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Modern Control System EKT 308

Modern Control System EKT 308. Root Locus Method ( contd …). Root Locus Procedure ( contd …). Root Locus Procedure. Step 1 (review):. Locate poles and zeros in the s-plane (‘x’ for poles, ‘o’ for zeros). Step 2 (review) : Locate the segments of the real axis that are root loci.

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Modern Control System EKT 308

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  1. Modern Control SystemEKT 308 Root Locus Method (contd…)

  2. Root Locus Procedure(contd…) Root Locus Procedure Step 1 (review): Locate poles and zeros in the s-plane (‘x’ for poles, ‘o’ for zeros)

  3. Step 2 (review): Locate the segments of the real axis that are root loci. The root locus on the real axis lies in a segment of the real axis to the left of an odd number of poles and zeros. Magnitude and Angle Criterion

  4. Magnitude and Angle Criterion (contd…)

  5. Figure 1: Angle for s = s1 Note: Because complex roots appear as complex conjugate pairs, root loci must be symmetrical with respect to horizontal real axis.

  6. Step 3: The loci proceed to the zeros at infinity along asymptotes centered at

  7. Example for step 3. Figure 2: Root loci on real axis

  8. Asymptotes are shown in Figure 3

  9. Figure 3: Asymptotes

  10. Step 4: Determine where the locus crosses the imaginary axis (if it does so), using Routh-Hurwitz criterion. Hint: When root locus crosses the imaginary axis from left to right, the system moves from stability to instability. Example: Complete first four steps of sketching root locus of the characteristic equation Step 1: Poles and zeros are shown in figure 4.

  11. Figure 4: Poles and zeros

  12. Step 2: There is a segment of root locus on the real axis between s=0 to s=-4 as shown in figure 4 above. The asymptotes are drawn in figure 5.

  13. Figure 5: Asymptotes

  14. Step 4.

  15. Root Locus (contd…) Step 5: Determine the break away point on the real axis (if any). The locus breakaway from the real axis occurs where there is a multiplicity of roots. At the breakaway point the angle of the tangent to the locus does not change for small change in s (fig 1). Fig 1: Breakaway point

  16. Procedure for finding breakaway point Graphical method.

  17. Poles: -2, -4 Zeros: none. Breakaway point is expected between -4 and -2 Fig 2: Poles (no zeros) Let us plot p(s) between s=-4 to s=-2. Fig 3: p(s) versus s

  18. Find the maximum point in the ps-s curve. It occurs at s = -3. So the locus breaks away at s=-3 as shown in figure 3. Fig 3: Breakaway at s=-3. b) Analytical method

  19. Step 6: Determine the angle of departure from pole and of arrival at zero The angle of locus departure from a pole = Difference between net angle due to all other poles and zeros, and the criterion angle Similar formula for calculating angle of arrival at zero. Example. Poles are zeros are shown in figure 4.

  20. In order to find angle of departure at, say complex pole -p1, place a test s1 at infinitesimal distance from -p1. From angle criterion, we get Step 7: Complete the sketch Complete all the sections of the locus not covered in the previous six steps.

  21. Figure 4: Angle of departure

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