Bode diagram
- 1. Control system Bode diagram Copyright © 2014 Addaani
- 2. Group names: 1. A/rizak mohamed ahmed……31 2. A/kadir A/llahi adan…………34 3. Abukar Hassan Takow………38 4. Ahmed A/aziiz yasiin…………64 Lecturer: ENG-mahamuud A/qadir Copyright © 2014 Addaani
- 3. Outline part: one Introduction to frequency response Amplitude ratio and phase part: two Introduction to bode diagram System analysis using bode diagram Copyright © 2014 Addaani
- 4. Frequency response • System response to sinusoidal input is known us frequency response • Range of frequency used • Used for system identification • Used for stability analysis Copyright © 2014 Addaani
- 5. Frequency response System behavior determined from the steady state response to sinusoidal input in the form R =Asineᾢt Sine wave used : Easy to analyse Easy to generate Easy to measure experimentally Copyright © 2014 Addaani
- 6. Cont…… Sinusoidal applied to linear system: Output will be sinusoidal Output amplitude is proportional to input Harmonic input produces harmonic output at same frequency Variation amplitude and phase Function of frequency Copyright © 2014 Addaani
- 7. CONT…… If output flows input is known lag system Copyright © 2014 Addaani
- 8. BODE DIAGRAM PART :TWO BODE DIAGRAM Copyright © 2014 Addaani
- 9. INTRODUCTION Hendrik Wade Bode (1905–1982), while working at Bell Labs in the United States in the 1930s, devised a simple but accurate method for graphing gain and phase-shift plots. These bear his name, Bode gain plot and Bode phase plot. Copyright © 2014
- 10. What is Bode plot? The Bode plot is the frequency response plot of the transfer function of a system. Bode plot consists of two graphs: One is the plot of magnitude of sinusoidal transfer function versus log . The other is a plot of the phase angle of a sinusoidal function versus log . Copyright © 2014 Addaani
- 11. BODE DIAGRAM Copyright © 2014 Addaani
- 12. BODE PLOTS A Bode plot is a standard format for plotting frequency response of LTI systems. Becoming familiar with this format is useful because: It is a standard format, so using that format facilitates communication between engineers. Many common system behaviors produce simple shapes (e.g. straight lines) on a Bode plot, so it is easy to either look at a plot and recognize the system behavior, or to sketch a plot from what you know about the system behavior. Copyright © 2014 Addaani
- 13. cont • That format is a log frequency scale on the horizontal axis and, on the vertical axis, phase in degrees and magnitude in decibels. Thus, we begin with a review of decibels: Decibels Definition: for voltages or other physical variables (current, velocity, pressure, etc.) (Since power is proportional to voltage squared (or current, velocity, pressure, etc., squared) Copyright © 2014 Addaani
- 14. Constructing bode diagram Constructing bode diagram Section of TF can be represented as straight lines =asymptotic approximation Example: Copyright © 2014 Addaani
- 15. Phase Copyright © 2014 Addaani
- 16. Cont….. Phase plot :this has three asymptotes A LF horizontal asymptote at 0 A HF horizontal asymptote at -45 A mid –frequency asymptote that intersects between HF and LF asymptote -90 Copyright © 2014 Addaani
- 17. Cont….. Each of TF has certain type of frequency response: Building blocks: Gain Differentiator Integrator First order/second order Copyright © 2014 Addaani
- 18. Gain………K • Constant terms such as K contribute a straight horizontal line of magnitude 20 log10(K) • A positive constant, K has no effect on phase Copyright © 2014 Addaani
- 19. Differentiator…….. | j | • A zero at the origin occurs when there is an s or j? multiplying the numerator. Each occurrence of this • causes a positively sloped line passing through ? = 1 with a rise of 20 db over a decade. Copyright © 2014 Addaani
- 20. Cont……. • Effect of Zeros at the origin on Phase Angle: • Zeros at the origin, s, cause a constant +90 degree shift for each zero. Copyright © 2014 Addaani
- 21. Integrator………1/s or 1/jw • A pole at the origin occurs when there are s or j? multiplying the denominator. Each occurrence of this • causes a negatively sloped line passing through ? = 1 with a drop of 20 db over a decade. Copyright © 2014 Addaani
- 22. Cont…… • Effect of Poles at the origin on Phase Angle: • Poles at the origin, s -1, cause a constant -90 degree shift for each pole. Copyright © 2014 Addaani
- 23. first order lead Copyright © 2014 Addaani
- 24. 1’s order lag Copyright © 2014 Addaani
- 25. Rules for Making Bode Plots Copyright © 2014 Addaani
- 26. Bode plots Where do the Bode diagram lines comes from? 1) Determine the Transfer Function of the system: 2) Rewrite it by factoring both the numerator and denominator into the standard form where the z s are called zeros and the p s are called poles. Copyright © 2014 Addaani
- 27. Con……. 3) Replace s with j? . Then find the Magnitude of the Transfer Function. If we take the log10 of this magnitude and multiply it by 20 it takes on the form of Copyright © 2014 Addaani
- 28. Example 1: For the transfer function given, sketch the Bode log magnitude diagram which shows how the log magnitude of the system is affected by changing input frequency. (TF=transfer function) Step 1: Repose the equation in Bode plot form: Copyright © 2014 Addaani
- 29. Con…….. Copyright © 2014 Addaani
- 30. Example 2: Your turn. Find the Bode log magnitude plot for the transfer function, Start by simplifying the transfer function form: Copyright © 2014 Addaani
- 31. Technique to get started: Copyright © 2014 Addaani
- 32. THANK YOU FOR YOUR LISTENING Copyright © 2014 Addaani