Control chap10
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The document discusses frequency response analysis of control systems. It defines frequency response as the amplitude and phase differences between the input and output sinusoids of a linear system subjected to a sinusoidal input. Frequency response consists of magnitude frequency response and phase frequency response. The document provides examples of using frequency response concepts like plotting Bode diagrams, calculating key points on Nyquist diagrams, and using the Nyquist criterion to determine stability.
![Introduction
The phase response is the sum of the
angles from the zeros of G(s) minus the
sum of angles from the poles of G(s)
drawn to points on imaginary axis.
jω
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O θ1
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θ2
X
θ3
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θ3
σ
φ ( jω1 ) = [θ1 + θ 2 ] − [θ3 + θ 4 ]](https://image.slidesharecdn.com/controlchap10-131231194116-phpapp01/85/Control-chap10-10-320.jpg)
Control chap10
- 1. CONTROL SYSTEMS THEORY Sinusoidal Tools CHAPTER 10 STB 35103
- 2. Objectives To learn the definition of frequency response To plot frequency response
- 3. Introduction In previous chapters we learn to analyze and design a control system using root locus method. Another method that can be used is frequency response.
- 4. Introduction What is frequency response? The frequency response is a representation of the system's open loop response to sinusoidal inputs at varying frequencies. The output of a linear system to a sinusoidal input is a sinusoid of the same frequency but with a different amplitude and phase. The frequency response is defined as the amplitude and phase differences between the input and output sinusoids.
- 5. Introduction Why do we use frequency response? The open-loop frequency response of a system can be used to predict the behaviour of the closed-loop system . we directly model a transfer function using physical data.
- 6. Introduction Frequency response is consists of: Magnitude frequency response, M(ω) Phase frequency response, ø(ω) M o (ω ) M (ω ) = M i (ω ) φ (ω ) = φo (ω ) − φi (ω )
- 7. Introduction A transfer function Laplace form can be change into frequency response using the following expression: G ( jω ) = G ( s ) s → jω We can plot the frequency response in two ways: Function of frequency with separate magnitude and phase plot. As a polar plot.
- 8. Introduction Magnitude and phase plot Magnitude curve can be plotted in decibels (dB) vs. log ω, where dB = 20 log M. The phase curve is plotted as phase angle vs. log ω. Data for the plots can be obtained using vectors on the s-plane drawn from the poles and zeros of G(s) to the imaginary axis.
- 9. Introduction Magnitude response at a particular frequency is the product of the vector length from the zeros of G(s) divided by the product of the vector lengths from the poles of G(s) drawn to points on the imaginary axis. jω jω1 A O O B X C X D A•B M ( jω1 ) = C•D σ
- 10. Introduction The phase response is the sum of the angles from the zeros of G(s) minus the sum of angles from the poles of G(s) drawn to points on imaginary axis. jω jω1 θ1 O θ1 O θ2 X θ3 X θ3 σ φ ( jω1 ) = [θ1 + θ 2 ] − [θ3 + θ 4 ]
- 11. Introduction Example 10.1 Find the analytical expression for the magnitude frequency response and the phase frequency response for a system G(s) = 1/ (s+2). Also, plot both the separate magnitude and phase diagrams and the polar plot.
- 12. Introduction Solution: First substitute s=jω in the system function and obtain G ( jω ) = 1 jω + 2 We always put complex number as numerator so we will multiply the above transfer function with the complex conjugate. 1 jω + 2 1 − jω + 2 = × jω + 2 − jω + 2 (2 − jω ) = 2 (ω + 4) G ( jω ) =
- 13. Introduction In order for us to plot the magnitude frequency response we must find the magnitude of the transfer function. Magnitude G(jω), M(ω) G ( jω ) = G ( jω )g ( jω )∗ G Where G(jω)* is the conjugate of G(jω), so the magnitude for transfer function in the question is G ( jω ) = = (2 − jω ) (2 + jω ) g 2 2 (ω + 4) (ω + 4) 1 (ω 2 + 4)
- 14. Introduction The phase angle of G(jω), ø(ω) B φ (ω ) = − tan −1 ÷ A (2 − jω ) A B (ω 2 + 4) 1 = 2 × (2 − jω ) (ω + 4) G ( jω ) = ω φ (ω ) = − tan −1 ÷ 2
- 15. Introduction We can plot the magnitude frequency response and phase frequency response 20 log M (ω ) = 1 ω 2 + 4 vs. log ω φ (ω ) = − tan −1 ω 2 vs. log ω
- 16. Introduction We can also plot the polar plot M (ω ) < φ (ω ) = 1 ω 2 + 4 < − tan −1 (ω 2)
- 17. Introduction Exercise 10.1 Convert the following transfer function to frequency response. Find the magnitude frequency response and phase frequency response. 1 G(s) = ( s + 2)( s + 4) Solution 1 ( jω + 2)( jω + 4) 1 = 2 2 j ω + j 4ω + j 2ω + 8 1 = 8 − ω 2 + j 6ω G ( jω ) =
- 18. Introduction 1 = 8 − ω 2 + j 6ω 1 8 − ω 2 − j 6ω = × 2 8 − ω + j 6ω 8 − ω 2 − j 6ω 8 − ω 2 − j 6ω = 64 − 8ω 2 − j 48ω − 8ω 2 + ω 4 + j 6ω 3 + j 48ω − j 6ω 3 − j 2 36ω 2 8 − ω 2 − j 6ω = 4 ω − 20ω 2 + 64
- 19. Introduction
- 21. Introduction Nyquist criterion Nyquist criterion relates the stability of a closed-loop system to the open-loop frequency response and open-loop pole location. This concept is similar to the root locus. The most important concept that we need to understand when learning Nyquist criterion is mapping contours.
- 22. Introduction Mapping contours Mapping contours means we take a point on one contours and put it into a function, F(s), thus creating a new contours.
- 25. Introduction When checking the stability of a system, the shape of contour that we will use is a counter that encircles the entire right halfplane.
- 26. Introduction The number of closed-loop poles in the right half plane (also equals zeros of 1+ G(s)H(s)), Z The number of open-loop poles in the right half plane , P The number of counterclockwise rotations about (-1,0), N N=P-Z The above relationship is called the Nyquist Criterion; and the mapping through G(s)H(s) is called the Nyquist Diagram of G(s)H(s)
- 27. Introduction Examples to determine the stability of a system P = 0, N = 0, Z = P − N = 0, the system is stable P = 0, N = −2, (clockwise '− ve ') Z = 0 − (−2) = 2,system unstable
- 28. Sketching the Nyquist Diagram The contour that encloses the right half-plane can be mapped through the function G(s)H(s) by substituting points along the contour into G(s)H(s). The points along the positive extension of the imaginary axis yield the polar frequency response of G(s)H(s). Approximation can be made to G(s)H(s) for points around the infinite semicircle by assuming that the vectors originate at the origin.
- 29. Sketching the Nyquist Diagram Example 10.4 Sketch a nyquist diagram based on the block diagram below.
- 30. Sketching the Nyquist Diagram Solution The open loop transfer function G(s), 500 G (s) = ( s + 1)( s + 10)( s + 3) Replacing s with jω yields the frequency response of G(s)H(s), i.e. G ( jω ) = 500 ( jω + 1)( jω + 10)( jω + 3) (−14ω 2 + 30) − j (43ω − ω 3 ) = 500 (−14ω 2 + 30) 2 + (43ω − ω 3 ) 2
- 31. Sketching the Nyquist Diagram Magnitude frequency response G ( jω ) = 500 (−14ω 2 + 30) 2 + (43ω − ω 3 ) 2 Phase frequency response 3 B −1 −(43ω − ω ) ∠G ( jω ) = tan ÷ = tan ÷ A −14ω 2 + 30 −1
- 32. Sketching the Nyquist Diagram Using the phase frequency response and magnitude frequency response we can calculate the key points on the Nyquist diagram. The key points that we will calculate are: Frequency when it crosses the imaginary and real axis. The magnitude and polar values during the frequency that crosses the imaginary and real axis. The magnitude and polar values when frequency is 0 and ∞.
- 33. Sketching the Nyquist Diagram When a contour crosses the real axis, the imaginary value is zero. So, the frequency during this is, (−14ω 2 + 30) − j (43ω − ω 3 ) 500 (−14ω 2 + 30) 2 + (43ω − ω 3 ) 2 (−14ω 2 + 30) (43ω − ω 3 ) = 500 −j 2 2 3 2 (−14ω + 30) + (43ω − ω ) ( −14ω 2 + 30) 2 + (43ω − ω 3 ) 2 real imaginary (43ω − ω 3 ) =0 2 2 3 2 (−14ω + 30) + (43ω − ω )
- 34. Sketching the Nyquist Diagram We need to find the frequency when imaginary is zero by finding the value of ω that could produce zero imaginary value. There are actually two conditions that could produce zero imaginary. First 0 =0 2 2 3 2 (−14ω + 30) + (43ω − ω ) Second (43ω − ω 3 ) =0 ∞
- 35. Sketching the Nyquist Diagram For the first condition, in order to get the numerator equals to zero we must find the root value of the numerator polynomial. (43ω − ω 3 ) 0 = 2 2 3 2 (−14ω + 30) + (43ω − ω ) ( −14ω 2 + 30) 2 + (43ω − ω 3 ) 2 (43ω − ω 3 ) = 0 ω1 = 0 ω2 = 6.5574 ω3 = −6.5574 There are three frequencies where the contour crosses the real axis.
- 36. Sketching the Nyquist Diagram For the second condition, the frequency values in the denominator that could produce zero imaginary value is infinity, ∞. (43ω − ω 3 ) (43ω − ω 3 ) = 2 2 3 2 (−14ω + 30) + (43ω − ω ) ∞ (−14ω 2 + 30) 2 + (43ω − ω 3 ) 2 = ∞ ω =∞
- 37. Sketching the Nyquist Diagram When a contour crosses the imaginary axis, the real value is zero. (−14ω 2 + 30) − j (43ω − ω 3 ) 500 (−14ω 2 + 30) 2 + (43ω − ω 3 ) 2 (−14ω 2 + 30) (43ω − ω 3 ) = 500 −j 2 2 3 2 (−14ω + 30) + (43ω − ω ) ( −14ω 2 + 30) 2 + (43ω − ω 3 ) 2 real imaginary (−14ω 2 + 30) =0 2 2 3 2 (−14ω + 30) + (43ω − ω )
- 38. Sketching the Nyquist Diagram There are two conditions that could produce zero real value. First 0 =0 2 2 3 2 (−14ω + 30) + (43ω − ω ) Second (−14ω 2 + 30) =0 ∞
- 39. Sketching the Nyquist Diagram Calculate the frequency values for the first condition. (−14ω 2 + 30) 0 = 2 2 3 2 (−14ω + 30) + (43ω − ω ) (−14ω 2 + 30) 2 + (43ω − ω 3 ) 2 (−14ω 2 + 30) = 0 ω = ±1.4639 Calculate the frequency values for the second condition (−14ω 2 + 30) ( −14ω 2 + 30) = 2 2 3 2 (−14ω + 30) + (43ω − ω ) ∞ ω=∞
- 40. Sketching the Nyquist Diagram Now that we know the frequencies of the key points in our polar plot we will now calculate the magnitudes and phase for each key points frequency. Cross real Cross imaginary
- 41. Sketching the Nyquist Diagram The new contour can be plot based on the key points in the previous table. ω = 6.5574 ω =∞ C ω = 1.4639 A ω=0
- 42. Sketching the Nyquist Diagram Note that the semicircle with a infinite radius, i.e., C-D, is mapped to the origin if the order the denominator of G(s) is greater than the order the numerator of G(s).