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EEE 302 Electrical Networks II

EEE 302 Electrical Networks II. Dr. Keith E. Holbert Summer 2001. Variable-Frequency Response Analysis. As an extension of ac analysis, we now vary the frequency and observe the circuit behavior

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EEE 302 Electrical Networks II

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  1. EEE 302Electrical Networks II Dr. Keith E. Holbert Summer 2001 Lecture 19

  2. Variable-Frequency Response Analysis • As an extension of ac analysis, we now vary the frequency and observe the circuit behavior • Graphical display of frequency dependent circuit behavior can be very useful; however, quantities such as the impedance are complex valued such that we will tend to graph the magnitude of the impedance versus frequency (i.e., |Z(j)| v. f) and the phase angle versus frequency (i.e., Z(j) v. f) Lecture 19

  3. Frequency Response of a Resistor • Consider the frequency dependent impedance of the resistor, inductor and capacitor circuit elements • Resistor (R): ZR = R 0° So the magnitude and phase angle of the resistor impedance are constant, such that plotting them versus frequency yields R Magnitude of ZR () Phase of ZR (°) 0° Frequency Frequency Lecture 19

  4. Frequency Response of an Inductor • Inductor (L): ZL = L 90° The phase angle of the inductor impedance is a constant 90°, but the magnitude of the inductor impedance is directly proportional to the frequency. Plotting them vs. frequency yields (note that the inductor appears as a short at dc) 90° Magnitude of ZL () Phase of ZL (°) Frequency Frequency Lecture 19

  5. Frequency Response of a Capacitor • Capacitor (C): ZC = 1/(C)–90° The phase angle of the capacitor impedance is –90°, but the magnitude of the inductor impedance is inversely proportional to the frequency. Plotting both vs. frequency yields (note that the capacitor acts as an open circuit at dc) Magnitude of ZC () Phase of ZC (°) -90° Frequency Frequency Lecture 19

  6. X(j)ejt = X(s)est Y(j)ejt = Y(s)est H(j) = H(s) Transfer Function • Recall that the transfer function, H(s), is • The transfer function can be shown in a block diagram as • The transfer function can be separated into magnitude and phase angle information, H(j) = |H(j)| H(j) Lecture 19

  7. Common Transfer Functions • Since the transfer function, H(j), is the ratio of some output variable to some input variable, • We may define any number of transfer functions • ratio of output voltage to input current, i.e., transimpedance, Z(jω) • ratio of output current to input voltage, i.e., transadmittance, Y(jω) • ratio of output voltage to input voltage, i.e., voltage gain, GV(jω) • ratio of output current to input current, i.e., current gain, GI(jω) Lecture 19

  8. Poles and Zeros • The transfer function is a ratio of polynomials • The roots of the numerator, N(s), are called the zeros since they cause the transfer function H(s) to become zero, i.e., H(zi)=0 • The roots of the denominator, D(s), are called the poles and they cause the transfer function H(s) to become infinity, i.e., H(pi)= Lecture 19

  9. Class Examples • Extension Exercise E12.1 • Extension Exercise E12.2 Lecture 19

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