Boston : , : Pearson, , [2016]

©2016

9781292098968 (Ebook)

1 online resource (1,219 pages) : illustrations (some color), tables

Always learning

621.319/2

Electric circuits

Electric circuit analysis - Data processing

Inglese

Includes index.

Cover -- Title Page -- Copyright Page -- Preface -- Acknowledgments -- Brief Contents -- Contents -- 1 Introduction -- 1.1 The Electrical/Electronics Industry -- 1.2 A Brief History -- 1.3 Units of Measurement -- 1.4 Systems of Units -- 1.5 Significant Figures, Accuracy, and Rounding Off -- 1.6 Powers of Ten -- 1.7 Fixed-Point, Floating-Point, Scientific, and Engineering Notation -- 1.8 Conversion Between Levels of Powers of Ten -- 1.9 Conversion Within and Between Systems of Units -- 1.10 Symbols -- 1.11 Conversion Tables -- 1.12 Calculators -- 1.13 Computer Analysis -- 2 Voltage and Current -- 2.1 Introduction -- 2.2 Atoms and Their Structure -- 2.3 Voltage -- 2.4 Current -- 2.5 Voltage Sources -- 2.6 Ampere-Hour Rating -- 2.7 Battery Life Factors -- 2.8 Conductors and Insulators -- 2.9 Semiconductors -- 2.10 Ammeters and Voltmeters -- 2.11 Applications -- 2.12 Computer Analysis -- 3 Resistance -- 3.1 Introduction -- 3.2 Resistance: Circular Wires -- 3.3 Wire Tables -- 3.4 Temperature Effects -- 3.5 Types of Resistors -- 3.6 Color Coding and Standard Resistor Values -- 3.7 Conductance -- 3.8 Ohmmeters -- 3.9 Resistance: Metric Units -- 3.10 The Fourth Element-The Memristor -- 3.11 Superconductors -- 3.12 Thermistors -- 3.13 Photoconductive Cell -- 3.14 Varistors -- 3.15 Applications -- 4 Ohm's Law, Power, and Energy -- 4.1 Introduction -- 4.2 Ohm's Law -- 4.3 Plotting Ohm's Law -- 4.4 Power -- 4.5 Energy -- 4.6 Efficiency -- 4.7 Circuit Breakers,

GFCIs, and Fuses -- 4.8 Applications -- 4.9 Computer Analysis -- 5 Series dc Circuits -- 5.1 Introduction -- 5.2 Series Resistors -- 5.3 Series Circuits -- 5.4 Power Distribution in a Series Circuit -- 5.5 Voltage Sources in Series -- 5.6 Kirchhoff's Voltage Law -- 5.7 Voltage Division in a Series Circuit -- 5.8 Interchanging Series Elements -- 5.9 Notation -- 5.10 Ground Connection Awareness.

5.11 Voltage Regulation and the Internal Resistance of Voltage Sources -- 5.12 Loading Effects of Instruments -- 5.13 Protoboards (Breadboards) -- 5.14 Applications -- 5.15 Computer Analysis -- 6 Parallel dc Circuits -- 6.1 Introduction -- 6.2 Parallel Resistors -- 6.3 Parallel Circuits -- 6.4 Power Distribution in a Parallel Circuit -- 6.5 Kirchhoff's Current Law -- 6.6 Current Divider Rule -- 6.7 Voltage Sources in Parallel -- 6.8 Open and Short Circuits -- 6.9 Voltmeter Loading Effects -- 6.10 Summary Table -- 6.11 Troubleshooting Techniques -- 6.12 Protoboards (Breadboards) -- 6.13 Applications -- 6.14 Computer Analysis -- 7 Series-Parallel Circuits -- 7.1 Introduction -- 7.2 Series-Parallel Networks -- 7.3 Reduce and Return Approach -- 7.4 Block Diagram Approach -- 7.5 Descriptive Examples -- 7.6 Ladder Networks -- 7.7 Voltage Divider Supply (Unloaded and Loaded) -- 7.8 Potentiometer Loading -- 7.9 Impact of Shorts and Open Circuits -- 7.10 Ammeter, Voltmeter, and Ohmmeter Design -- 7.11 Applications -- 7.12 Computer Analysis -- 8 Methods of Analysis and Selected Topics (dc) -- 8.1 Introduction -- 8.2 Current Sources -- 8.3 Branch-Current Analysis -- 8.4 Mesh Analysis (General Approach) -- 8.5 Mesh Analysis (Format Approach) -- 8.6 Nodal Analysis (General Approach) -- 8.7 Nodal Analysis (Format Approach) -- 8.8 Bridge Networks -- 8.9 Y Δ (T-π) and Δ-Y (π-T) Conversions -- 8.10 Applications -- 8.11 Computer Analysis -- 9 Network Theorems -- 9.1 Introduction -- 9.2 Superposition Theorem -- 9.3 Thévenin's Theorem -- 9.4 Norton's Theorem -- 9.5 Maximum Power Transfer Theorem -- 9.6 Millman's Theorem -- 9.7 Substitution Theorem -- 9.8 Reciprocity Theorem -- 9.9 Computer Analysis -- 10 Capacitors -- 10.1 Introduction -- 10.2 The Electric Field -- 10.3 Capacitance -- 10.4 Capacitors -- 10.5 Transients in Capacitive Networks: The Charging Phase.

10.6 Transients in Capacitive Networks: The Discharging Phase -- 10.7 Initial Conditions -- 10.8 Instantaneous Values -- 10.9 Thévenin Equivalent: T = RThC -- 10.10 The Current iC -- 10.11 Capacitors in Series and in Parallel -- 10.12 Energy Stored by a Capacitor -- 10.13 Stray Capacitances -- 10.14 Applications -- 10.15 Computer Analysis -- 11 Inductors -- 11.1 Introduction -- 11.2 Magnetic Field -- 11.3 Inductance -- 11.4 Induced Voltage vL -- 11.5 R-L Transients: The Storage Phase -- 11.6 Initial Conditions -- 11.7 R-L Transients: The Release Phase -- 11.8 Thévenin Equivalent: T = L/RTh -- 11.9 Instantaneous Values -- 11.10 Average Induced Voltage: vLav -- 11.11 Inductors in Series and in Parallel -- 11.12 Steady-State Conditions -- 11.13 Energy Stored by an Inductor -- 11.14 Applications -- 11.15 Computer Analysis -- 12 Magnetic Circuits -- 12.1 Introduction -- 12.2 Magnetic Field -- 12.3 Reluctance -- 12.4 Ohm's Law for Magnetic Circuits -- 12.5 Magnetizing Force -- 12.6 Hysteresis -- 12.7 Ampère's Circuital Law -- 12.8 Flux φ -- 12.9 Series Magnetic Circuits: Determining NI -- 12.10 Air Gaps -- 12.11 Series-Parallel Magnetic Circuits -- 12.12 Determining φ -- 12.13 Applications -- 13 Sinusoidal Alternating Waveforms -- 13.1 Introduction -- 13.2 Sinusoidal ac Voltage Characteristics and Definitions -- 13.3 Frequency Spectrum -- 13.4 The Sinusoidal Waveform -- 13.5 General Format for the Sinusoidal Voltage or Current -- 13.6 Phase Relations -- 13.7 Average Value -- 13.8 Effective (rms) Values -- 13.9 Converters and Inverters -- 13.10 ac Meters and Instruments -- 13.11 Applications --

13.12 Computer Analysis -- 14 The Basic Elements and Phasors -- 14.1 Introduction -- 14.2 Response of Basic R, L, and C Elements to a Sinusoidal Voltage or Current -- 14.3 Frequency Response of the Basic Elements -- 14.4 Average Power and Power Factor.

14.5 Complex Numbers -- 14.6 Rectangular Form -- 14.7 Polar Form -- 14.8 Conversion Between Forms -- 14.9 Mathematical Operations with Complex Numbers -- 14.10 Calculator Methods with Complex Numbers -- 14.11 Phasors -- 14.12 Computer Analysis -- 15 Series ac Circuits -- 15.1 Introduction -- 15.2 Resistive Elements -- 15.3 Inductive Elements -- 15.4 Capacitive Elements -- 15.5 Impedance Diagram -- 15.6 Series Configuration -- 15.7 Voltage Divider Rule -- 15.8 Frequency Response for Series ac Circuits -- 15.9 Summary: Series ac Circuits -- 15.10 Phase Measurements -- 15.11 Applications -- 15.12 Computer Analysis -- 16 Parallel ac Circuits -- 16.1 Introduction -- 16.2 Total Impedance -- 16.3 Total Admittance -- 16.4 Parallel ac Networks -- 16.5 Current Divider Rule -- 16.6 Frequency Response of Parallel Elements -- 16.7 Summary: Parallel ac Networks -- 16.8 Equivalent Circuits -- 16.9 Applications -- 16.10 Computer Analysis -- 17 Series-Parallel ac Networks -- 17.1 Introduction -- 17.2 Illustrative Examples -- 17.3 Ladder Networks -- 17.4 Grounding -- 17.5 Applications -- 17.6 Computer Analysis -- 18 Methods of Analysis and Selected Topics (ac) -- 18.1 Introduction -- 18.2 Independent Versus Dependent (Controlled) Sources -- 18.3 Source Conversions -- 18.4 Mesh Analysis -- 18.5 Nodal Analysis -- 18.6 Bridge Networks (ac) -- 18.7 Δ - Y, Y - Δ Conversions -- 18.8 Computer Analysis -- 19 Network Theorems (ac) -- 19.1 Introduction -- 19.2 Superposition Theorem -- 19.3 Thévenin's Theorem -- 19.4 Norton's Theorem -- 19.5 Maximum Power Transfer Theorem -- 19.6 Substitution, Reciprocity, and Millman's Theorems -- 19.7 Application -- 19.8 Computer Analysis -- 20 Power (ac) -- 20.1 Introduction -- 20.2 General Equation -- 20.3 Resistive Circuit -- 20.4 Apparent Power -- 20.5 Inductive Circuit and Reactive Power -- 20.6 Capacitive Circuit.

20.7 The Power Triangle -- 20.8 The Total P, Q, and S -- 20.9 Power-Factor Correction -- 20.10 Power Meters -- 20.11 Effective Resistance -- 20.12 Applications -- 20.13 Computer Analysis -- 21 Resonance -- 21.1 Introduction -- 21.2 Series Resonant Circuit -- 21.3 The Quality Factor (Q) -- 21.4 ZT Versus Frequency -- 21.5 Selectivity -- 21.6 VR, VL, and VC -- 21.7 Practical Considerations -- 21.8 Summary -- 21.9 Examples (Series Resonance) -- 21.10 Parallel Resonant Circuit -- 21.11 Selectivity Curve for Parallel Resonant Circuits -- 21.12 Effect of Ql Q1 ≥10 -- 21.13 Summary Table -- 21.14 Examples (Parallel Resonance) -- 21.15 Applications -- 21.16 Computer Analysis -- 22 Decibels, Filters, and Bode Plots -- 22.1 Introduction -- 22.2 Properties of Logarithms -- 22.3 Decibels -- 22.4 Filters -- 22.5 R-C Low-Pass Filter -- 22.6 R-C High-Pass Filter -- 22.7 Band-Pass Filters -- 22.8 Band-Stop Filters -- 22.9 Double-Tuned Filter -- 22.10 Other Filter Configurations -- 22.11 Bode Plots -- 22.12 Sketching the Bode Response -- 22.13 Low-Pass Filter with Limited Attenuation -- 22.14 High-Pass Filter with Limited Attenuation -- 22.15 Additional Properties of Bode Plots -- 22.16 Crossover Networks -- 22.17 Applications -- 22.18 Computer Analysis -- 23 Transformers -- 23.1 Introduction -- 23.2 Mutual Inductance -- 23.3 The Iron-Core Transformer -- 23.4 Reflected Impedance and Power -- 23.5 Impedance Matching, Isolation, and Displacement -- 23.6 Equivalent Circuit (Iron-Core Transformer) -- 23.7 Frequency Considerations -- 23.8 Series Connection of Mutually Coupled Coils -- 23.9 Air-Core Transformer -- 23.10 Nameplate Data -- 23.11 Types of Transformers -- 23.12 Tapped and Multiple-Load Transformers -- 23.13 Networks

with Magnetically Coupled Coils -- 23.14 Current Transformers -- 23.15 Applications -- 23.16 Computer Analysis -- 24 Polyphase Systems.

For courses in DC/AC circuits: conventional flow      The Latest Insights in Circuit Analysis   Introductory Circuit Analysis, the number one acclaimed text in the field for over three decades, is a clear and interesting information source on a complex topic. The Thirteenth Edition contains updated insights on the highly technical subject, providing students with the most current information in circuit analysis. With updated software components and challenging review questions at the end of each chapter, this text engages students in a profound understanding of Circuit Analysis.