T(s)= 15.2/ s^3 +8s^2+16s+15.2 From T(s) in Question # 2, use Routh Hurwitz method to make Routh table and find whether the system is stable or not. K = 15.2. Is the system stable? Why? Find poles of T(s) to find the stability of system. Is the system stable? Why? From transfer function, how we can find stability in time domain? Find inverse Laplace transform if T(s), and show that the system is stable in time domain.
T(s)= 15.2/ s^3 +8s^2+16s+15.2 From T(s) in Question # 2, use Routh Hurwitz method to make Routh table and find whether the system is stable or not. K = 15.2. Is the system stable? Why? Find poles of T(s) to find the stability of system. Is the system stable? Why? From transfer function, how we can find stability in time domain? Find inverse Laplace transform if T(s), and show that the system is stable in time domain.
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 6.16P
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T(s)= 15.2/ s^3 +8s^2+16s+15.2
- From T(s) in Question # 2, use Routh Hurwitz method to make Routh table and find whether the system is stable or not. K = 15.2. Is the system stable? Why?
- Find poles of T(s) to find the stability of system. Is the system stable? Why?
- From transfer function, how we can find stability in time domain? Find inverse Laplace transform if T(s), and show that the system is stable in time domain.
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