Problem 6: For the system shown below, make an accurate plot of the root locus and find the follo...
P. 3: For each system shown below, make an accurate plot of the root locus and find the following: a. The breakaway and break-in points b. The range of K to keep the system stable. c. The value of K that yields a stable system with critically damped second-order system d. The value of K that yields a stable system with a pair of second-order poles that have a damping ratio of 0.707 e. For system 2, find the departure...
For each system, make an accurate plot of the root locus and find the following: a) The breakaway and break-in points. b) The range of K to keep the system stable. c) The value of K that yields a stable system with critically damped second-order poles. d) The value of K that yields a stable system with a pair of second-order poles that have a damping ratio of 0.707. cally dempe secondes de protest 2) G(s) - K(s+2)(s+1) (s? –...
For the unity feedback system, where G(s) =-s-2)(s-1) make an accurate plot of the root locus and find the following: (a) The breakaway and break-in points (b) The range of K to keep the system stable (c) The value of K that yields a stable system with critically damped second-order poles (d) The value of K that yields a stable system with a pair of second-order poles that have a damping ratio of 0.707
For the system shown below, find the followings; (a) Make an accurate plot of the root locus (b) The value of K that gives a stable system with critically damped second-order poles (c ) The value of K that gives a marginally stable sytems Cs) (s-20s- I) 0.5 The characteristic equation (denominator of the closed-loop trans fer function set equal to zero) is given by
For the system shown below, find the followings; (a) Make an accurate plot of the...
1 GH(s) (s24s3s2 + 10s 24) sketch the root locus and find the following: [Section: 8.5 a. The breakaway and break-in points b. The jo-axis crossing c. The range of gain to keep the system stable d. The value of K to yield a stable system with second-order complex poles, with a damping ratio of 0.5
1 GH(s) (s24s3s2 + 10s 24) sketch the root locus and find the following: [Section: 8.5 a. The breakaway and break-in points b. The...
Note: Please draw the Root Locus plots using Rules and verify your results with Matlab Commands. Enclose both plots. For the unity feedback system, with the following transfer functions (as shown in problems 1 through 4), sketch the Root- Locus plot and find the following: (a) The break-away and break-in points (b) The jw-axis crossing (c) The angle of departures / arrivals at complex poles and zeros. (d) The range of the gain K, to keep the system stable. Problem...
Root Locus: Consider the following system (a) What are the poles of the open loop system (locations of the open loop poles)? What are zeros of the open loop system (locations of the zeros)? (b) What is the origin of the asymptotes? (c) What are the angles of asymptotes? (d) Find the break-away and break-in points. (e) Find the angles of departure for all the poles. (f) Draw the root locus plot of G(s). (g) For what values of K is the closed loop system stable?
Sketch the root-locus plot of a unity feedback system. Determine the asymptotes of the root loci. Find the points where root loci cross the imaginary axis and the value of at the crossing points. Find the breakaway point. K(s+9) G(s) =- H(S)=1 s(s+2) (s+5)
Question# 1 (25 points) For a unity feedback system with open loop transfer function K(s+10)(s+20) (s+30)(s2-20s+200) G(s) = Do the following using Matlab: a) Sketch the root locus. b) Find the range of gain, K that makes the system stable c) Find the value of K that yields a damping ratio of 0.707 for the system's closed-loop dominant poles. d) Obtain Ts, Tp, %OS for the closed loop system in part c). e) Find the value of K that yields...
Theroot-locus design method
(d) Gos)H(s)2) 5.5 Complex poles and zeros. For the systems with an open-loop transfer function given below, sketch the root locus plot. Find the asymptotes and their angles. the break-away or break-in points, the angle of arrival or departure for the complex poles and zeros, respectively, and the range of k for closed-loop stability 5 10ん k(s+21
(d) Gos)H(s)2) 5.5 Complex poles and zeros. For the systems with an open-loop transfer function given below, sketch the root...