- 6.6.1: If the voltage across a 7.5-F capacitor is 2te3t V, find the curren...
- 6.6.2: A capacitor has energy w(t) 10 cos2 50-mF 377t J. Determine the cur...
- 6.6.3: Design a problem to help other students better understand how capac...
- 6.6.4: A current of A flows through a 5-F capacitor. Find the voltage acro...
- 6.6.5: The voltage across a capacitor is shown in Fig. 6.45. Find the curr...
- 6.6.6: The voltage waveform in Fig. 6.46 is applied across a capacitor. Dr...
- 6.6.7: At , the voltage across a 25-mF capacitor is 10 V. Calculate the vo...
- 6.6.8: A 4-mF capacitor has the terminal voltage If the capacitor has an i...
- 6.6.9: The current through a 0.5-F capacitor is 6(1 et ) A. Determine the ...
- 6.6.10: The voltage across a 5-mF capacitor is shown in Fig. 6.47. Determin...
- 6.6.11: A 4-mF capacitor has the current waveform shown in Fig. 6.48. Assum...
- 6.6.12: A voltage of appears across a parallel combination of a 100-mF capa...
- 6.6.13: Find the voltage across the capacitors in the circuit of Fig. 6.49 ...
- 6.6.14: Series-connected 20-pF and 60-pF capacitors are placed in parallel ...
- 6.6.15: Two capacitors ( and ) are connected to a 100-V source. Find the en...
- 6.6.16: The equivalent capacitance at terminals a-b in the circuit of Fig. ...
- 6.6.17: Determine the equivalent capacitance for each of the circuits of Fi...
- 6.6.18: Find in the circuit of Fig. 6.52 if all capacitors are 4 mF.
- 6.6.19: Find the equivalent capacitance between terminals a and b in the ci...
- 6.6.20: Find the equivalent capacitance at terminals a-b of the circuit in ...
- 6.6.21: Determine the equivalent capacitance at terminals a-b of the circui...
- 6.6.22: Obtain the equivalent capacitance of the circuit in Fig. 6.56.
- 6.6.23: Using Fig. 6.57, design a problem that will help other students bet...
- 6.6.24: For the circuit in Figure 6.58, determine (a) the voltage across ea...
- 6.6.25: (a) Show that the voltage-division rule for two capacitors in serie...
- 6.6.26: Three capacitors, C1 5 mF, C2 10 mF, and C3 20 mF, are connected in...
- 6.6.27: Given that four capacitors can be connected in series and in parall...
- 6.6.28: Obtain the equivalent capacitance of the network shown in Fig. 6.60.
- 6.6.29: Determine for each circuit in Fig. 6.61.
- 6.6.30: Assuming that the capacitors are initially uncharged, find in the c...
- 6.6.31: If find and in the circuit of Fig. 6.63. i2 v(t), i (t) 1 v(0) 0,
- 6.6.32: In the circuit of Fig. 6.64, let is 50e2t mA and v (t) 1(0) 50 V, v...
- 6.6.33: Obtain the Thevenin equivalent at the terminals, a-b, of the circui...
- 6.6.34: The current through a 10-mH inductor is 10et2 A. Find the voltage a...
- 6.6.35: An inductor has a linear change in current from 50 mA to 100 mA in ...
- 6.6.36: Design a problem to help other students better understand how induc...
- 6.6.37: The current through a 12-mH inductor is 4 sin 100t A. Find the volt...
- 6.6.38: The current through a 40-mH inductor is i(t) b 0, t 6 0 te2t A, t 7...
- 6.6.39: The voltage across a 200-mH inductor is given by v(t) 3t 2 2t 4 V f...
- 6.6.40: The current through a 5-mH inductor is shown in Fig. 6.66. Determin...
- 6.6.41: The voltage across a 2-H inductor is 20(1 e2t ) V. If the initial c...
- 6.6.42: If the voltage waveform in Fig. 6.67 is applied across the terminal...
- 6.6.43: The current in an 80-mH inductor increases from 0 to 60 mA. How muc...
- 6.6.44: A 100-mH inductor is connected in parallel with a 2-k resistor. The...
- 6.6.45: If the voltage waveform in Fig. 6.68 is applied to a 10-mH inductor...
- 6.6.46: Find and the energy stored in the capacitor and inductor in the cir...
- 6.6.47: For the circuit in Fig. 6.70, calculate the value of R that will ma...
- 6.6.48: Under steady-state dc conditions, find i and in the circuit in Fig....
- 6.6.49: Find the equivalent inductance of the circuit in Fig. 6.72. Assume ...
- 6.6.50: An energy-storage network consists of seriesconnected 16-mH and 14-...
- 6.6.51: Determine at terminals a-b of the circuit in Fig. 6.73.
- 6.6.52: Using Fig. 6.74, design a problem to help other students better und...
- 6.6.53: Find at the terminals of the circuit in Fig. 6.75.
- 6.6.54: Find the equivalent inductance looking into the terminals of the ci...
- 6.6.55: Find in each of the circuits in Fig. 6.77.
- 6.6.56: Find in the circuit of Fig. 6.78.
- 6.6.57: Determine that may be used to represent the inductive network of Fi...
- 6.6.58: The current waveform in Fig. 6.80 flows through a 3-H inductor. Ske...
- 6.6.59: (a) For two inductors in series as in Fig. 6.81(a), show that the v...
- 6.6.60: In the circuit of Fig. 6.82, Determine and for v t 7 0. o i (t) o(t...
- 6.6.61: Consider the circuit in Fig. 6.83. Find: (a) and if (b) (c) energy ...
- 6.6.62: Consider the circuit in Fig. 6.84. Given that for and find: (a) (b)...
- 6.6.63: In the circuit of Fig. 6.85, sketch vo.
- 6.6.64: The switch in Fig. 6.86 has been in position A for a long time. At ...
- 6.6.65: The inductors in Fig. 6.87 are initially charged and are connected ...
- 6.6.66: The current i(t) through a 20-mH inductor is equal, in magnitude, t...
- 6.6.67: An op amp integrator has R 50 k and C 0.04 mF. If the input voltage...
- 6.6.68: A 10-V dc voltage is applied to an integrator with R 50 k , C 100 m...
- 6.6.69: An op amp integrator with R 4 M and C 1 mF has the input waveform s...
- 6.6.70: Using a single op amp, a capacitor, and resistors of 100 k or less,...
- 6.6.71: Show how you would use a single op amp to generate If the integrati...
- 6.6.72: At calculate due to the cascaded integrators in Fig. 6.89. Assume t...
- 6.6.73: Show that the circuit in Fig. 6.90 is a noninverting integrator.
- 6.6.74: The triangular waveform in Fig. 6.91(a) is applied to the input of ...
- 6.6.75: An op amp differentiator has and The input voltage is a ramp Find t...
- 6.6.76: A voltage waveform has the following characteristics: a positive sl...
- 6.6.77: The output of the op amp circuit in Fig. 6.92(a) is shown in Fig. 6...
- 6.6.78: Design an analog computer to simulate where and v 0 v (0) 0. 0(0) 2...
- 6.6.79: Design an analog computer circuit to solve the following ordinary d...
- 6.6.80: Figure 6.93 presents an analog computer designed to solve a differe...
- 6.6.81: Design an analog computer to simulate the following equation: d2 v ...
- 6.6.82: Design an op amp circuit such that where and are the input voltage ...
- 6.6.83: Your laboratory has available a large number of capacitors rated at...
- 6.6.84: An 8-mH inductor is used in a fusion power experiment. If the curre...
- 6.6.85: A square-wave generator produces the voltage waveform shown in Fig....
- 6.6.86: An electric motor can be modeled as a series combination of a resis...

# Solutions for Chapter 6: Capacitors and Inductors

## Full solutions for Fundamentals of Electric Circuits | 5th Edition

ISBN: 9780073380575

Solutions for Chapter 6: Capacitors and Inductors

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