1. 1 Eeng 224 Chapter 14 Frequency Response Huseyin Bilgekul Eeng 224 Circuit Theory II Department of Electrical and Electronic Engineering Eastern Mediterranean University Chapter Objectives:  Understand the Concept of Transfer Functions.  Be Familiar with the Decibel Scale.  Learn how to make Bode Magnitude and Phase plots.  Learn about series and parallel resonant RLC circuits.  Know Different Types of Passive and Active Filters and their Characteristics.  Understand the use of scaling in circuit analysis.  Be Able to use PSpice to obtain frequency response.  Apply what is learnt to radio receiver and touch-tone telephone.

2. 2 Eeng 224 What is Frequency Response of a Circuit? It is the variation in a circuit’s behavior with change in signal frequency and may also be considered as the variation of the gain and phase with frequency. FREQUENCY RESPONSE

3. 3 Eeng 224 TRANSFER FUNCTION  The transfer function H(  ) of a circuit is the is the frequency dependent ratio of the phasor output Y(  ) to a phasor input X(  ).  Considered input and output may be either the current or the voltage variable.  4 types of possible transfer functions.

4. 4 Eeng 224 Magnitude plot for a low-pass filter TRANSFER FUNCTION of Low-pass RC Circuit R=20 kΩ C=1200 pF At low frequenciesAt high frequencies

5. 5 Eeng 224 Phase plot for a low-pass filter TRANSFER FUNCTION of Low-pass RC Circuit At low frequenciesAt high frequencies R=20 kΩ C=1200 pF

6. 6 Eeng 224 TRANSFER FUNCTION of High-pass RC Circuit Magnitude plot for a high-pass filter At high frequenciesAt low frequencies R=20 kΩ C=1200 pF

7. 7 Eeng 224 TRANSFER FUNCTION of High-pass RC Circuit Magnitude plot for a high-pass filter Phase plot for high-pass filter At high frequenciesAt low frequencies R=20 kΩ C=1200 pF

8. 8 Eeng 224 TRANSFER FUNCTION of a Band-pass RC Circuit

9. 9 Eeng 224 Frequency Response of the RC Circuit a) Time Domain RC Circuit b) Frequency Domain RC Circuit

10. 10 Eeng 224 Drawing Frequency Response of RC Circuit a) Amplitude Response b) Phase Response Low Pass Filter  The frequency value of  o is of special interest.  Because output is considerable only at low values of frequency, the circuit is also called a LOW PASS FILTER.

11. 11 Eeng 224 HIGH Pass Filter

12. 12 Eeng 224 TRANSFER FUNCTION  The transfer function H(  ) can be expressed in terms of its numerator polynomial N(  ) and its denominator polynomial D(  ).  The roots of N(  )=0 are called ZEROS of H(  ) (j  =z 1, z 2, z 3, ….). Similarly The roots of D(  )=0 are called POLES of H(  ) (j  =p 1, p 2, p 3, ….). A zero as a root of the numerator polynomial, results in a zero value of the transfer function. A pole as a root of the denominator polynomial, results in an infinite value of the transfer function.

13. 13 Eeng 224 s=j 

14. 14 Eeng 224 VxVx 0.5V x VxVx