Series AC Circuits Analysis
ET 242 Circuit Analysis II
Electrical and Telecommunication Engineering Technology
Professor Jang
AcknowledgementAcknowledgement
I want to express my gratitude to Prentice Hall giving me the permission to use instructor’s material for developing this module. I would like to thank the Department of Electrical and Telecommunications Engineering Technology of NYCCT for giving me support to commence and complete this module. I hope this module is helpful to enhance our students’ academic performance.
OUTLINESOUTLINES
Introduction to Series ac Circuits Analysis
Voltage Divider Rule
Impedance and Phase Diagram
Series Configuration
Frequency Response for Series ac Circuits
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 2
Key Words: Impedance, Phase, Series Configuration, Voltage Divider Rule
Series & Parallel ac Circuits
Phasor algebra is used to develop a quick, direct method for solving both series and parallel ac circuits. The close relationship that exists between this method for solving for unknown quantities and the approach used for dc circuits will become apparent after a few simple examples are considered. Once this association is established, many of the rules (current divider rule, voltage divider rule, and so on) for dc circuits can be applied to ac circuits.
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 3
Series ac Circuits Impedance & the Phasor Diagram – Resistive
ElementsFrom previous lesson we found, for the purely resistive circuit in Fig. 15-1, that v and i were in phase, and the magnitude
Figure 15.1 Resistive ac circuit.
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ET162 Circuit Analysis – Ohm’s Law Boylestad 4
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ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 5
Ex. 15-1 Using complex algebra, find the current i for the circuit in Fig. 15-2. Sketch the waveforms of v and i.
FIGURE 15.3FIGURE 15.2
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ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 6
Ex. 15-2 Using complex algebra, find the voltage v for the circuit in Fig. 15- 4. Sketch the waveforms of v and i.
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FIGURE 15.4
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 3
Series ac Circuits Impedance & the Phasor Diagram – Inductive
ElementsFrom previous lesson we found that the purely inductive circuit in Fig. 15-7, voltage leads the current by 90° and that the reactance of the coil XL is determined by ωL.
Figure 15.7 Inductive ac circuit.
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Since v leads i by 90°, i must have an angle of – 90° associated with it. To satisfy this condition, θL must equal + 90°. Substituting θL = 90°, we obtain
We use the fact that θL = 90° in the following polar format for inductive reactance to ensure the proper phase relationship between the voltage and current of an inductor:
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ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 5
Ex. 15-3 Using complex algebra, find the current i for the circuit in Fig. 15- 8. Sketch the v and i curves.
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FIGURE 15.8FIGURE 15.9
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 9
Ex. 15-4 Using complex algebra, find the voltage v for the circuit in Fig. 15- 10. Sketch the v and i curves.
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FIGURE 15.10 FIGURE 15.11
Ex. 13-3 Determine the frequency of the waveform in Fig. 13-9.
From the figure, T = (25 ms – 5 ms) or (35 ms – 15 ms) = 20 ms, and
HzsT
f 501020
113
FIGURE 13.9
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 10
FIGURE 13.12 The sine wave is the only alternating waveform whose shape is not altered by the response characteristics of a pure resistor, indicator, or capacitor.
Consider the power of the following statement:
The sinusoidal waveform is the only alternating waveform whose shape is unaffected by the response characteristics of R, L, and C element.
In other word, if the voltage or current across a resistor, inductor, or capacitor is sinusoidal in nature, the resulting current or voltage for each will also have sinusoidal characteristics, as shown in Fig. 13-12.
ET162 Circuit Analysis – Ohm’s Law Boylestad 11
The Sinusoidal Waveform
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 2
FIGURE 13.13 Defining the radian.
The unit of measurement for the horizontal axis can be time, degree, or radians. The term radian can be defined as follow: If we mark off a portion of the circumference of a circle by a length equal to the radius of the circle, as shown in Fig. 13-13, the angle resulting is called 1 radian. The result is
1 rad = 57.296° ≈ 57.3°
where 57.3° is the usual approximation applied.
One full circle has 2π radians, as shown in Fig. 13-14. That is
2π rad = 360°
2π = 2(3.142) = 6.28
2π(57.3°) = 6.28(57.3°) = 359.84° ≈ 360°
FIGURE 13.14 There are 2π radian in one full circle of 360°.
ET 242 Circuit Analysis – Sinusoidal Alternating Waveforms Boylestad 13
A number of electrical formulas contain a multiplier of π. For this reason, it is sometimes preferable to measure angles in radians rather than in degrees.
The quantity is the ratio of the circumference of a circle to its diameter.
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reesRadians
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FIGURE 13.15 Plotting a sine wave versus (a) degrees and (b) radians.
For comparison purposes, two sinusoidal voltages are in Fig. 13-15 using degrees and radians as the units of measurement for the horizontal axis.
ET 242 Circuit Analysis – Sinusoidal Alternating Waveforms Boylestad 14
In Fig. 13-16, the time required to complete one revolution is equal to the period (T) of the sinusoidal waveform. The radians subtended in this time interval are 2π. Substituting, we have
ω = 2π/T or 2πf (rad/s)
FIGURE 13.17 Demonstrating the effect of ω on the frequency and period
FIGURE 13.16 Generating a sinusoidal waveform through the vertical projection of a rotating vector.
Ex. 13-4 Determine the angular velocity of a sine wave having a frequency of 60 Hz.
ω = 2πf = (2π)(60 Hz) ≈ 377 rad/s
Ex. 13-5 Determine the frequency and period of the sine wave in Fig. 13-17 (b).
HzsT
fand
mssrad
radT
TSince
58.791057.12
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57.12/500
22
,/2
3
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 15
Ex. 13-6 Given ω = 200 rad/s, determine how long it will take the sinusoidal waveform to pass through an angle of 90°.
α = ωt, and t = α / ω
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Ex. 13-7 Find the angle through which a sinusoidal waveform of 60 Hz will pass in a period of 5 ms.
α = ωt, or
α = 2πft = (2π)(60 Hz)(5 × 10-3 s) = 1.885 rad
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ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 16
General Format for the Sinusoidal Voltage or Current
The basic mathematical format for the sinusoidal waveform is
Am sin α = Am sin ωt
where Am is the peak value of the waveform and α is the unit of measure for the horizontal axis, as shown in Fig. 13-18.
For electrical quantities such as current and voltage, the general format is
i = Im sin ωt = Im sin α
e = Em sin ωt = Em sin α
where the capital letters with the subscript m represent the amplitude, and the lowercase letters I and e represent the instantaneous value of current and voltage at any time t.
FIGURE 13.18 Basic sinusoidal function.
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 17
Ex. 13-8 Given e = 5 sin α , determine e at α = 40° and α = 0.8π.
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Ex. 13-11 Given i = 6×10-3 sin 100t , determine i at t = 2 ms.
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ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 18
Phase RelationsIf the waveform is shifted to the right or left of 0°, the expression becomes
Am sin (ωt ± θ)where θ is the angle in degrees or radiations that the waveform has been shifted.
If the waveform passes through the horizontal axis with a positive going slope before 0°, as shown in Fig. 13-27, the expression is
Am sin (ωt + θ)
If the waveform passes through the horizontal axis with a positive going slope after 0°, as shown in Fig. 13-28, the expression is
Am sin (ωt – θ)
FIGURE 13.27 Defining the phase shift for a sinusoidal function that crosses the horizontal axis with a positive slope before 0°.
FIGURE 13.28 Defining the phase shift for a sinusoidal function that crosses the horizontal axis with a positive slope after 0°.
If the waveform crosses the horizontal axis with a positive-going slope 90° (π/2) sooner, as shown in Fig. 13-29, it is called a cosine wave; that is
sin (ωt + 90°)=sin (ωt + π/2) = cos πt
or sin ωt = cos (ωt – 90°) = cos (ωt – π/2)
cos α = sin (α + 90°)
sin α = cos (α – 90°)
– sin α = sin (α ± 180°)
– cos α = sin (α + 270°) = sin (α – 90°)
sin (–α) = –sin α
cos (–α) = cos α
FIGURE 13.29 Phase relationship between a sine wave and a cosine wave.
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 20
Phase Relations – The Oscilloscope
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The oscilloscope is an instrument that will display the sinusoidal alternating waveform in a way that permit the reviewing of all of the waveform’s characteristics. The vertical scale is set to display voltage levels, whereas the horizontal scale is always in units of time.
Ex. 13-13 Find the period, frequency, and peak value of the sinusoidal waveform appearing on the screen of the oscilloscope in Fig. 13-36. Note the sensitivities provided in the figure.
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VdivV
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m 2.0.
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FIGURE 13.36ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 21
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 22
An oscilloscope can also be used to make phase measurements between two sinusoidal waveforms. Oscilloscopes have the dual-trace option, that is, the ability to show two waveforms at the same time. It is important that both waveforms must have the same frequency. The equation for the phase angle can be introduced using Fig. 13-37.
First, note that each sinusoidal function has the same frequency, permitting the use of either waveform to determine the period. For the waveform chosen in Fig. 13-37, the period encompasses 5 divisions at 0.2 ms/div. The phase shift between the waveforms is 2 divisions. Since the full period represents a cycle of 360°, the following ratio can be formed:
FIGURE 13.37 Finding the phase angle between waveforms using a dual-trace oscilloscope.
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Average ValueThe concept of the average value is an important one in most technical fields. In Fig. 13-38(a), the average height of the sand may be required to determine the volume of sand available. The average height of the sand is that height obtained if the distance from one end to the other is maintained while the sand is leveled off, as shown in Fig. 13-38(b). The area under the mound in Fig. 13-38(a) then equals the area under the rectangular shape in Fig. 13-38(b) as determined by A = b × h.
FIGURE 13.38 Defining average value. FIGURE 13.39 Effect of distance (length) on average value.
FIGURE 13.40 Effect of depressions (negative excursions) on average value.
Ex. 13-14 Determine the average value of the waveforms in Fig.13-42.
FIGURE 13.42
a. By inspection, the area above the axis equals the area below over one cycle, resulting in an average value of zero volts.
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ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 24
Ex. 13-15 Determine the average value of the waveforms over one full cycle:a. Fig. 13-44.b. Fig. 13-45
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ms
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10
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FIGURE 13.44
FIGURE 13.45
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 25
Results in an average or dc level of – 7 mV, as noted by the dashed line in Fig. 13-52.
Ex. 13-16 Determine the average value of the sinusoidal waveforms in Fig. 13-51.
The average value of a pure sinusoidal waveform over one full cycle is zero.
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Ex. 13-17 Determine the average value of the waveforms in Fig. 13-52.
FIGURE 13.51
FIGURE 13.52
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ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 26
Effective (rms) Values
mmrms
mmrms
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1
This section begins to relate dc and ac quantities with respect to the power delivered to a load. The average power delivered by the ac source is just the first term, since the average value of a cosine wave is zero even though the wave may have twice the frequency of the original input current waveform. Equation the average power delivered by the ac generator to that delivered by the dc source,
Which, in words, states that
The equivalent dc value of a sinusoidal current or voltage is 1 / √2 or 0.707 of its peak value.
The equivalent dc value is called the rms or effective value of the sinusoidal quantity.
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Similarly,
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 27
Ex. 13-20 Find the rms values of the sinusoidal waveform in each part of Fig. 13-58.
FIGURE 13.58
mAA
Ia rms 48.82
1012.
3
b. Irms = 8.48 mA
Note that frequency did not change the effective value in (b) compared to (a).
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Vc rms 1202
73.169.
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 28
Ex. 13-21 The 120 V dc source in Fig. 13-59(a) delivers 3.6 W to the load. Determine the peak value of the applied voltage (Em) and the current (Im) if the ac source [Fig. 13-59(b)] is to deliver the same power to the load.
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mAV
W
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42.42)30)(414.1(2
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FIGURE 13.59
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 29
Ex. 13-22 Find the rms value of the waveform in Fig. 13-60.
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Vrms
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40
8
)4()1()4()3( 22
Ex. 13-24 Determine the average and rms values of the square wave in Fig. 13-64.
FIGURE 13.60 FIGURE 13.61
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1020
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1020
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3
3
3
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By inspection, the average value is zero.FIGURE 13.64
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 30
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 31
Ac Meters and Instruments
It is important to note whether the DMM in use is a true rms meter or simply meter where the average value is calculated to indicate the rms level. A true rms meter reads the effective value of any waveform and is not limited to only sinusoidal waveforms.
Fundamentally, conduction is permitted through the diodes in such a manner as to convert the sinusoidal input of Fig. 13-68(a) to one having been effectively “flipped over” by the bridge configuration. The resulting waveform in Fig. 13-68(b) is called a full-wave rectified waveform.
mmmmm V
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2
2
4
2
22
FIGURE 13.68 (a) Sinusoidal input; (b) full-wave rectified signal.
ET 242 Circuit Analysis II – Sinusoidal Alternating Waveforms Boylestad 2
11.1637.0
707.0
m
m
dc
rms
V
V
V
VForming the ratio between the rms and dc levels results in
Meter indication = 1.11 (dc or average value) Full-wave
Ex. 13-25 Determine the reading of each meter for each situation in Fig. 13-71(a) &(b).
For Fig. 13-71(a), situation (1): Meter indication = 1.11(20V) = 22.2V
For Fig.13-71(a), situation (2):Vrms = 0.707Vm = 0.707(20V) = 14.14V
For Fig. 13-71(b), situation (1):Vrms = Vdc = 25 V
For Fig.13-71(b), situation (2):Vrms = 0.707Vm = 0.707(15V) ≈ 10.6V
FIGURE 13.71