5 1/3 1/4 1/8 2.84% 6.02% 9.5% 16.3% 25.38% 32.93% 44.43% 67.31% Let P(s) 1 + 5)² D) 163% You will design a constants controller C(s) = K Find the closed-loop transfer function. Then find the range of K such that the closed-loop system is BIBO stable Hyr = PC K 1+ PC s² +10s +25+ K BIBO stable for -25 < K <∞ i.e., K>-25 Find the range of K so that the percent overshoot PO of the step response is not more than

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter6: Power Flows

Section: Chapter Questions

Problem 6.15P

See similar textbooks

Similar questions

If ? = 50Ω, L = 1.5H, what value of C will cause a sourceless series RLC circuit to be a) overdamped ?, b) critically damped ?, c) underdamped?
Make the equation s(s+1)(s+2)+K=0 in the form of 1+KF(s) and explain the drawing of root-locus curves. (Note: Indicate the splitting points, centers and angles of the asymptotes)
A)Perform the N=5 point circular convolution of x and h using DFT. B)Perform the N=5 point circular convolution of x and h in time-domain.
The system whose characteristic equation is given as s3 + 2s2 + Ks + 20 = 0 is asymptotically stable for which K values
A) Reduce the block diagram. B) G1(s)= 2/s, G2(s)= 1/4s+2, G3(s)=4, H(s)=0.5 According to these; find the time constant, natural frequency, damping rate, and dynamic behavior. C)G1(s)= 2/s, G2(s)= 1/4s+2, G3(s)=4, H(s)=0.5 Find the poles, zeros, and reverse Laplace of the system. Is it stable or not?
Given the plant transfer function, G(s) = 90/ s(s+4) and H(s) = 1. Obtain (i) characteristic equation (ii) damped frequency of oscillation (iii) damping ratio (iv) settling time (v) delay time
Consider two systems one is second order and the other is third order. The characteristic equations are: as2+bs+c for the second order and as3+bs2+cs+d for the third order, where a,b,c,d are positive real numbers. Then which of the following is correct with regard to the stability of these two systems? a. stability of either system cannot be confirmed with the given data b. third order is definitely stable but second order cannot be confirmed c. both systems are definitely stable d. second order is definitely stable but third order cannot be confirmed
A series RC circuit with R = 40Ω and C = 0.1F is connected to a sinusoidal voltage v = 180sin(20t + β)V source at a time where β = 90°. The capacitor is initially uncharged. The s-domain equation for the current is given by the attached picture. Find the value of K1, K2, and K4.
The mathematical models of some continuous time systems are given above. x(t) is the input signal of the system, and y(t) is the output signal of the system. Which of the following systems is linear and which is nonlinear? For linear systems, write "linear" in the space next to the option. For non-linear systems, write "non-linear" in the space next to the option.
G(s)=35/s(s+5) find: damping ratio natural freq.
I need help with the question below Consider a causal LTI continuous system described by the differential equation y′′(t) + 3y′(t) + 2y(t) = x(t) where y(t) is the system output and x(t) is the input.1. Find the transfer function H(s) of the system.2. Find its poles and zeros. From its poles and zeros, determine if the system is BIBO stable or not.3. If x(t) = u(t) and initial conditions are zero, determine the steady-state response yss(t)4. If the initial conditions were not zero, would you get the same steady state?. Explain
Find and graph the current i(t) in the RLC circuit of the figure, where R=1 Ω, L= 0,25 H, C=0,2 F, v(t)=377sin(20t) V for (10/π) seconds ≤ t ≤ (25/π) seconds, and v(t) = 0 for 0 ≤ t < (10/π) seconds and (25/π) seconds < t < ∞, considering the initial current and load as null. (Note: Use the Laplace method as they are causal systems)