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Root Locus
- 1. Gyanmanjari Institute of Technology Department of Electrical Engineering Subject:- Controll System Engineering (2150909) Topic: Root - Locus Plot steps and procedure Name Enrollment No. Jay Makwana 151290109027 Dhruv Pandya 151290109032 Root Locus StepsAnd Procedure1 Department of Electrical Engineering Subject:- Controll System Engineering (2150909) Topic: Root - Locus Plot steps and procedure Name Enrollment No. Jay Makwana 151290109027 Dhruv Pandya 151290109032
- 2. Root – Locus Plot Determination of The Stability of a System Root Locus StepsAnd Procedure2
- 3. Index 1. Introduction 2. Steps to find Root-locus 3. Example a. Pole zero b. centroid c.Asymptotes d. Break away point e. Intersection point f.Angle of Departure 4. Root Locus On Matlab Root Locus StepsAnd Procedure3 1. Introduction 2. Steps to find Root-locus 3. Example a. Pole zero b. centroid c.Asymptotes d. Break away point e. Intersection point f.Angle of Departure 4. Root Locus On Matlab
- 4. 1. Introduction to Root Locus: The Stability of a given closed loop system depends upon the location of the roots of the characteristics equation, which is the location of the closed loop poles. If we change some parameter of a system, then the location of closed loop pole changes in 's' plane. This movement of poles in 's' plane is called as 'Root Locus'. Root Locus is a simple graphical method for determining the roots of the characteristic equation which was invented by W.R. Evans in 1948. It can be drawn by varying the parameter (usually gain of the system) from zero to infinity. Root Locus StepsAnd Procedure4 The Stability of a given closed loop system depends upon the location of the roots of the characteristics equation, which is the location of the closed loop poles. If we change some parameter of a system, then the location of closed loop pole changes in 's' plane. This movement of poles in 's' plane is called as 'Root Locus'. Root Locus is a simple graphical method for determining the roots of the characteristic equation which was invented by W.R. Evans in 1948. It can be drawn by varying the parameter (usually gain of the system) from zero to infinity.
- 5. 2. General steps for drawing the Root Locus of the given system: 1. Determine the open loop poles, zeros and a number of branches from given G(s)H(s). 2. Draw the pole-zero plot and determine the region of real axis for which the root locus exists.Also, determine the number of breakaway points (This will be explained while solving the problems). 3. Calculate the angle of asymptote. 4. Determine the centroid. 5. Calculate the breakaway points (if any). 6. Calculate the intersection point of root locus with the imaginary axis. 7. Calculate the angle of departure or angle of arrivals if any. 8. From above steps draw the overall sketch of the root locus. 9. Predict the stability and performance of the given system by the root locus. Root Locus StepsAnd Procedure5 1. Determine the open loop poles, zeros and a number of branches from given G(s)H(s). 2. Draw the pole-zero plot and determine the region of real axis for which the root locus exists.Also, determine the number of breakaway points (This will be explained while solving the problems). 3. Calculate the angle of asymptote. 4. Determine the centroid. 5. Calculate the breakaway points (if any). 6. Calculate the intersection point of root locus with the imaginary axis. 7. Calculate the angle of departure or angle of arrivals if any. 8. From above steps draw the overall sketch of the root locus. 9. Predict the stability and performance of the given system by the root locus.
- 6. 3. Let us learn the Root Locus method by solving a problem as given below: A feedback control system has an open loop transfer function, Find the root locus as K varies from zero to infinity )22)(1( 2 ssss K sHsG Root Locus StepsAnd Procedure6 A feedback control system has an open loop transfer function, Find the root locus as K varies from zero to infinity )22)(1( 2 ssss K sHsG
- 7. From the numerator, there is no 0’s term present, So, number of zeros (z) = 0 From the denominator, equating it to zero we get, :. s = 0, -3, )22)(1( 2 ssss K sHsG Poles And Zeroes: Root Locus StepsAnd Procedure7 From the numerator, there is no 0’s term present, So, number of zeros (z) = 0 From the denominator, equating it to zero we get, :. s = 0, -3, j1-
- 9. Asymptotes: Angle of asymptotes(Өp)= Where , q = 0,1,2 … (p-z-1) So here, q = 0,1,2,3 z-p 1)180(2q 0 Root Locus StepsAnd Procedure9 Angle of asymptotes(Өp)= Where , q = 0,1,2 … (p-z-1) So here, q = 0,1,2,3
- 11. Breakaway I Break in point: The characteristic equation of the transfer function is given by, 0616s15s4s 0 ds dK 6)16s15s-(4s ds dK 6s)8s5s(s-K 0K6s8s5ss 0K2)2s3)(ss(s 23 23 234 234 2 Root Locus StepsAnd Procedure11 0616s15s4s 0 ds dK 6)16s15s-(4s ds dK 6s)8s5s(s-K 0K6s8s5ss 0K2)2s3)(ss(s 23 23 234 234 2 -2.28s
- 12. Intersection Point: From the characteristic equation of the transfer function, 0K6s8s5ss 234 Ks Ks Ks s Ks 0 1 2 3 4 073.06 08.6 065 81 js s s Ks 09.1 8.6 2.8 02.88.6 08.6 2 2 2 Routh Array, Root Locus StepsAnd Procedure12 Ks Ks Ks s Ks 0 1 2 3 4 073.06 08.6 065 81 js s s Ks 09.1 8.6 2.8 02.88.6 08.6 2 2 2
- 13. Angle of Departure/Arrival: Angle of departure, w.r.t p2 431 0 0 180 pppp z zpd 0 2p 1p4p Root Locus StepsAnd Procedure13 431 0 0 180 pppp z zpd 0 -1-2-3 3p
- 14. From the figure, 000 0000 01 4 0 3 010 1 56.7156.251180 56.25156.2690135 56.26 2 1 tan 90 1351tan180 d p p p p 0 2p 1p4p Root Locus StepsAnd Procedure14 000 0000 01 4 0 3 010 1 56.7156.251180 56.25156.2690135 56.26 2 1 tan 90 1351tan180 d p p p p 0 -1-2-3 3p
- 15. 0 1.09j -2.28 j1 -3 -2 -1 0 -1.28 -1.09j -2.28 Root Locus StepsAnd Procedure15 j1
- 16. 4. Matlab Program: n=input('enter numerator ') d=input('enter denominator') g=tf(n,d) rlocus(g) Root Locus StepsAnd Procedure16 n=input('enter numerator ') d=input('enter denominator') g=tf(n,d) rlocus(g)
- 17. Root Locus StepsAnd Procedure17
- 18. Thank YouThank You Root Locus StepsAnd Procedure18