- Chapter 1: Circuit Variables
- Chapter 1.2: The International System of Units
- Chapter 1.5: The Ideal Basic Circuit Element
- Chapter 1.6: Power and Energy
- Chapter 10: Sinusoidal Steady-State Power Calculations
- Chapter 10.2: Average and Reactive Power
- Chapter 10.3: The rms Value and Power Calculations
- Chapter 10.5: Power Calculations
- Chapter 10.6: Maximum Power Transfer
- Chapter 11: Balanced Three-Phase Circuits
- Chapter 11.3: Analysis of the Wye-Wye Circuit
- Chapter 11.4: Analysis of the Wye-Delta Circuit
- Chapter 11.5: Power Calculations in Balanced Three-Phase Circuits
- Chapter 12: Introduction to the Laplace Transform
- Chapter 12.4: Functional Transforms
- Chapter 12.5: Operational Transforms
- Chapter 12.7: Inverse Transforms
- Chapter 12.9: Initial- and Final-Value Theorems
- Chapter 13.2: Circuit Analysis in the s Domain
- Chapter 13.3: Applications
- Chapter 13.4: The Transfer Function
- Chapter 13.5: The Transfer Function in Partial Fraction Expansions
- Chapter 13.7: The Transfer Function and the Steady-State Sinusoidal Response
- Chapter 14: Introduction to Frequency Selective Circuits
- Chapter 14.2: Low-Pass Filters
- Chapter 14.3: High-Pass Filters
- Chapter 14.4: Bandpass Filters
- Chapter 14.5: Bandreject Filters
- Chapter 15.1: First-Order Low-Pass and High-Pass Filters
- Chapter 15.2: Scaling
- Chapter 15.4: Higher Order Op Amp Filters
- Chapter 15.5: Narrowband Bandpass and Bandreject Filters
- Chapter 16: Fourier Series
- Chapter 16.2: The Fourier Coefficients
- Chapter 16.3: The Effect of Symmetry on the Fourier Coefficients
- Chapter 16.4: An Alternative Trigonometric Form of the Fourier Series
- Chapter 16.5: An Application
- Chapter 16.6: Average-Power Calculations with Periodic Functions
- Chapter 16.8: The Exponential Form of the Fourier Series
- Chapter 16.9: Amplitude and Phase Spectra
- Chapter 17: The Fourier Transform
- Chapter 17.2: The Convergence of the Fourier Integral
- Chapter 17.3: Using Laplace Transforms to Find Fourier Transforms
- Chapter 17.6: Operational Transforms
- Chapter 17.7: Circuit Applications
- Chapter 17.8: Parsevals Theorem
- Chapter 18: Two-Port Circuits
- Chapter 18.2: The Two-Port Parameters
- Chapter 18.3: Analysis of the Terminated Two-Port Circuit
- Chapter 18.4: Interconnected Two-Port Circuits
- Chapter 2: Circuit Elements
- Chapter 2.1: Voltage and Current Sources
- Chapter 2.2: Electrical Resistance (Ohms Law)
- Chapter 2.4: Kirchhoffs Laws
- Chapter 2.5: Analysis of a Circuit Containing Dependent Sources
- Chapter 3: Simple Resistive Circuits
- Chapter 3.2: Resistors in Parallel
- Chapter 3.3: The Voltage-Divider and Current-Divider Circuits
- Chapter 3.4: Voltage Division and Current Division
- Chapter 3.5: Measuring Voltage and Current
- Chapter 3.6: Measuring Resistance The Wheatstone Bridge
- Chapter 3.7: Delta-to-Wye (Pi-to-Tee) Equivalent Circuits
- Chapter 4: Techniques of Circuit Analysis
- Chapter 4.10: Thvenin and Norton Equivalents
- Chapter 4.11: More on Deriving a Thvenin Equivalent
- Chapter 4.12: Maximum Power Transfer
- Chapter 4.2: Introduction to the Node-Voltage Method
- Chapter 4.3: The Node-Voltage Method and Dependent Sources
- Chapter 4.4: The Node-Voltage Method: Some Special Cases
- Chapter 4.5: Introduction to the Mesh-Current Method
- Chapter 4.6: The Mesh-Current Method and Dependent Sources
- Chapter 4.7: The Mesh-Current Method: Some Special Cases
- Chapter 4.8: The Node-Voltage Method Versus the Mesh-Current Method
- Chapter 4.9: Source Transformations
- Chapter 5: The Operational Amplifier
- Chapter 5.2: Terminal Voltages and Currents
- Chapter 5.3: The Inverting-Amplifier Circuit
- Chapter 5.4: The Summing-Amplifier Circuit
- Chapter 5.5: The Noninverting-Amplifier Circuit
- Chapter 5.6: The Difference-Amplifier Circuit
- Chapter 5.7: A More Realistic Model for the Operational Amplifier
- Chapter 6: Inductance, Capacitance, and Mutual Inductance
- Chapter 6.1: The Inductor
- Chapter 6.2: The Capacitor
- Chapter 6.3: Series-Parallel Combinations of Inductance and Capacitance
- Chapter 6.4: Mutual Inductance
- Chapter 7: Response of First-Order RL and RC Circuits
- Chapter 7.1: The Natural Response of an RL Circuit
- Chapter 7.2: The Natural Response of an RC Circuit
- Chapter 7.3: The Step Response of RL and RC Circuits
- Chapter 7.5: Sequential Switching
- Chapter 7.6: Unbounded Response
- Chapter 8: Natural and Step Responses of RLC Circuits
- Chapter 8.1: Introduction to the Natural Response of a Parallel RLC Circuit
- Chapter 8.2: The Forms of the Natural Response of a Parallel RLC Circuit
- Chapter 8.3: The Step Response of a Parallel RLC Circuit
- Chapter 8.4: The Natural and Step Response of a Series RLC Circuit
- Chapter 9: Sinusoidal Steady-State Analysis
- Chapter 9.1: The Transformer
- Chapter 9.11: The Ideal Transformer
- Chapter 9.3: The Phasor
- Chapter 9.4: The Passive Circuit Elements in the Frequency Domain
- Chapter 9.5: Kirchhoffs Laws in the Frequency Domain
- Chapter 9.6: Series, Parallel, and Delta-to-Wye Simplifications The rules for combining impedances i
- Chapter 9.7: Source Transformations and Thvenin-Norton Equivalent Circuits
- Chapter 9.8: The Node-Voltage Method
- Chapter 9.9: The Mesh-Current Method

# Electric Circuits 10th Edition - Solutions by Chapter

## Full solutions for Electric Circuits | 10th Edition

ISBN: 9780133760033

Electric Circuits | 10th Edition - Solutions by Chapter

Get Full SolutionsThe full step-by-step solution to problem in Electric Circuits were answered by , our top Engineering and Tech solution expert on 03/13/18, 07:48PM. Since problems from 107 chapters in Electric Circuits have been answered, more than 12144 students have viewed full step-by-step answer. This expansive textbook survival guide covers the following chapters: 107. This textbook survival guide was created for the textbook: Electric Circuits, edition: 10. Electric Circuits was written by and is associated to the ISBN: 9780133760033.