DC / AC Devices Theory Questions

Section 7

Basic Network Theorems
Monday
October
17
, 2011

presenterawful_3a5b1927

23aa

41f4

b479

00fcfe145ebf.doc
S7
Page
1
of
6
T F 1.
When the
load resistance
equals the
source resistance
, maximum power is delivered
to the load from the source.
T F 2.
When maximum power is delivered to the load, load power dissipation equals
source resistance power dissipation.
T F 3.
Under maximum power transfer, the efficiency factor is 100%.
T F 4.
When the load resistance is greater than the source resistance, efficiency is less than
50%.
T F 5.
When the load resistance is less than the source resistance, efficiency is grea
ter than
50%.
T F 6.
At
maximum power transfer
, load voltage is 50% of the source voltage.
T F 7.
At maximum power transfer, load current is 50% of maximum source current.
T F 8.
An ideal voltage source has zero source resistance (
r
int
).
T F
9.
The
superposition theorem
is used to simplify circuit analysis where two or more
sources are present.
T F 10.
To disable other multiple voltage sources for purposes of calculations, consider them
open circuited.
T F 11.
The final results obtai
ned from the superposition theorem are determined by
algebraically adding the values obtained.
T F 12.
The direction of current flow and the polarity of the voltage drops are not
necessary using superposition theorems.
T F 13.
Thevenin's theorem
is
used to simplify complex networks to a simple voltage
source with its source resistance.
T F 14.
Solving a Thevenized circuit is as simple as solving a single resistor series circuit.
T F 15.
Thevenin's theorem deals with a simple parallel equival
ent circuit.
T F 16.
The Thevenized voltage is felt across the load resistor analyzed.
T F 17.
The Thevenized resistance is determined by shorting out the source voltage.
T F 18.
The Thevenized resistance is always in series with the load resis
tance.
T F 19.
Voltage divider analysis can be used to find load voltage in a Thevenized
equivalent circuit.
T F 20.
A current

related approach is used to
Nortonize a
complex circuit.
T F 21.
The Norton resistance is placed in series with the N
orton current source.
T F 22.
The Norton resistance can be found the same way the Thevenized resistance is
calculated.
T F 23.
The first step in Thevenizing a circuit is to remove the load.
T F 24.
The first step in Nortonizing a circuit is to
short out the load.
T F 25.
Norton's equivalent circuit is comprised of a constant current source with a
shunt (parallel) Norton resistance.
T F 26.
Thevenin's equivalent circuit is comprised of a voltage source with a series
Thevenin's resistance.
T F 27.
Norton's and Thevenin's theorems can be used on any network using any components.
T F 28.
Ohm's law cannot be used to calculate for voltage or current distributions
when using superposition, Thevenin or Norton equivalent circuits.
T F 29
.
Norton current is determined by assigning a value of zero ohm to the load resistance.
T F 30.
Norton resistance is found by looking back into the source from the open load
terminals (
with the current source opened
).
T F 31.
Thevenin's resistanc
e is found by looking back into the source from the open
load terminals (
with the voltage source shorted
).
T F 32.
Voltage sources must be shorted, current sources must be opened, and loads
must be removed to determine source resistance.
DC / AC Devices Theory Questions

Section 7

Basic Network Theorems
Monday
October
17
, 2011

presenterawful_3a5b1927

23aa

41f4

b479

00fcfe145ebf.doc
S7
Page
2
of
6
33.
The theore
ms in this chapter deal with
A.
bilateral components.
B.
linear components.
C.
steady state conditions.
D.
All of the above.
34.
At maximum power transfer conditions,
A.
load voltage is 50% of maximum source voltage.
B.
load current is 50% of maximum sour
ce current.
C.
load resistance equals source resistance.
D.
All of the above.
35.
When load resistance is greater than source resistance
A.
efficiency is greater than 50%.
B.
efficiency is lower than 50%.
C.
efficiency equals 50%.
D.
None of the above.
3
6.
To use the superposition theorem,
A.
note the directions of current flow.
B.
note the polarity of the voltage drops.
C.
analyze one source at a time.
D.
All the above.
37.
Superposition can be used to analyze circuits containing
A.
single voltage sourc
es.
B.
single current sources.
C.
multiple current and/or voltage sources.
D.
None of the above.
38.
Norton’s theorem uses
A.
a voltage related approach.
B.
a current related approach.
C.
Both A and B.
D.
None of the above.
39.
To convert a Norton equiva
lent circuit to a Thevenin equivalent circuit,
A.
let the Norton resistance equal the Thevenin resistance.
B.
the product of Norton current and Norton resistance equals the Thevenin voltage.
C.
Both A and B.
D.
None of the above.
40.
To find the Norton pa
rameters from the Thevenin parameters,
A.
let the Thevenin resistance equal the Norton resistance.
B.
the Norton current is equal to the Thevenin voltage divided by the Thevenin resistance.
C.
Both A and B.
D.
None of the above.
DC / AC Devices Theory Questions

Section 7

Basic Network Theorems
Monday
October
17
, 2011

presenterawful_3a5b1927

23aa

41f4

b479

00fcfe145ebf.doc
S7
Page
3
of
6
41.
The first steps to Nor
tonizing a circuit are:
A.
short R
L
, determine I
L
, make I
L
= I
N
.
B.
open R
L
, determine I
L
, make I
L
= I
N
.
C.
short R
L
, determine R
N
, make V
S
/R
N
= I
N
.
D.
open R
L
, determine V
L
, make V
L
/R
L
= I
N
.
42.
The first steps to Thevenizing a circuit are:
A.
short R
L
,
determine I
L
, make I
L
= I
th
.
B.
open R
L
, determine R
th
, make V
S
/R
th
= I
th
.
C.
open R
L
, determine V
L
, make V
L
= V
th
.
D.
open R
L
, determine I
L
, make R
L
x I
L
= V
th
.
Circuit values and parameters for
Figure 7

1:
V
s
= 12 V
R
1
=
R
3
= 470
R
2
= 910
R
L
= 1
k
Determine the following unknowns:
43.
R
th
= ______________
44.
V
th
= ______________
45.
Draw the Thevenized circuit.
46.
V
L
= ______________
47.
I
L
= ______________
Change the load resistance to 470
and recalculate t
he following:
48.
V
L
= ______________
49.
I
L
= ______________
Convert the
Thevenin
circuit of Question 43, 44 to a
Norton
equivalent circuit.
50.
I
N
= ______________
51.
R
N
= ______________
52.
Draw the Norton circuit below
.
DC / AC Devices Theory Questions

Section 7

Basic Network Theorems
Monday
October
17
, 2011

presenterawful_3a5b1927

23aa

41f4

b479

00fcfe145ebf.doc
S7
Page
4
of
6
For the circuit of
Figure 7

1
on the previous page, calculate the load current and voltage
using the original circuit values of resistance and voltage. Use the basic rules for parallel and
series circuits only. Calculate for a load of 1 k
as well
as for a load of 470
. (This is for
practice using the longer method !)
53.
I
L 1 k
= _______
54.
V
L 1 k
= _______
55.
I
L
470
= _______
56.
V
L 470
= _______
57.
As far as the load voltage is concerned,
does it make any difference if you
Thevenize or Nortonize the circuit?
Answer: Yes or No.
Explain:
58.
As far as the load current is concerned, does it make any difference if you
Thevenized or Nortonized the circuit?
Answer: Yes or No.
Explain:
Circuit values and parameters
for
Figure 7

2:
V
s
= 24 V
R
1
= 3.3 k
R
2
= 6.8 k
R
3
= 7.5 k
R
4
= 5.1 k
R
L
= 1.2 k
Determine the following
unknowns:
59.
V
th
= ______________
60.
R
th
= ______________
61.
V
RL
= ______________
62.
I
L
= ______________
63.
Draw the equivalent circuit.
64.
Conventional current flows from point _______ through to point _______.
DC / AC Devices Theory Questions

Section 7

Basic Network Theorems
Monday
October
17
, 2011

presenterawful_3a5b1927

23aa

41f4

b479

00fcfe145ebf.doc
S7
Page
5
of
6
Referring again to
Figure 7

2
on the
previous page
, answer the following questions based on
the premise that th
e value of
V
s
is doubled to 48 V.
65.
V
th
would
A. double.
C. remain the same.
B. halve.
D. increase by fourfold.
66.
I
L
would
A. double.
C. remain the same.
B. halve.
D. decrease by one

fourth.
67.
The direction of current flow through R
L
would
A. remain the same.
B. reverse.
Circuit values and
parameters for
Figure 7

3:
V
s
= 100 V
I
s
= 200 mA
R
1
= 6.8 k
R
2
= 2.2 k
R
3
= 3.3 k
R
4
= 4.7 k
Determine the following
unknowns:
68.
R
T
for I
S
= ______________
69.
R
T
for V
S
= ______________
70.
I
R1
= ______________
71.
I
R2
= ______________
72.
I
R3
= ______________
73.
I
R4
= ______________
74.
V
R1
= ______________
75.
V
R2
= ____________
__
76.
V
R3
= ______________
77.
V
R4
= ______________
78.
V
A
= ______________
79.
V
B
= ______________
80.
V
BC
= ______________
81.
V
BA
= ______________
82.
Draw the equivalent current source circuit and the
voltage source circuit on a separate
piece of paper.
NOTE:
Refer to the figures you just drew. Verify your data with
Kirchhoff's voltage and current loops.
DC / AC Devices Theory Questions

Section 7

Basic Network Theorems
Monday
October
17
, 2011

presenterawful_3a5b1927

23aa

41f4

b479

00fcfe145ebf.doc
S7
Page
6
of
6
Answers for Questions 7a
1
T
2
T
3
F
4
F
5
F
6
T
7
T
8
T
9
T
10
F
11
T
12
F
13
T
14
F
15
F
16
F
17
T
18
T
19
T
20
T
21
F
22
T
23
T
24
T
25
T
26
T
27
F
28
F
29
T
30
T
31
T
32
T
33
D
34
D
35
A
36
D
37
C
38
B
39
C
40
C
41
A
42
C
43
779.93
44
7.913 V
45
Draw a voltage source of 7.91 V in series with a 780 ohm
source resistance.
46
4.446 V
47
4.446 mA
48
2.9755 V
49
6.331 mA
50
10.146 mA
51
779.93
㔲
䑲a眠a‱〮ㄴ㘠流⁃畲 e湴潵牣e⁷楴栠愠獨畮琠⡰a牡汬e氩‷㠰†
潨洠牥獩s瑯爮
㔳
㐮㐵4
㔴
㐮㐵⁖
㔵
6
⸳㌠流
㔶
㈮㤸⁖
㔷
乯⸠⁔桥潡搠ge瑳⁴桥 浥⁶潬瑡来Ⱐ,畲牥湴Ⱐ慮搠灯睥爠r湤n
獥e猠瑨攠獡浥潵牣e 牥獩獴慮se.
㔸
Sa浥猠瑨攠灲e癩潵vⁱ略獴s潮o
㔹
㘮㐴㐠6
㘰
㔮㈵㜵
㘱
ㄮㄹ㜵⁖
㘲
㤹㜮㤳9
A
㘳
䑲a眠a‶⸴㐠灯獩瑩癥⁶潬 a来潵牣e渠獥 楥猠睩瑨‵⸲㘠
欠
獯畲see獩s瑯爠t湤‱⸲ 潡搮
㘴
䄠瑯⁂潲⁃CF a湤⁂⁴漠䄠A潲汥c瑲潮汯l
㘵
A
㘶
A
㘷
A
㘸
ㄮ㌷㘠1
㘹
㔮㠷㘠5
㜰
㐹⸶㠠流
㜱
㠮1
㜲
㐲⸲㌠流
㜳
㐲⸲㌠流
㜴
㌳㜮㠱⁖
㜵
㈳㜮㠱⁖
㜶7
ㄳ㤮㌵⁖
㜷7
ㄹ㠮㐶⁖
㜸

㌳㜮㠱⁖
㜹

ㄹ㠮㐶⁖
㠰

㤸⸴㘠9
㠱
ㄳ㤮㌵⁖
㠲
䑲a眠a畲牥湴潵牣e映㈰〠流汯睩湧⁵瀠睩瑨 a‱⸳㠠欠
獨畮s潵牣e潡搮† ra眠a ga瑩癥‱〰⁖⁶潬瑡来潵牣e⁷楴栠愠
㔮㠸潡搮
乏呅㨠†䅮y湤汬⁶潬 a来爠 u牲e湴潯灳畳琠敱畡氠le牯r
Commentaires 0
Connectezvous pour poster un commentaire