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Variable-Frequency Response Analysis Network performance as function of frequency. Transfer function

VARIABLE-FREQUENCY NETWORK PERFORMANCE. Variable-Frequency Response Analysis Network performance as function of frequency. Transfer function. Sinusoidal Frequency Analysis Bode plots to display frequency response data. Resistor. VARIABLE FREQUENCY-RESPONSE ANALYSIS.

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Variable-Frequency Response Analysis Network performance as function of frequency. Transfer function

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  1. VARIABLE-FREQUENCY NETWORK PERFORMANCE Variable-Frequency Response Analysis Network performance as function of frequency. Transfer function Sinusoidal Frequency Analysis Bode plots to display frequency response data

  2. Resistor VARIABLE FREQUENCY-RESPONSE ANALYSIS In AC steady state analysis the frequency is assumed constant (e.g., 60Hz). Here we consider the frequency as a variable and examine how the performance varies with the frequency. Variation in impedance of basic components

  3. Inductor

  4. Capacitor

  5. Frequency dependent behavior of series RLC network

  6. Simplified notation for basic components For all cases seen, and all cases to be studied, the impedance is of the form Moreover, if the circuit elements (L,R,C, dependent sources) are real then the expression for any voltage or current will also be a rational function in s

  7. EXAMPLE Some nomenclature NETWORK FUNCTIONS When voltages and currents are defined at different terminal pairs we define the ratios as Transfer Functions If voltage and current are defined at the same terminals we define Driving Point Impedance/Admittance To compute the transfer functions one must solve the circuit. Any valid technique is acceptable

  8. EXAMPLE We will use Thevenin’s theorem

  9. EXAMPLE (More nomenclature) POLES AND ZEROS Arbitrary network function Using the roots, every (monic) polynomial can be expressed as a product of first order terms The network function is uniquely determined by its poles and zeros and its value at some other value of s (to compute the gain)

  10. SINUSOIDAL FREQUENCY ANALYSIS Circuit represented by network function

  11. By extension HISTORY OF THE DECIBEL Originated as a measure of relative (radio) power Using log scales the frequency characteristics of network functions have simple asymptotic behavior. The asymptotes can be used as reasonable and efficient approximations

  12. Poles/zeros at the origin Frequency independent First order terms Quadratic terms for complex conjugate poles/zeros General form of a network function showing basic terms Display each basic term separately and add the results to obtain final answer Let’s examine each basic term

  13. Constant Term Poles/Zeros at the origin

  14. Simple pole or zero Asymptote for phase High freq. asymptote Behavior in the neighborhood of the corner Low freq. Asym.

  15. Simple zero Simple pole

  16. Generate magnitude and phase plots LEARNING EXAMPLE Draw asymptotes for each term Draw composites

  17. asymptotes

  18. A B C D E DETERMINING THE TRANSFER FUNCTION FROM THE BODE PLOT This is the inverse problem of determining frequency characteristics. We will use only the composite asymptotes plot of the magnitude to postulate a transfer function. The slopes will provide information on the order A. different from 0dB. There is a constant Ko B. Simple pole at 0.1 C. Simple zero at 0.5 D. Simple pole at 3 E. Simple pole at 20 If the slope is -40dB we assume double real pole. Unless we are given more data

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