Principles and Applications of Electrical Engineering
6th Edition
ISBN: 9780073529592
Author: Giorgio Rizzoni Professor of Mechanical Engineering, James A. Kearns Dr.
Publisher: McGraw-Hill Education
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Question
Chapter 3, Problem 3.70HP
To determine
The Norton equivalent seen by the resistor
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Refer to the given circuit below. Using Superposition Theorem, determine the percent contribution of E₁ to the current through R3 (lbc)-
R3E1
% contribution =
x 100
R3E1+1R3E2+¹R31
R1
R2
R3
R4
E₁
E2
T
8 Ω
6Q
4Q
7 V
11 V
5 A
R₂
C
ΤΩ
R₁
E₁
a
b
R3
RA
E₂
According to the circuit and parameters given in the figure, make your calculations and write the
table.
wmww w n
ww bbn m
w w w w
Please fill in.
www ww w
+12V
+12V
M1
M2
2kN
10kN
K
ImA/V²
0.5mA/V²
VTH
2V
1.5V
22kN
M2
MODE
33k2
M1
Ip
1kN
VGS
Vps
K1=lmA/V²
Vth1=2V; M2: K2=0.5mA/V² VTH2=1.5V
Q3) For the network shown in the figure below, determine the following:
a) fe b) Zinl and Zin2
c) Zo1 and Zo2
d) Avı, Av2, and AVT
+20 V
6.8 kQ
30 ka
6.8 ka
30 ka
0.5 F
0.5 uF
P-150
B- 150
1.5 ka
50 uF
1.5 ka
50 uF
Chapter 3 Solutions
Principles and Applications of Electrical Engineering
Ch. 3 - Use node voltage analysis to find the voltages V1...Ch. 3 - Use node voltage analysis to find the voltages V1...Ch. 3 - Using node voltage analysis in the circuit of...Ch. 3 - Using node voltage analysis in the circuit of...Ch. 3 - In the circuit shown in Figure P3.5, the mesh...Ch. 3 - In the circuit shown in Figure P3.5, the source...Ch. 3 - Use nodal analysis in the circuit of Figure P3.7...Ch. 3 - Use mesh analysis in the circuit of Figure P3.7 to...Ch. 3 - Use nodal analysis in the circuit of Figure P3.9...Ch. 3 - Use nodal analysis in the circuit of Figure P3.10...
Ch. 3 - Use nodal analysis in the circuit of Figure P3.11...Ch. 3 - Find the power delivered to the load resistor R0...Ch. 3 - For the circuit of Figure P3.13, write the nodee...Ch. 3 - Using mesh analysis, find the currents i1 and i2...Ch. 3 - Using mesh analysis, find the currents i1 and i2...Ch. 3 - Using mesh analysis, find the voltage v across the...Ch. 3 - Using mesh analysis, find the currents I1,I2 and...Ch. 3 - Using mesh analysis. Find the voltage V across the...Ch. 3 - Prob. 3.19HPCh. 3 - For the circuit of Figure P3.20, use mesh analysis...Ch. 3 - In the circuit in Figure P3.21, assume the source...Ch. 3 - For the circuit of Figure P3.22 determine: a. The...Ch. 3 - Figure P3.23 represents a temperature measurement...Ch. 3 - Use nodal analysis on the circuit in Figure P3.24...Ch. 3 - Use mesh analysis to find the mesh currents in...Ch. 3 - Use mesh analysis to find the mesh currents in...Ch. 3 - Use mesh analysis to find the currents in Figure...Ch. 3 - Use mesh analysis to find V4 in Figure P3.28. Let...Ch. 3 - Use mesh analysis to find mesh currents in Figure...Ch. 3 - Use mesh analysis to find the current i in Figure...Ch. 3 - Use mesh analysis to find the voltage gain...Ch. 3 - Use nodal analysis to find node voltages V1,V2,...Ch. 3 - Use mesh analysis to find the currents through...Ch. 3 - Prob. 3.34HPCh. 3 - Prob. 3.35HPCh. 3 - Using the data of Problem 3.35 and Figure P3.35,...Ch. 3 - Prob. 3.37HPCh. 3 - Prob. 3.38HPCh. 3 - Use nodal analysis in the circuit of Figure P3.39...Ch. 3 - Prob. 3.40HPCh. 3 - Refer to Figure P3.10 and use the principle of...Ch. 3 - Use the principle of superposition to determine...Ch. 3 - Refer to Figure P3.43 and use the principle of...Ch. 3 - Refer to Figure P3.44 and use the principle of...Ch. 3 - Refer to Figure P3.44 and use the principle of...Ch. 3 - Prob. 3.46HPCh. 3 - Use the principle of super position to determine...Ch. 3 - Prob. 3.48HPCh. 3 - Use the principle of super position to determine...Ch. 3 - Use the principle of superposition to determine...Ch. 3 - Find the Thé venin equivalent of the network...Ch. 3 - Find the Thé venin equivalent of the network seen...Ch. 3 - Find the Norton equivalent of the network seen by...Ch. 3 - Find the Norton equivalent of the network between...Ch. 3 - Find the Thé venin equivalent of the network seen...Ch. 3 - Prob. 3.56HPCh. 3 - Find the Thé venin equivalent of the network seen...Ch. 3 - Find the Thé venin equivalent network seen by...Ch. 3 - Prob. 3.59HPCh. 3 - Prob. 3.60HPCh. 3 - Prob. 3.61HPCh. 3 - Find the Thé venin equivalent resistance seen...Ch. 3 - Find the Thé venin equivalent resistance seen by...Ch. 3 - Find the Thé venin equivalent network seen from...Ch. 3 - Find the Thé’cnin equivalent resistance seen by R3...Ch. 3 - Find the Norton equivalent of the network seen by...Ch. 3 - Find the Norton equivalent of the network seen by...Ch. 3 - Prob. 3.68HPCh. 3 - Find the Norton equivalent network between...Ch. 3 - Prob. 3.70HPCh. 3 - Prob. 3.71HPCh. 3 - Prob. 3.72HPCh. 3 - The Thé venin equivalent network seen by a load Ro...Ch. 3 - The Thévenin equivalent network seen by a load Ro...Ch. 3 - Prob. 3.75HPCh. 3 - Prob. 3.76HPCh. 3 - Many practical circuit elements are non-linear;...Ch. 3 - Prob. 3.78HPCh. 3 - The non-linear diode in Figure P3.79 has the i-v...Ch. 3 - Prob. 3.80HPCh. 3 - The non-linear device D in Figure P3.81 has the...Ch. 3 - Prob. 3.82HPCh. 3 - The so-called forward-bias i-v relationship for a...
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- Use the Principle of Superposition to determine the current i through R3 in the Figure. Let R1 = 100, R2 = 40, R3 = 20, R4 = 20, R5= 20, Vs 10 V, Is = 2A. ww VS R3 ww wwwarrow_forwardRefer to the given circuit below. Using Superposition Theorem, determine the percent contribution of E₁ to the current through R3 (lbc)- 1 R3E1 % contribution = - x 100 R3E2 + 1 R1 R2 R3 R4 E₁ E2 I 3 Ω 70 4 Ω 3 Ω 7 V 8 V 5 A I R3E1 +1 R31 + R₁ E₁ a ↑ R₂ C b R3 R4 E₂ +arrow_forwardElectrical Engineering I looked that the other explnations were incorrect, so I would like for a better explanation please, especially when people were finding the gain and got it at 13000 (they used +13V in their case) +10 R, 10 k2 Rp 100 k2 +15 Vo Time 20 k2 5 k23W -15 Vô -10 (b) (a) Figure E3.1 (a) This circuit sums the input voltage v plus one-half of the balancing voltage v. Thus the output voltage v, can be set to zero even when v has a nonzero de component, (b) The three waveforms show v, the input voltage; (v + v/2), the balanced-out voltage; and vo, the amplified output voltage. If vy were directly amplified, the op amp would saturate. 3.3 Use the circuit shown in Figure E3.1 to design a de-coupled one-op-amp circuit that will amplify the +100 uV EOG to have the maximal gain possible without exceeding the typical guaranteed linear output range. Include a control that can balance (remove) series clectrode offset potentials up to +300 m V. Give all numerical values. Voltage, Varrow_forward
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