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  <titleInfo>
    <title>Electric Circuits, Global Edition</title>
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  <name type="personal">
    <namePart>Nilsson, James.</namePart>
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  <name type="personal">
    <namePart>Riedel, Susan.</namePart>
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    <dateIssued encoding="marc">2019</dateIssued>
    <edition>11th ed.</edition>
    <issuance>monographic</issuance>
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  <language>
    <languageTerm authority="iso639-2b" type="code">eng</languageTerm>
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    <extent>1 online resource (819 pages)</extent>
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  <abstract>The full text downloaded to your computer   With eBooks you can:   search for key concepts, words and phrases make highlights and notes as you study share your notes with friends   eBooks are downloaded to your computer and accessible either offline through the Bookshelf (available as a free download), available online and also via the iPad and Android apps.   Upon purchase, you will receive via email the code and instructions on how to access this product.   Time limit   The&amp;#xA0;eBooks products do not have an expiry date. You will continue to access your&amp;#xA0;digital&amp;#xA0;ebook&amp;#xA0;products whilst you have your&amp;#xA0;Bookshelf installed.   For courses in Introductory Circuit Analysis or Circuit Theory.   The fundamental goals of the best-selling&amp;#xA0;Electric Circuits&amp;#xA0;remain unchanged. The&amp;#xA0;11th Edition&amp;#xA0;continues to motivate students to build new ideas based on concepts previously presented, to develop problem-solving skills that rely on a solid conceptual foundation, and to introduce realistic engineering experiences that challenge students to develop the insights of a practicing engineer. The 11th Edition represents the most extensive revision since the 5th Edition with every sentence, paragraph, subsection, and chapter examined and oftentimes rewritten to improve clarity, readability, and pedagogy-without sacrificing the breadth and depth of coverage that Electric Circuits is known for. Dr. Susan Riedel draws on her classroom experience to introduce the&amp;#xA0;Analysis Methods&amp;#xA0;feature, which gives students a step-by-step problem-solving approach.</abstract>
  <tableOfContents>Front Cover -- Title Page -- Copyright Page -- Brief Contents -- Contents -- List of Examples -- List of Tables -- List of Analysis Methods -- Preface -- Chapter 1 Circuit Variables -- Practical Perspective: Balancing Power -- 1.1 Electrical Engineering: An Overview -- 1.2 The International System of Units -- 1.3 Circuit Analysis: An Overview -- 1.4 Voltage and Current -- 1.5 The Ideal Basic Circuit Element -- 1.6 Power and Energy -- Practical Perspective: Balancing Power -- Summary -- Problems -- Chapter 2 Circuit Elements -- Practical Perspective: Heating with Electric Radiators -- 2.1 Voltage and Current Sources -- 2.2 Electrical Resistance (Ohm's Law) -- 2.3 Constructing a Circuit Model -- 2.4 Kirchhoff's Laws -- 2.5 Analyzing a Circuit Containing Dependent Sources -- Practical Perspective: Heating with Electric Radiators -- Summary -- Problems -- Chapter 3 Simple Resistive Circuits -- Practical Perspective: Resistive Touch Screens -- 3.1 Resistors in Series -- 3.2 Resistors in Parallel -- 3.3 The Voltage-Divider and Current-Divider Circuits -- 3.4 Voltage Division and Current Division -- 3.5 Measuring Voltage and Current -- 3.6 Measuring Resistance- The Wheatstone Bridge -- 3.7 Delta-to-Wye (pi-toTtee) Equivalent Circuits -- Practical Perspective: Resistive Touch Screens -- Summary -- Problems -- Chapter 4 Techniques of Circuit Analysis -- Practical Perspective: Circuits with Realistic Resistors -- 4.1 Terminology -- 4.2 Introduction to the Node-Voltage Method -- 4.3 The Node-Voltage Method and Dependent Sources -- 4.4 The Node-Voltage Method: Some Special Cases -- 4.5 Introduction to the Mesh-Current Method -- 4.6 The Mesh-Current Method and Dependent Sources -- 4.7 The Mesh-Current Method: Some Special Cases -- 4.8 The Node-Voltage Method Versus the Mesh-Current Method -- 4.9 Source Transformations -- 4.10 Th�evenin and Norton Equivalents.</tableOfContents>
  <tableOfContents>4.11 More on Deriving the Th�evenin Equivalent -- 4.12 Maximum Power Transfer -- 4.13 Superposition -- Practical Perspective: Circuits with Realistic Resistors -- Summary -- Problems -- Chapter 5 The Operational Amplifier -- Practical Perspective: Sensors -- 5.1 Operational Amplifier Terminals -- 5.2 Terminal Voltages and Currents -- 5.3 The Inverting-Amplifier Circuit -- 5.4 The Summing-Amplifier Circuit -- 5.5 The Noninverting-Amplifier Circuit -- 5.6 The Difference-Amplifier Circuit -- 5.7 A More Realistic Model for the Operational Amplifier -- Practical Perspective: Sensors -- Summary -- Problems -- Chapter 6 Inductance, Capacitance, and Mutual Inductance -- Practical Perspective: Capacitive Touch Screens -- 6.1 The Inductor -- 6.2 The Capacitor -- 6.3 Series-Parallel Combinations of Inductance and Capacitance -- 6.4 Mutual Inductance -- 6.5 A Closer Look at Mutual Inductance -- Practical Perspective: Capacitive Touch Screens -- Summary -- Problems -- Chapter 7 Response of First-Order RL and RC Circuits -- Practical Perspective: Artificial Pacemaker -- 7.1 The Natural Response of an RL Circuit -- 7.2 The Natural Response of an RC Circuit -- 7.3 The Step Response of RL and RC Circuits -- 7.4 A General Solution for Step and Natural Responses -- 7.5 Sequential Switching -- 7.6 Unbounded Response -- 7.7 The Integrating Amplifier -- Practical Perspective: Artificial Pacemaker -- Summary -- Problems -- Chapter 8 Natural and Step Responses of RLC Circuits -- Practical Perspective: Clock for Computer Timing -- 8.1 Introduction to the Natural Response of a Parallel RLC Circuit -- 8.2 The Forms of the Natural Response of a Parallel RLC Circuit -- 8.3 The Step Response of a Parallel RLC Circuit -- 8.4 The Natural and Step Response of a Series RLC Circuit -- 8.5 A Circuit with Two Integrating Amplifiers -- Practical Perspective: Clock for Computer Timing.</tableOfContents>
  <tableOfContents>Summary -- Problems -- Chapter 9 Sinusoidal Steady-State Analysis -- Practical Perspective: A Household Distribution Circuit -- 9.1 The Sinusoidal Source -- 9.2 The Sinusoidal Response -- 9.3 The Phasor -- 9.4 The Passive Circuit Elements in the Frequency Domain -- 9.5 Kirchhoff's Laws in the Frequency Domain -- 9.6 Series, Parallel, and Delta-to-Wye Simplifications -- 9.7 Source Transformations and Th�evenin-Norton Equivalent Circuits -- 9.8 The Node-Voltage Method -- 9.9 The Mesh-Current Method -- 9.10 The Transformer -- 9.11 The Ideal Transformer -- 9.12 Phasor Diagrams -- Practical Perspective: A Household Distribution Circuit -- Summary -- Problems -- Chapter 10 Sinusoidal Steady-State Power Calculations -- Practical Perspective: Vampire Power -- 10.1 Instantaneous Power -- 10.2 Average and Reactive Power -- 10.3 The rms Value and Power Calculations -- 10.4 Complex Power -- 10.5 Power Calculations -- 10.6 Maximum Power Transfer -- Practical Perspective: Vampire Power -- Summary -- Problems -- Chapter 11 Balanced Three-Phase Circuits -- Practical Perspective: Transmission and Distribution of Electric Power -- 11.1 Balanced Three-Phase Voltages -- 11.2 Three-Phase Voltage Sources -- 11.3 Analysis of the Wye-Wye Circuit -- 11.4 Analysis of the Wye-Delta Circuit -- 11.5 Power Calculations in Balanced Three-Phase Circuits -- 11.6 Measuring Average Power in Three-Phase Circuits -- Practical Perspective: Transmission and Distribution of Electric Power -- Summary -- Problems -- Chapter 12 Introduction to the Laplace Transform -- Practical Perspective: Transient Effects -- 12.1 Definition of the Laplace Transform -- 12.2 The Step Function -- 12.3 The Impulse Function -- 12.4 Functional Transforms -- 12.5 Operational Transforms -- 12.6 Applying the Laplace Transform -- 12.7 Inverse Transforms -- 12.8 Poles and Zeros of F(s).</tableOfContents>
  <tableOfContents>12.9 Initial-and Final-Value Theorems -- Practical Perspective: Transient Effects -- Summary -- Problems -- Chapter 13 The Laplace Transform in Circuit Analysis -- Practical Perspective: Surge Suppressors -- 13.1 Circuit Elements in the s Domain -- 13.2 Circuit Analysis in the s Domain -- 13.3 Applications -- 13.4 The Transfer Function -- 13.5 The Transfer Function in Partial Fraction Expansions -- 13.6 The Transfer Function and the Convolution Integral -- 13.7 The Transfer Function and the Steady-State Sinusoidal Response -- 13.8 The Impulse Function in Circuit Analysis -- Practical Perspective: Surge Suppressors -- Summary -- Problems -- Chapter 14 Introduction to Frequency Selective Circuits -- Practical Perspective: Pushbutton Telephone Circuits -- 14.1 Some Preliminaries -- 14.2 Low-Pass Filters -- 14.3 High-Pass Filters -- 14.4 Bandpass Filters -- 14.5 Bandreject Filters -- Practical Perspective: Pushbutton Telephone Circuits -- Summary -- Problems -- Chapter 15 Active Filter Circuits -- Practical Perspective:Bass Volume Control -- 15.1 First-Order Low-Pass and High-Pass Filters -- 15.2 Scaling -- 15.3 Op Amp Bandpass and Bandreject Filters -- 15.4 Higher-Order Op Amp Filters -- 15.5 Narrowband Bandpass and Bandreject Filters -- Practical Perspective: Bass Volume Control -- Summary -- Problems -- Chapter 16 Fourier Series -- Practical Perspective: Active High-Q Filters -- 16.1 Fourier Series Analysis: An Overview -- 16.2 The Fourier Coefficients -- 16.3 The Effect of Symmetry on the Fourier Coefficients -- 16.4 An Alternative Trigonometric Form of the Fourier Series -- 16.5 An Application -- 16.6 Average-Power Calculations With Periodic Functions -- 16.7 The Rms Value of a Periodic Function -- 16.8 The Exponential Form of the Fourier Series -- 16.9 Amplitude and Phase Spectra -- Practical Perspective: Active High-Q Filters -- Summary.</tableOfContents>
  <tableOfContents>Problems -- Chapter 17 The Fourier Transform -- Practical Perspective: Filtering Digital Signals -- 17.1 The Derivation of the Fourier Transform -- 17.2 The Convergence of the Fourier Integral -- 17.3 Using Laplace Transforms to Find Fourier Transforms -- 17.4 Fourier Transforms in the Limit -- 17.5 Some Mathematical Properties -- 17.6 Operational Transforms -- 17.7 Circuit Applications -- 17.8 Parseval's Theorem -- Practical Perspective: Filtering Digital Signals -- Summary -- Problems -- Chapter 18 Two-Port Circuits -- Practical Perspective: Characterizing an Unknown Circuit -- 18.1 The Terminal Equations -- 18.2 The Two-Port Parameters -- 18.3 Analysis of the Terminated Two-Port Circuit -- 18.4 Interconnected Two-Port Circuits -- Practical Perspective: Characterizing an Unknown Circuit -- Summary -- Problems -- Appendix A The Solution of Linear Simultaneous Equations -- A.1 Preliminary Steps -- A.2 Calculator and Computer Methods -- A.3 Paper-and-Pencil Methods -- A.4 Applications -- Appendix B Complex Numbers -- B.1 Notation -- B.2 The Graphical Representation of a Complex Number -- B.3 Arithmetic Operations -- B.4 Useful Identities -- B.5 The Integer Power of a Complex Number -- B.6 The Roots of a Complex Number -- Appendix C More on Magnetically Coupled Coils and Ideal Transformers -- C.1 Equivalent Circuits for Magnetically Coupled Coils -- C.2 The Need for Ideal Transformers in Tthe Equivalent Circuits -- Appendix D The Decibel -- Appendix E Bode Diagrams -- E.1 Real, First-Order Poles and Zeros -- E.2 Straight-Line Amplitude Plots -- E.3 More Accurate Amplitude Plots -- E.4 Straight-Line Phase Angle Plots -- E.5 Bode Diagrams: Complex Poles and Zeros -- E.6 Straight-Line Amplitude Plots for Complex Poles -- E.7 Correcting Straight-Line Amplitude Plots for Complex Poles -- E.8 Phase Angle Plots for Complex Poles.</tableOfContents>
  <tableOfContents>Appendix F An Abbreviated Table of Trigonometric Identities.</tableOfContents>
  <subject authority="lcsh">
    <topic>Electric circuits-Alternating current</topic>
  </subject>
  <classification authority="lcc">TK454.15.A48 .N557 2020</classification>
  <classification authority="ddc">621.3192</classification>
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