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Ch.9 Sinusoids and Phasors

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Title: Ch.9 Sinusoids and Phasors


1
Ch.9 Sinusoids and Phasors
2
1. Introduction
  • AC is more efficient and economical to transmit
    over long distance
  • Sinusoid is a signal that has the form of the
    sine or cosine function
  • Sinusoidal current alternating current (ac)
  • Nature is sinusoidal
  • Easy to generate and transmit
  • Any practical periodic signal can be represented
    by a sum of sinusoids
  • Easy to handle mathematically

3
2. Sinusoids
  • Consider the sinusoidal voltage
  • T period of the sinusoid

4
Sinusoids (2)
  • Periodic function
  • Satisfies f(t) f(tnT), for all t and for all
    integers n
  • Hence
  • Cyclic frequency f of the sinusoid

5
Sinusoids (3)
  • Let us examine the two sinusoids
  • Trigonometric identities

6
Sinusoids (4)
  • Graphical approach
  • Used to add two sinusoids of the same frequency
  • where

7
Example 9.1
  • Find the amplitude, phase, period, and frequency
    of the sinusoid

8
Example 9.2
  • Sol)

9
3. Phasors
  • Phasor is a complex number that represents the
    amplitude and phase of a sinusoid
  • Provides a simple means of analyzing linear
    circuits excited by sinusoidal sources
  • Complex number
  • with

10
Phasors (2)
  • Operations of complex number
  • Addition
  • Subtraction
  • Multiplication
  • Division
  • Reciprocal
  • Square Root
  • Complex Conjugate

11
Phasors (3)
  • Eulers identity
  • with
  • Given a sinusoid
  • Thus, where
  • Plot of the

12
Phasors (4)
  • Phasor representation of the sinusoid v(t)

13
Phasors (5)
  • Derivative integral of v(t)
  • Derivative of v(t)
  • Phasor domain representation of derivative v(t)
  • Phasor domain rep. of Integral of v(t)

14
Phasors (6)
  • Summing sinusoids of the same frequency
  • Differences between v(t) and V
  • v(t) is time domain representation, while V is
    phasor domain rep.
  • v(t) is time dependent, while V is not
  • v(t) is always real with no complex term, while V
    is generally complex
  • Phasor analysis
  • Applies only when frequency is constant
  • Applies in manipulating two or more sinusoidal
    signals only if they are of the same frequency

15
Example 9.3
  • Evaluate these complex numbers
  • Sol)
  • a)
  • then
  • Taking the square root

16
Example
  • Example 9.4
  • Transform these sinusoids to phasors
  • Example 9.5
  • Find the sinusoids represented by these phasors

17
Example
  • Example 9.6
  • Example 9.7
  • Using the phasor approach, determine the current
    i(t)

18
4. Phasor Relationships for Circuit Elements
  • Voltage-current relationship
  • Resistor ohms law
  • Phasor form
  • Inductor
  • Phasor form

19
Phasor Relationships for Circuit Elements(2)
  • Inductor
  • The current lags the voltage by 90o.
  • Capacitor
  • Phasor form
  • The current leads the voltage by 90o.

20
Example 5.6
  • The voltage v12cos(60t45o) is applied to a 0.1H
    inductor. Find the steady-state current through
    the inductor
  • Sol)
  • Converting this to the time domain,

21
5. Impedance and Admittance
  • Voltage-current relations for three passive
    elements
  • Ohms law in phasor form
  • Imdedance Z of a circuit is the ratio of the
    phasor voltage to the phasor current I, measured
    in ohms
  • When ,
  • When ,

22
Impedance and Admittance (2)
  • Impedance Resistance j Reactance
  • where
  • Adimttance Y is the reciprocal of impedance,
    measured in siemens (S)
  • Admittance Conductance j Susceptance

23
Example 9.9
  • Find v(t) and i(t) in the circuit
  • Sol)
  • From the voltage source
  • The impedance
  • Hence the current
  • The voltage across the capacitor

24
6. Kirchhoffs law in the frequency domain
  • For KVL,
  • Then,
  • KVL holds for phasors
  • KCL holds for phasors
  • Time domain
  • Phasor domain
  • KVL KCL holds in frequency domain

25
7. Impedance Combinations
  • Consider the N series-connected impedances
  • Voltage-division relationship

26
Impedance Combinations (2)
  • Consider the N parallel-connected impedances
  • Current-division relationship

27
Example 9.10
  • Find the input impedance of the circuit with w50
    rad/s
  • Sol)
  • The input impedance is

28
Example 9.11
  • Determine vo(t) in the circuit
  • Sol)
  • Time domain ? frequency domain
  • Voltage-division principle
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