Alternating current voltages

Sinusoidal Waves
Presented
By
SURESH.R
H.T.No : 16705A0426

Objective of Lecture
 Discuss the characteristics of a sinusoidal wave.
 Define the mathematical relationship between the
period, frequency, and angular frequency of a sine
wave.
 Explain how to define the amplitude of a sine wave.
 Describe what a phase angle is and the difference
between lagging and leading signals.

Characteristics of a Sine Wave
 The length of time it takes to complete one cycle or conversely
the number of cycles that occur in one second.
 Period
 Frequency
 Angular Frequency
 The maximum and minimum voltage or current swing
 Amplitude
 Peak-to-peak amplitude
 Value of the root mean square (RMS)
 Average value of a sine wave
 DC offset
 Comparison between two sine waves
 Phase angle
 Lagging and leading signals

Time Period, T
mssttT 7.16
60
1
12 
The time that it takes for a
sine wave to complete one full
cycle. This can be measured
by finding the times at which
the signal crosses zero (need
two zero crossings). The unit
usually used is seconds (s).
An alternative way to measure
the period is to determine the
time required for the sine
wave return to the same
maximum or minimum value.
t1 t2

Frequency, f
 The number of cycles a sine wave will complete in one
second(fractions are okay). The unit is cycles/second
or Hertz (Hz).
 The longer the period, the lower the frequency is.
 The shorter the period, the higher the frequency is.
T
f
1

Hz
msT
f 60
7.16
11


Electric Utilities
 Standardization on the frequency of the electricity
distribution systems didn’t occur until the mid-
1900’s.
 The frequency of the ac voltage supplied by power
companies in the US is 60 Hz.
 The frequency used in much of Europe and Asia is 50 Hz.
 While some electronic circuits function properly when
connected to a power supply operating at either frequency,
some are designed for a specific frequency, which is one
reason why power adaptors are needed when you travel.
 If you look at the label on the tablet ‘brick’, the frequency
of the ac signal is specified.

Angular frequency
 Motors are used in the alternators in coal- and gas-
powered electric generation stations. One full rotation
of the motor shaft produces one complete cycle of the
ac electricity produced.
 Position of the motor shaft is measured in radians (rad)
or degrees (o).
 1 rad = 57.3o
 2p rad = 360o
rad/s37760  Hzf
T
f
p
p
2
2 

Amplitude
Peak amplitude Peak-to-Peak amplitude
ppp
ppp
II
VV
2
2



Instantaneous Value
 Instantaneous value or amplitude is the magnitude of
the sinusoid at a point in time.
VssradVtvmst
VssradVtvst
tsradVtv
94.2)]01.0)(/377sin[(5)(10
0)]0)(/377sin[(5)(0
])/377sin[(5)(




Average Value
 The average value of a
sinusoid signal is the
integral of the sine wave
over one full cycle. This
is always equal to zero.
 If the average of an ac
signal is not zero, then
there is a dc component
known as a DC offset.

Root Mean Square (RMS)
 Most equipment that measure the amplitude of a
sinusoidal signal displays the results as a root mean
square value. This is signified by the unit Vac or VRMS.
 RMS voltage and current are used to calculate the average
power associated with the voltage or current signal in one
cycle.
 
T
RMS dttv
T
V
0
2
)(
1
  RVP
VVV
RMSAve
ppRMS
2
707.0
2
2



Phase Angle
 The phase angle is an angular measurement of the
position of one sinusoid signal with respect to a
reference.
 The signal and reference must have the same frequency.

Calculation of Phase
 Suppose there are three signals
 One signal is the reference
 I have chosen the reference to be the signal in blue on the
following slide
 The phase of the other two signals will be calculated
with respect to the reference signal.
 The period of each signal should be the same, which means
that all signals have the same frequency.

Example #1
 Calculate the period, T, for the reference signal
 This is the time for a full cycle to be completed.
 T= 500 second for Signal 1
 Calculate the difference in time between zero crossings
of
 Signal 2 and Signal 1: Dt = 40 second – 0 seconds = 40 s
 Signal 3 and Signal 1: Dt = 480 seconds – 0 seconds= 480 s

Example #1 (con’t)
 The sinusoidal function that describes Signal 1, the
reference voltage, is
V(t) = 5V sin (t) where   2p/T = 12.6 mrad/s
 To write the sinusoidal function that describes Signals
2 and 3, we need to address the fact that there is a shift
in the zero crossings
V(t) = A sin (t + f) where   2p/T
f  2p Dt/T in radians or f = 360o Dt/T
 f is called the phase shift

Lagging and Leading
 Don’t get fooled by the positions of the curves on the
graph!
 Signal 2: V(t) = 5V sin [12.6 mrad/s)t – 28.8o]
 f is -0.502 radians or -28.8 degrees
 Signal 2 lags Signal 1 as it reaches zero at a later time than Signal 1
 Signal 3: V(t) = 5V sin [12.6 mrad/s)t + 14.4o]
 f is 0.251 radians or 14.4 degrees
 Signal 3 leads Signal 1 as it reaches zero at an earlier time than
Signal 1

Formulas
)sin()( f  tVtv p
where f is in degrees and the units
for  are usually not included.

Summary
 AC signals are sinusoidal functions.
 The mathematical description of the sinusoid includes the peak
amplitude and the angular frequency and may include a phase
angle.
 RMS values of a sinusoid are calculated using the
formula
 Phase angle for a sinusoid is calculated with respect to
a reference.
 A signal lags a reference when fsignal – freference < 0o.
 It leads a reference when fsignal – freference > 0o.
T
f
p
p
2
2 )sin()( f  tVtv p
 
T
RMS dttv
T
V
0
2
)(
1
pRMS VV 707.0

Alternating current voltages

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