Presentation is loading. Please wait.

Presentation is loading. Please wait.

ENGR-43_Lec-06a_Fourier_XferFcn.pptx 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer, PE Licensed Electrical.

Published byDarlene Shields Modified over 9 years ago

Similar presentations

Presentation on theme: "ENGR-43_Lec-06a_Fourier_XferFcn.pptx 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer, PE Licensed Electrical."— Presentation transcript:

1 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege.edu Engineering 43 Fourier Transfer Fcn

2 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 2 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Fourier Transform  A Fourier Transform is an integral transform that re- expresses a function in terms of different Sine/Cosine waves of varying amplitudes, wavelengths, and phases.  A Conceptual Example This Irregular Signal Is the SAME as the Sum of these Sinusoids

3 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 3 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Fourier Transform  John Baptiste Joseph Fourier investigated Time Varying Heat-Flow in a Metal Bar  His great Insight: ANY Periodic Function Could be Expressed as the sum of Sinusoidal Functions  For a Given, arbitrary Periodic Function, f(t), The Fourier Equivalents

4 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 4 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Example: Square Wave  The SquareWave Shown at Bottom-Lt can be described by a sum-of-sines

5 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 5 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Transfer Fuction, H(f)  Consider a “Black Box” that takes Input Power, v in & i in Transforms this Power into an Output, v out & i out A typical transformation would be to “Filter- Out” certain electrical frequencies.  For Phasor Voltages V in & V out Define the voltage Transfer Function as

6 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 6 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Transfer Function  Note that the Transfer Function Is a Function of FREQENCY ONLY Can Change (and usually does change) the Magnitude and Phase-Angle of many of the incoming, frequency-dependent, electrical signals  Measuring an Unknown “Black Box” Apply Sinusoidal Vin (V in  0°), Measure Vout (V out  φ°) and Plot: V out / V in and φ

7 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 7 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Example Transfer Function

8 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 8 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Example Transfer Function  Find v out for v in = 1.35Vcos(40∙2πt+65°) −25

9 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 9 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Example Transfer Function  Then at 40 Hz (40∙2π rads/sec)  Recall v in  In Phasor for  Thus  Using the Values Taken from the H(f) Mag & Phase Graphs  Or in the Time Domain

10 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 10 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis MultiFrequency Example 6.2  Note the THREE Frequencies 0 Hz 1000 Hz –1000∙2π rad/sec 2000 Hz –2000∙2π rad/sec

11 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 11 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Ex6.2 Transfer Function  Apply to v in the Transfer Function  From the Transfer Function find Apply To components of v in

12 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 12 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Example 6.2  Using This H(f) Set find  Note that the above Phasors CanNOT be added as they have DIFFERENT Frequencies.

13 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 13 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Example 6.2  Because of Differing Frequencies MUST add TIME-DOMAIN Voltages  Then v out (t) is simply the SUM of the above

14 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 14 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis 1st Order Lo-Pass Filter  Consider the RC Ckt Shown below  In the Frequency Domain the Cap Impedance, Z c  Notice the Limits of Behavior  A cap is OPEN to Low-Freq SHORT to Hi-Freq

15 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 15 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis 1st Order Lo-Pass Filter  Thus the Behavior of a Cap-Based Impedance At LO-Frequencies a Cap acts as an OPEN Circuit At HI-Frequencies a Cap Acts as a SHORT Circuit  Now use Phasor V- Divider on RC ckt  Multiplying Top&Bot by j2πfC

16 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 16 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis 1st Order Lo-Pass Filter  Then the Transfer Function  ReWriting  Where  f B is the “Break point” Frequency at which H(f) falls to 70.7% of its Original Magnitude Value.  Note The Mag & Ph of H(f) in terms of f B :

17 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 17 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Lo-Pass Filter  The LoPass Filter Transfer Function  f B : is also call the Half-Power-Frequency Recall Full Power to a Resistor: Then HALF Power:

18 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 18 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis LR (LowPass) Filter  Find the Transfer Function for LR Ckt  Use Ohm Find The Single Loop Current  Then also by Ohm  ReWriting  Arrive at Xfer Fcn very similar to RC Ckt

19 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 19 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis The deciBel (dB)  Named after Alexander Graham Bell, the deciBel (dB) relates two Power Levels  SomeTimes The Power Level is Referenced to a Standard Value, P 0  In this case  ReCall a Current or Voltage delivering Power to a Resistor  Then the dB in Current or Voltage Ratios

20 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 20 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis The deciBel (dB)  dB In Terms of Voltage Ratios  Or dB for Currents  Now we Defined  Since |H(f)| is a Voltage Ratio, define

21 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 21 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis dB Plots (SemiLog) Plot  Plotting H(f) on the logarithmic dB Scale makes it easier to distinguish Very Large (10 4 vs 10 5 ) or Very Small (10 −4 vs 10 −5 ) Points on the Plots

22 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 22 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Cascaded NetWork Gain  Consider the Transfer Function of the “BlackBox” at Right  Looking inside the BlackBox find  Note that with V out1 = V in2  Or in dB form

23 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 23 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Reading Logarithmic Scales  Tools Needed Ruler Scientific Calculator  To Find a Value of a Pt Between Decades m & n Use Ruler to Measure –Decade Distance, d d –Distance from Pt to Lower Decade (Decade m), d p Then The Value at the Pt

24 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 24 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis

25 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 25 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Octave  An octave is the interval between two points where the frequency at the second point is twice the frequency of the first.  Given Frequencies f 1 & f 2 MUSICAL Octaves

26 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 26 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis WhiteBoard Work  Let’s This Nice Problem   Find the OutPut Voltage for For this Input

27 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 27 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis All Done for Today 79.5 MHz Notch Filter

28 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 28 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege.edu Engineering 43 Appendix

29 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 29 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Logarithm Change of Base Proof

30 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 30 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis

31 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 31 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis

32 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 32 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis

33 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 33 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis White Board RL Filter Problem

34 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 34 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis LR Filter Transfer Function f = 0:10:20e3 HfB = 1./sqrt(1+(f/fB).^2); plot(f,HfB,'LineWidth',3), grid, xlabel('f (Hz)'), ylabel('|H(f)') disp('showing fB plot - hit ANY KEY to continue') pause fB = 2700/(2*pi*68e-3) Hf = abs(2700./(2700 + j*2*pi*f*68e-3)); plot(f,Hf,'LineWidth',3), grid, xlabel('f (Hz)'), ylabel('|H(f)')

35 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 35 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis P5.57 Graphics

36 BMayer@ChabotCollege.edu ENGR-43_Lec-06a_Fourier_XferFcn.pptx 36 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis P5.81 Graphics

Download ppt "ENGR-43_Lec-06a_Fourier_XferFcn.pptx 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer, PE Licensed Electrical."

Similar presentations

Lecture 30 Review: First order highpass and lowpass filters Cutoff frequency Checking frequency response results Time-to-frequency domain relations for.

Lecture 30 Review: First order highpass and lowpass filters Cutoff frequency Checking frequency response results Time-to-frequency domain relations for.
Fundamentals of Electric Circuits Chapter 14 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Fundamentals of Electric Circuits Chapter 14 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
ENGR-43_Lec-06c_2ndOrder-Filter_MATLAB-BodePlots.pptx 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer,

ENGR-43_Lec-06c_2ndOrder-Filter_MATLAB-BodePlots.pptx 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer,
Coupling and Filter Circuits. Filter –a device that removes or “filters” or attenuates unwanted signals, and keeps (and sometimes magnifies) the desired.

Coupling and Filter Circuits. Filter –a device that removes or “filters” or attenuates unwanted signals, and keeps (and sometimes magnifies) the desired.
Chapter 12 RL Circuits.

Chapter 12 RL Circuits.
ENGR-43_Scope_Phase-Angle_Tutorial.ppt 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer, PE Licensed.

ENGR-43_Scope_Phase-Angle_Tutorial.ppt 1 Bruce Mayer, PE Engineering-43: Engineering Circuit Analysis Bruce Mayer, PE Licensed.
Complex Power – Background Concepts

Complex Power – Background Concepts
Bode Magnitude Plots Constructed Bode Actual Bode

Bode Magnitude Plots Constructed Bode Actual Bode
Recap Filters ABE425 Engineering Tony Grift, PhD Dept. of Agricultural & Biological Engineering University of Illinois.

Recap Filters ABE425 Engineering Tony Grift, PhD Dept. of Agricultural & Biological Engineering University of Illinois.
Noise. Noise is like a weed. Just as a weed is a plant where you do not wish it to be, noise is a signal where you do not wish it to be. The noise signal.

Noise. Noise is like a weed. Just as a weed is a plant where you do not wish it to be, noise is a signal where you do not wish it to be. The noise signal.
Slide 1EE100 Summer 2008Bharathwaj Muthuswamy EE100Su08 Lecture #12 (July 23 rd 2008) Outline –MultiSim licenses on Friday –HW #1, Midterm #1 regrade deadline:

Slide 1EE100 Summer 2008Bharathwaj Muthuswamy EE100Su08 Lecture #12 (July 23 rd 2008) Outline –MultiSim licenses on Friday –HW #1, Midterm #1 regrade deadline:
Fundamentals of Electric Circuits Chapter 14

Fundamentals of Electric Circuits Chapter 14
Quiz: Find an expression for in terms of the component symbols.

Quiz: Find an expression for in terms of the component symbols.
EE40 Summer 2006: Lecture 5 Instructor: Octavian Florescu 1 Announcements Lecture 3 updated on web. Slide 29 reversed dependent and independent sources.

EE40 Summer 2006: Lecture 5 Instructor: Octavian Florescu 1 Announcements Lecture 3 updated on web. Slide 29 reversed dependent and independent sources.
Department of EECS University of California, Berkeley EECS 105 Fall 2003, Lecture 2 Lecture 2: Transfer Functions Prof. Niknejad.

Department of EECS University of California, Berkeley EECS 105 Fall 2003, Lecture 2 Lecture 2: Transfer Functions Prof. Niknejad.
Announcements Assignment 0 solutions posted Assignment 1 due on Thursday DC circuit Lab reports due to Sajan today and tomorrow This week’s lab – AC circuits.

Announcements Assignment 0 solutions posted Assignment 1 due on Thursday DC circuit Lab reports due to Sajan today and tomorrow This week’s lab – AC circuits.
Electronic Instrumentation Experiment 5 * AC Steady State Theory * Part A: RC and RL Circuits * Part B: RLC Circuits.

Electronic Instrumentation Experiment 5 * AC Steady State Theory * Part A: RC and RL Circuits * Part B: RLC Circuits.
Experiment # 3 EE 312 Basic Electronic Instrument Laboratory September 13, 2000 See Lecture 5 Filters on 1999 EE 312/352 Website www.ee.buffalo.edu/~whalen/ee352.

Experiment # 3 EE 312 Basic Electronic Instrument Laboratory September 13, 2000 See Lecture 5 Filters on 1999 EE 312/352 Website
R,L, and C Elements and the Impedance Concept

R,L, and C Elements and the Impedance Concept
Lecture 10b Decibels – Logarithmic Measure for Power, Voltage, Current, Gain and Loss.

Lecture 10b Decibels – Logarithmic Measure for Power, Voltage, Current, Gain and Loss.

Similar presentations

Ads by Google