Delmar's Standard Textbook Of Electricity
7th Edition
ISBN: 9781337900348
Author: Stephen L. Herman
Publisher: Cengage Learning
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Textbook Question
Chapter 20, Problem 1PP
Capacitive Circuits
Fill in all the missing values. Refer to the formulas that follow.
| Capacitance |
|
Frequency |
| 38
|
60 Hz | |
| 78.8
|
400 Hz | |
| 250 pF | 4.5
|
|
| 234
|
10 kHZ | |
| 240
|
50 Hz | |
| 10
|
36.8
|
|
| 560 nF | 2 MHz | |
| 15
|
60 Hz | |
| 75 nF | 560
|
|
| 470 pF | 200 kHz | |
| 6.8
|
400 Hz | |
| 34
|
450
|
Expert Solution & Answer
To determine
The missing values.
Answer to Problem 1PP
| Capacitance | Xc | Frequency |
| 38 µF | 69.8 Ω | 60 Hz |
| 5.05 µF | 78.8 Ω | 400 Hz |
| 250 pF | 4.5 kΩ | 141.47 kHz |
| 234 µF | 0.068 Ω | 10 kHz |
| 13.26 µF | 240 Ω | 50 Hz |
| 10 µF | 36.8 Ω | 432.48 Hz |
| 560 nF | 0.1421 Ω | 2 MHz |
| 176.8 nF | 15 kΩ | 60 Hz |
| 75 µF | 560 Ω | 3.78 Hz |
| 470 pF | 1.69 kΩ | 200KHz |
| 58 nF | 6.8 kΩ | 400Hz |
| 34 µF | 450 Ω | 10.4 Hz |
Explanation of Solution
Description:
We are given the following formulae,
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Students have asked these similar questions
c)
An RC circuit is given in Figure Q1.1, where Vi(t) and Vo(t) are the input and
output voltages.
(i) Derive the transfer function of the circuit.
(ii) With a unit step change of Vi(t) applied to the circuit, derive the time
response of Vo(t) with this step change.
Vi(t)
C₁
Vo(1)
R₂ C2 C3 |
R = 20 ΚΩ = 50 ΚΩ
C=C2=C3=25 μF
Figure Q1.1. RC circuit.
c) An RC circuit is given in Figure Q1. vi(t) and vo (t) are the input and output
voltages.
(i) Derive the transfer function of the circuit.
(ii) With a unit step change vi(t) applied to the circuit, derive and sketch the
time response of the circuit.
R₁ R2
v₁(t)
R3 C₁
v₁(t)
R₁ = R₂ = 10 k
R3
= 100 kn C₁ = 100 μF
Figure Q1. RC circuit.
c)
A RC circuit is given in Figure Q1.1. Vi(t) and Vo(t) are the input and output
voltages.
(i) Derive the transfer function of the circuit.
(ii)
With a unit step change of Vi(t) applied to the circuit, derive the time
response of the circuit.
C₁ C₂
Vi(t)
Vo(1)
R₁ C₂
R-25 k C=C2=50 µF
Figure Q1.1. RC circuit.
Chapter 20 Solutions
Delmar's Standard Textbook Of Electricity
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