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AC STEADY-STATE ANALYSIS

Learn about sinusoidal signals, phasors, impedance, and phasor diagrams for steady-state AC circuit analysis with examples and shortcuts.

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AC STEADY-STATE ANALYSIS

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  1. AC STEADY-STATE ANALYSIS LEARNING GOALS SINUSOIDS Review basic facts about sinusoidal signals SINUSOIDAL AND COMPLEX FORCING FUNCTIONS Behavior of circuits with sinusoidal independent sources and modeling of sinusoids in terms of complex exponentials PHASORS Representation of complex exponentials as vectors. It facilitates steady-state analysis of circuits. IMPEDANCE AND ADMITANCE Generalization of the familiar concepts of resistance and conductance to describe AC steady state circuit operation PHASOR DIAGRAMS Representation of AC voltages and currents as complex vectors BASIC AC ANALYSIS USING KIRCHHOFF LAWS ANALYSIS TECHNIQUES Extension of node, loop, Thevenin and other techniques

  2. SINUSOIDS As function of time Adimensional plot

  3. RADIANS AND DEGREES BASIC TRIGONOMETRY

  4. LEARNING EXAMPLE Lags by 315 Leads by 45 degrees Leads by 225 or lags by 135

  5. LEARNING EXAMPLE Frequency in radians per second is the factor of the time variable To find phase angle we must express both sinusoids using the same trigonometric function; either sine or cosine with positive amplitude We like to have the phase shifts less than 180 in absolute value

  6. LEARNING EXTENSION

  7. Learning Example algebraic problem SINUSOIDAL AND COMPLEX FORCING FUNCTIONS If the independent sources are sinusoids of the same frequency then for any variable in the linear circuit the steady state response will be sinusoidal and of the same frequency Determining the steady state solution can be accomplished with only algebraic tools!

  8. FURTHER ANALYSIS OF THE SOLUTION

  9. SOLVING A SIMPLE ONE LOOP CIRCUIT CAN BE VERY LABORIOUS IF ONE USES SINUSOIDAL EXCITATIONS TO MAKE ANALYSIS SIMPLER ONE RELATES SINUSOIDAL SIGNALS TO COMPLEX NUMBERS. THE ANALYSIS OF STEADY STATE WILL BE CONVERTED TO SOLVING SYSTEMS OF ALGEBRAIC EQUATIONS ... … WITH COMPLEX VARIABLES If everybody knows the frequency of the sinusoid then one can skip the term exp(jwt)

  10. Learning Example

  11. SHORTCUT 1 NEW IDEA: PHASORS ESSENTIAL CONDITION ALL INDEPENDENT SOURCES ARE SINUSOIDS OF THE SAME FREQUENCY BECAUSE OF SOURCE SUPERPOSITION ONE CAN CONSIDER A SINGLE SOURCE THE STEADY STATE RESPONSE OF ANY CIRCUIT VARIABLE WILL BE OF THE FORM SHORTCUT 2: DEVELOP EFFICIENT TOOLS TO DETERMINE THE PHASOR OF THE RESPONSE GIVEN THE INPUT PHASOR(S)

  12. Learning Extensions It is essential to be able to move from sinusoids to phasor representation Learning Example Phasors can be combined using the rules of complex algebra The phasor can be obtained using only complex algebra We will develop a phasor representation for the circuit that will eliminate the need of writing the differential equation

  13. Phasor representation for a resistor PHASOR RELATIONSHIPS FOR CIRCUIT ELEMENTS RESISTORS Phasors are complex numbers. The resistor model has a geometric interpretation The voltage and current phasors are colineal In terms of the sinusoidal signals this geometric representation implies that the two sinusoids are “in phase”

  14. Relationship between sinusoids Learning Example For the geometric view use the result INDUCTORS The relationship between phasors is algebraic The voltage leads the current by 90 deg The current lags the voltage by 90 deg

  15. Relationship between sinusoids Learning Example CAPACITORS The relationship between phasors is algebraic In a capacitor the current leads the voltage by 90 deg The voltage lags the current by 90 deg

  16. LEARNING EXTENSIONS Now an example with capacitors

  17. (INPUT) IMPEDANCE (DRIVING POINT IMPEDANCE) IMPEDANCE AND ADMITTANCE For each of the passive components the relationship between the voltage phasor and the current phasor is algebraic. We now generalize for an arbitrary 2-terminal element The units of impedance are OHMS Impedance is NOT a phasor but a complex number that can be written in polar or Cartesian form. In general its value depends on the frequency

  18. KVL AND KCL HOLD FOR PHASOR REPRESENTATIONS In a similar way, one shows ... The components will be represented by their impedances and the relationships will be entirely algebraic!!

  19. LEARNING EXAMPLE SPECIAL APPLICATION: IMPEDANCES CAN BE COMBINED USING THE SAME RULES DEVELOPED FOR RESISTORS

  20. LEARNING EXTENSION

  21. (COMPLEX) ADMITTANCE

  22. LEARNING EXTENSION LEARNING EXAMPLE

  23. SERIES-PARALLEL REDUCTIONS LEARNING EXAMPLE

  24. LEARNING EXTENSION

  25. LEARNING EXAMPLE SKETCH THE PHASOR DIAGRAM FOR THE CIRCUIT CAPACITIVE CASE INDUCTIVE CASE PHASOR DIAGRAMS Display all relevant phasors on a common reference frame Very useful to visualize phase relationships among variables. Especially if some variable, like the frequency, can change Any one variable can be chosen as reference. For this case select the voltage V

  26. LEARNING EXAMPLE DO THE PHASOR DIAGRAM FOR THE CIRCUIT 2. PUT KNOWN NUMERICAL VALUES It is convenient to select the current as reference Read values from diagram! 1. DRAW ALL THE PHASORS

  27. PHASOR DIAGRAM LEARNING BY DOING Notice that I was chosen as reference

  28. LEARNING EXTENSION Draw a phasor diagram illustrating all voltages and currents Current divider DRAW PHASORS. ALL ARE KNOWN. NO NEED TO SELECT A REFERENCE

  29. BASIC ANALYSIS USING KIRCHHOFF’S LAWS PROBLEM SOLVING STRATEGY For relatively simple circuits use For more complex circuits use

  30. COMPUTE ALL THE VOLTAGES AND CURRENTS LEARNING EXAMPLE

  31. LEARNING EXTENSION THE PLAN...

  32. ANALYSIS TECHNIQUES PURPOSE: TO REVIEW ALL CIRCUIT ANALYSIS TOOLS DEVELOPED FOR RESISTIVE CIRCUITS; I.E., NODE AND LOOP ANALYSIS, SOURCE SUPERPOSITION, SOURCE TRANSFORMATION, THEVENIN’S AND NORTON’S THEOREMS. 1. NODE ANALYSIS NEXT: LOOP ANALYSIS

  33. 2. LOOP ANALYSIS ONE COULD ALSO USE THE SUPERMESH TECHNIQUE SOURCE IS NOT SHARED AND Io IS DEFINED BY ONE LOOP CURRENT NEXT: SOURCE SUPERPOSITION

  34. Circuit with voltage source set to zero (SHORT CIRCUITED) SOURCE SUPERPOSITION = Circuit with current source set to zero(OPEN) Due to the linearity of the models we must have Principle of Source Superposition + The approach will be useful if solving the two circuits is simpler, or more convenient, than solving a circuit with two sources We can have any combination of sources. And we can partition any way we find convenient

  35. 3. SOURCE SUPERPOSITION NEXT: SOURCE TRANSFORMATION

  36. Source Transformationcan be used to determine the Thevenin or Norton Equivalent... BUT THERE MAY BE MORE EFFICIENT TECHNIQUES Source transformation is a good tool to reduce complexity in a circuit ... WHEN IT CAN BE APPLIED!! “ideal sources” are not good models for real behavior of sources A real battery does not produce infinite current when short-circuited

  37. 4. SOURCE TRANSFORMATION Now a voltage to current transformation NEXT: THEVENIN

  38. Thevenin Equivalent Circuit for PART A THEVENIN’S EQUIVALENCE THEOREM

  39. Voltage Divider 5. THEVENIN ANALYSIS NEXT: NORTON

  40. Norton Equivalent Circuit for PART A NORTON’S EQUIVALENCE THEOREM

  41. 6. NORTON ANALYSIS Possible techniques: loops, source transformation, superposition

  42. LEARNING EXAMPLE WHY SKIP SUPERPOSITION AND TRANSFORMATION? NODES Notice choice of ground

  43. LOOP ANALYSIS MESH CURRENTS DETERMINED BY SOURCES MESH CURRENTS ARE ACCEPTABLE

  44. Alternative procedure to compute Thevenin impedance: 1. Set to zero all INDEPENDENT sources 2. Apply an external probe KVL FOR OPEN CIRCUIT VOLTAGE THEVENIN

  45. NORTON Now we can draw the Norton Equivalent circuit ... USE NODES

  46. Current Divider Using Norton’s method EQUIVALENCE OF SOLUTIONS Using Thevenin’s Using Node and Loop methods NORTON’S EQUIVALENT CIRCUIT

  47. LEARNING EXTENSION USE THEVENIN USE NODAL ANALYSIS

  48. LEARNING EXTENSION USING NODES USING SOURCE SUPERPOSITION

  49. LEARNING EXTENSION 1. USING SUPERPOSITION

  50. 2. USE SOURCE TRANSFORMATION

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