10 mF20 NH40. Consider the network depicted in Fig. 10.54, and determine the equivalentimpedance seen looking into the open terminals if (a) w = 1 rad/s;(b) w = 10 rad/s; (c) w = 100 rad/s.25 N55 N20 mH41. Exchange the capacitor and inductor in the network shown in Fig. 10.54,and calculate the equivalent impedance looking into the open terminals ifw = 25 rad/s.I FIGURE 10.5442. Find V in Fig. 10.55 if the box contains (a) 3 2 in series with 2 mH; (b) 3 2 inseries with 125 µF; (c) 3 2, 2 mH, and 125 µF in series; (d) 3 N, 2 mH, and125 µF in series, but w = 4 krad/s.43. Calculate the equivalent impedance seen at the open terminals of the networkshown in Fig. 10.56 if ƒ is equal to (a) 1 Hz; (b) 1 kHz; (c) 1 MHz; (d) 1 GHz;(e) 1 THz.3/-20° Aw = 2 krad/sV10 mHellFIGURE 10.5560 N60 N: 30 μFboI FIGURE 10.56ll

10 mF 20 Ω 40. Consider the network depicted in Fig. 10.54, and determine the equivalent impedance seen looking into the open terminals if (a) w = 1 rad/s; (b) w = 10 rad/s; (c) w = 100 rad/s. 25 N 55 Ω 20 mH 41. Exchange the capacitor and inductor in the network shown in Fig. 10.54, and calculate the equivalent impedance looking into the open terminals if W = 25 rad/s. I FIGURE 10.54 12 Find V in Fig 10. 55 if the boy9onteine R0 in H. (b) 3 O in

10 mF 20 Ω 40. Consider the network depicted in Fig. 10.54, and determine the equivalent impedance seen looking into the open terminals if (a) w = 1 rad/s; (b) w = 10 rad/s; (c) w = 100 rad/s. 25 N 55 Ω 20 mH 41. Exchange the capacitor and inductor in the network shown in Fig. 10.54, and calculate the equivalent impedance looking into the open terminals if W = 25 rad/s. I FIGURE 10.54 12 Find V in Fig 10. 55 if the boy9onteine R0 in H. (b) 3 O in

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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Concept explainers

Nodal Analysis

In the analysis of any electric circuit, nodal analysis is the method of determining the potential difference or voltage between different nodes in an electric circuit. A node is a point where two or more branches connect each other. In the nodal analysis, the voltages are determined in the terms of branch currents. The nodal analysis is also known as the node voltage method or branch current method. The nodal analysis method is one of the several applications of Kirchhoff's Current Law (KCL).

Question

100%

10 mF
20 N
H
40. Consider the network depicted in Fig. 10.54, and determine the equivalent
impedance seen looking into the open terminals if (a) w = 1 rad/s;
(b) w = 10 rad/s; (c) w = 100 rad/s.
25 N
55 N
20 mH
41. Exchange the capacitor and inductor in the network shown in Fig. 10.54,
and calculate the equivalent impedance looking into the open terminals if
w = 25 rad/s.
I FIGURE 10.54
42. Find V in Fig. 10.55 if the box contains (a) 3 2 in series with 2 mH; (b) 3 2 in
series with 125 µF; (c) 3 2, 2 mH, and 125 µF in series; (d) 3 N, 2 mH, and
125 µF in series, but w = 4 krad/s.
43. Calculate the equivalent impedance seen at the open terminals of the network
shown in Fig. 10.56 if ƒ is equal to (a) 1 Hz; (b) 1 kHz; (c) 1 MHz; (d) 1 GHz;
(e) 1 THz.
3/-20° A
w = 2 krad/s
V
10 mH
ell
FIGURE 10.55
60 N
60 N
: 30 μF
bo
I FIGURE 10.56
ll

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All parts or none .... I vll upvote
In the circuit of Fig. 10.77, (a) find values for I1, I2, and I3. (b) Show Vs, I1, I2, and I3 on a phasor diagram (scales of 50 V/in and 2 A/in work fine). (c) Find Is graphically and give its amplitude and phase angle.