550 likes | 571 Vues
Chapter 5. Root Locus. In previous lecture. Chapter 4 Routh Hurwitz Criterion Steady-state error analysis. Today’s plan. Construction of Root Locus. Learning Outcomes. At the end of this lecture, students should be able to: Sketch the root locus for a given system
E N D
Chapter 5 Root Locus
In previous lecture • Chapter 4 • Routh Hurwitz Criterion • Steady-state error analysis
Today’s plan • Construction of Root Locus
Learning Outcomes • At the end of this lecture, students should be able to: • Sketch the root locus for a given system • Identify the stability of a system using root-locus analysis
Introduction • Root Locus illustrates how the poles of the closed-loop system vary with the closed-loop gain. • Graphically, the locus is the set of paths in the complex plane traced by the closed-loop poles as the root locus gain is varied from zero to infinity.
R(s) C(s) K Gc + - H block diagram of the closed loop system given a forward-loop transfer function; KGc(s)H(s) where K is the root locus gain, and the corresponding closed-loop transfer function the root locus is the set of paths traced by the roots of 1 + KGc(s)H(s) =0 • as K varies from zero to infinity. As K changes, the solution to this equation changes.
So basically, the root locus is sketch based on the characteristic equation of a given transfer function. Let say: Thus, the characteristic equation :
Root locus starts from the characteristic equation. Split into 2 equations: Magnitude condition Angle condition where
Remarks If Si is a root of the characteristic equation, then 1+G(s)H(s) = 0 OR Both the magnitude and Angle conditions must be satisfied If not satisfied Not part of root locus
Example 1 0 -1 -2
Let say my first search point, S1 S1 0 -1 -2 (A) Satisfy the angle condition FIRST (B) Magnitude condition to find K
Let say the next search point 0 -1 -2 Check whether satisfy angle condition Since angle condition was not satisfied not part of root locus
CONSTRUCTION RULES OF ROOT LOCUS 8 RULES TO FOLLOW
Construction Rules of Root Locus Assume Then
Rule 1 : When K = 0 Root at open loop poles • The R-L starts from open loop poles • The number of segments is equal to the number of open loop poles
Rule 2: When K = ∞ • The R-L terminates (end) at the open loop zeros
Rule 3: Real-axis segments On the real axis, for K > 0 the root locus exists to the left of an odd number of real-axis, finite open-loop poles and/or finite open-loop zeros Example 2 R-L doesn’t exist here R-L exist here R-L exist here
Rule 4: Angle of asymptote NP = number of poles NZ = number of zeros
Example 3 NP=3 NZ=0 Centroid
Rule 5: Centroid From example 3 Recall Thus, -1
Rule 6: Break away & break in points 0 0 -1 -1 -2 -2 Break away point Break in point How to find these points ?
Differentiate K with respect to S & equate to zero How ? Solve for S this value will either be the break away or break in point
Let say Thus,
Now, find Thus, So, notice that
Example 4 Solution: 0 -1 -2
Example 5 0 -1 -2 NP = 3 NZ = 0
0 -1 -2
Break away point Invalid, why ???
How to determine these values ? 0 -1 -2 -0.42
From characteristic equation Construct the Routh array
Since Force S1 row to zero or K=6 Replace K=6 into S2 row
0 -1 -2 -0.42
Rule 7 : Angle of departure (arrival) Finding angles of departure and arrival from complex poles & zero Root locus start from open loop poles Angle of departure Root locus terminates at open loop zeros Angle of departure
Replace in this equation To make it easier to remember: Let’s change: and let k=0, we get Angles due to poles, keep using symbol θ Since Φp= Φp+360o Re-arrange Angles due to zeros, change to symbol β Thus, the angle of departure:
Replace in this equation To make it easier to remember: Let’s change: and let k=0, we get Angles due to poles, keep using symbol θ Re-arrange Thus, the angle of arrival: Angles due to zeros, change to symbol β
Angle of Departure Angle of Arrival
Example 6 Step 1: Determine poles & zeros Np=3 Nz=0 poles at : Step 2: Maps poles & zeros on the s-plane 4 -3 0 -4
Step 4: Determine centroid poles: Step 5: Sketch asymptotes line with dotted line 4 -3 -2 0 -4
Step 6: Determine the break-away or break in points Complex numbers NO break away or break in points only exist on real-axis of s-plane
Step 7: Since complex poles exist, calculate the angle of departure 4 due to s=0 due to its complex conjugate -3 0 -4 How to determine θ?
To determine θ 4 -3 0 Thus: -4 Angle of departure : -36.87o Cross Hair
Step 8: Determine jω-crossing see RULE 8 : After this Step 9: Sketch the root locus -36.87o 4 Rule 8 -3 -2 0 -4 36.87o
Rule 8 : R-L crosses jω-axis From Characteristic equation:
Force row s1 to be zero, thus 150-K=0; K = 150 Substitute K = 150 into row s2 Since s = jω Thus
Final Sketch 5 -36.87o 4 -3 -2 0 10 points -4 36.87o -5