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Alexander-Sadiku
Fundamentals of Electric Circuits
  • Chapter 9
  •    Sinusoidal Steady-State Analysis
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Sinusoids and Phasor
Chapter 9

  • 9.1 Motivation
  • 9.2 Sinusoids’ features
  • 9.3 Phasors
  • 9.4 Phasor relationships for circuit elements
  • 9.5 Impedance and admittance
  • 9.6 Kirchhoff’s laws in the frequency domain
  • 9.7 Impedance combinations
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How to determine v(t) and i(t)?
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9.2 Sinusoids (1)
  • A sinusoid is a signal that has the form of the sine or cosine function.
  • A general expression for the sinusoid,






  • where
  • Vm  =  the amplitude of the sinusoid
  • ω  = the angular frequency in radians/s
  • Ф =  the phase
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9.2 Sinusoids (2)
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9.2 Sinusoids (3)
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9.2 Sinusoids (4)
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9.3 Phasor (1)
  • A phasor is a complex number that represents the amplitude and phase of a sinusoid.


  • It can be represented in one of the following three forms:
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9.3 Phasor (2)
  • Example 3
  • Evaluate the following complex numbers:


    • a.


    • b.
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9.3 Phasor (3)
  • Mathematic operation of complex number:
  • Addition
  • Subtraction
  • Multiplication
  • Division
  • Reciprocal
  • Square root
  • Complex conjugate
  • Euler’s identity
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9.3 Phasor (4)
  • Transform a sinusoid to and from the time  domain to the phasor domain:


  •  (time domain) (phasor domain)
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9.3 Phasor (5)
  • Example 4
  • Transform the following sinusoids to phasors:
    • i = 6cos(50t – 40o) A
    • v = –4sin(30t + 50o) V
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9.3 Phasor (6)
  • Example 5:
  •     Transform the sinusoids corresponding to phasors:
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9.3 Phasor (7)
  • The differences between v(t) and V:
  • v(t) is instantaneous or time-domain representation
    V is the frequency or phasor-domain representation.
  • v(t) is time dependent, V is not.
  • v(t) is always real with no complex term, V is generally complex.


  • Note: Phasor analysis applies only when frequency is  constant; when it is applied to two or more sinusoid signals only if they have the same frequency.
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9.3 Phasor (8)
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9.3 Phasor (9)
  • Example 6
  •    Use phasor approach, determine the current i(t) in a circuit described by the integro-differential equation.
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9.3 Phasor (10)
  • In-class exercise for Unit 6a, we can derive the differential equations for the following circuit in order to solve for vo(t) in phase domain Vo.
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9.3 Phasor (11)
  • The answer is YES!
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9.4 Phasor Relationships
for Circuit Elements (1)
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9.4 Phasor Relationships
for Circuit Elements (2)
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9.4 Phasor Relationships
for Circuit Elements (3)
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9.5 Impedance and Admittance (1)
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9.5 Impedance and Admittance (2)
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9.5 Impedance and Admittance (3)
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9.5 Impedance and Admittance (4)
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9.5 Impedance and Admittance (5)
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9.6 Kirchhoff’s Laws
in the Frequency Domain (1)
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9.7 Impedance Combinations (1)
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9.7 Impedance Combinations (2)