Efnisyfirlit

• Title Page
• Copyright Page
• Table of Contents
• Introduction
  • About This Book
  • Conventions Used in This Book
  • What You’re Not to Read
  • Foolish Assumptions
  • How This Book Is Organized
    • Part I: Getting Started with Circuit Analysis
    • Part II: Applying Analytical Methods for Complex Circuits
    • Part III: Understanding Circuits with Transistors and Operational Amplifiers
    • Part IV: Applying Time-Varying Signals to First- and Second-Order Circuits
    • Part V: Advanced Techniques and Applications in Circuit Analysis
    • Part VI: The Part of Tens
  • Icons Used in This Book
  • Where to Go from Here
• Part I: Getting Started with Circuit Analysis
  • Chapter 1: Introducing Circuit Analysis
    • Getting Started with Current and Voltage
      • Going with the flow with current
      • Recognizing potential differences with voltage
      • Staying grounded with zero voltage
      • Getting some direction with the passive sign convention
    • Beginning with the Basic Laws
    • Surveying the Analytical Methods for More-Complex Circuits
    • Introducing Transistors and Operational Amplifi ers
    • Dealing with Time-Varying Signals, Capacitors, and Inductors
    • Avoiding Calculus with Advanced Techniques
  • Chapter 2: Clarifying Basic Circuit Concepts and Diagrams
    • Looking at Current-Voltage Relationships
      • Absorbing energy with resistors
        • Applying Ohm’s law to resistors
        • Calculating the power dissipated by resistors
      • Offering no resistance: Batteries and short circuits
        • Batteries: Providing power independently
        • Short circuits: No voltage, no power
      • Facing infinite resistance: Ideal current sources and open circuits
      • All or nothing: Combining open and short circuits with ideal switches
    • Mapping It All Out with Schematics
      • Going in circles with loops
      • Getting straight to the point with nodes
  • Chapter 3: Exploring Simple Circuits with Kirchhoff’s Laws
    • Presenting Kirchhoff’s Famous Circuit Laws
      • Kirchhoff’s voltage law (KVL): Conservation of energy
        • Identifying voltage rises and drops
        • Forming a KVL equation
      • Kirchhoff’s current law (KCL): Conservation of charge
        • Tracking incoming and outgoing current
        • Calculating KCL
    • Tackling Circuits with KVL, KCL, and Ohm’s Law
      • Getting batteries and resistors to work together
        • Starting with voltage
        • Bringing in current
        • Combining device equations with KVL
        • Summarizing the results
      • Sharing the same current in series circuits
      • Climbing the ladder with parallel circuits
        • Describing total resistance using conductance
        • Using a shortcut for two resistors in parallel
        • Finding equivalent resistor combinations
    • Combining series and parallel resistors
  • Chapter 4: Simplifying Circuit Analysis with Source Transformation and Division Techniques
    • Equivalent Circuits: Preparing for the Transformation
    • Transforming Sources in Circuits
      • Converting to a parallel circuit with a current source
      • Changing to a series circuit with a voltage source
    • Divvying It Up with the Voltage Divider
      • Getting a voltage divider equation for a series circuit
      • Figuring out voltages for a series circuit with two or more resistors
      • Finding voltages when you have multiple current sources
      • Using the voltage divider technique repeatedly
    • Cutting to the Chase Using the Current Divider Technique
      • Getting a current divider equation for a parallel circuit
      • Figuring out currents for parallel circuits
      • Finding currents when you have multiple voltage sources
      • Using the current divider technique repeatedly
• Part II: Applying Analytical Methods for Complex Circuits
  • Chapter 5: Giving the Nod to Node-Voltage Analysis
    • Getting Acquainted with Node Voltages and Reference Nodes
    • Testing the Waters with Node Voltage Analysis
      • What goes in must come out: Starting with KCL at the nodes
      • Describing device currents in terms of node voltages with Ohm’s law
      • Putting a system of node voltage equations in matrix form
      • Solving for unknown node voltages
    • Applying the NVA Technique
      • Solving for unknown node voltageswith a current source
      • Dealing with three or more node equations
    • Working with Voltage Sources in Node-Voltage Analysis
  • Chapter 6: Getting in the Loop on Mesh Current Equations
    • Windowpanes: Looking at Meshes and Mesh Currents
    • Relating Device Currents to Mesh Currents
    • Generating the Mesh Current Equations
      • Finding the KVL equations first
      • Ohm’s law: Putting device voltages in terms of mesh currents
      • Substituting the device voltages into the KVL equations
      • Putting mesh current equations into matrix form
      • Solving for unknown currents and voltages
    • Crunching Numbers: Using Meshes to Analyze Circuits
      • Tackling two-mesh circuits
      • Analyzing circuits with three or more meshes
  • Chapter 7: Solving One Problem at a Time Using Superposition
    • Discovering How Superposition Works
      • Making sense of proportionality
      • Applying superposition in circuits
      • Adding the contributions of each independent source
    • Getting Rid of the Sources of Frustration
      • Short circuit: Removing a voltage source
      • Open circuit: Taking out a current source
    • Analyzing Circuits with Two Independent Sources
      • Knowing what to do when the sources are two voltage sources
      • Proceeding when the sources are two current sources
      • Dealing with one voltage source and one current source
      • Solving a Circuit with Three Independent Sources
  • Chapter 8: Applying Thévenin’s and Norton’s Theorems
    • Showing What You Can Do with Thévenin’s and Norton’s Theorems
    • Finding the Norton and Thévenin Equivalents for Complex Source Circuits
      • Applying Thévenin’s theorem
        • Finding the Thévenin equivalent of a circuit with a single independent voltage source
      • Applying Norton’s theorem
      • Using source transformation to find Thévenin or Norton
        • A shortcut: Finding Thévenin or Norton equivalents with source transformation
        • Finding the Thévenin equivalent of a circuit with multiple independent sources
      • Finding Thévenin or Norton with superposition
    • Gauging Maximum Power Transfer: A Practical Application of Both Theorems
• Part III: Understanding Circuits with Transistors and Operational Amplifiers
  • Chapter 9: Dependent Sources and the Transistors That Involve Them
    • Understanding Linear Dependent Sources: Who Controls What
      • Classifying the types of dependent sources
      • Recognizing the relationship between dependent and independent sources
    • Analyzing Circuits with Dependent Sources
      • Applying node-voltage analysis
      • Using source transformation
      • Using the Thévenin technique
    • Describing a JFET Transistor with a Dependent Source
    • Examining the Three Personalities of Bipolar Transistors
      • Making signals louder with the common emitter circuit
      • Amplifying signals with a common base circuit
      • Isolating circuits with the common collector circuit
  • Chapter 10: Letting Operational Amplifiers Do the Tough Math Fast
    • The Ins and Outs of Op-Amp Circuits
      • Discovering how to draw op amps
      • Looking at the ideal op amp and its transfer characteristics
      • Modeling an op amp with a dependent source
      • Examining the essential equations for analyzing ideal op-amp circuits
    • Looking at Op-Amp Circuits
      • Analyzing a noninverting op amp
      • Following the leader with the voltage follower
      • Turning things around with the inverting amplifier
      • Adding it all up with the summer
      • What’s the difference? Using the op-amp subtractor
    • Increasing the Complexity of What You Can Do with Op Amps
      • Analyzing the instrumentation amplifi er
      • Implementing mathematical equations electronically
      • Creating systems with op amps
• Part IV: Applying Time-Varying Signals to First- and Second-Order Circuits
  • Chapter 11: Making Waves with Funky Functions
    • Spiking It Up with the Lean, Mean Impulse Function
      • Changing the strength of the impulse
      • Delaying an impulse
      • Evaluating impulse functions with integrals
    • Stepping It Up with a Step Function
      • Creating a time-shifted, weighted step function
      • Being out of step with shifted step functions
      • Building a ramp function with a step function
    • Pushing the Limits with the Exponential Function
    • Seeing the Signs with Sinusoidal Functions
      • Giving wavy functions a phase shift
      • Expanding the function and finding Fourier coefficients
      • Connecting sinusoidal functions to exponentials with Euler’s formula
  • Chapter 12: Spicing Up Circuit Analysis with Capacitors and Inductors
    • Storing Electrical Energy with Capacitors
      • Describing a capacitor
      • Charging a capacitor (credit cards not accepted)
      • Relating the current and voltage of a capacitor
      • Finding the power and energy of a capacitor
      • Calculating the total capacitance for parallel and series capacitors
      • Finding the equivalent capacitance of parallel capacitors
      • Finding the equivalent capacitance of capacitors in series
    • Storing Magnetic Energy with Inductors
      • Describing an inductor
      • Finding the energy storage of an attractive inductor
      • Calculating total inductance for series and parallel inductors
        • Finding the equivalent inductance for inductors in series
        • Finding the equivalent inductance for inductors in parallel
    • Calculus: Putting a Cap on Op-Amp Circuits
      • Creating an op-amp integrator
      • Deriving an op-amp differentiator
    • Using Op Amps to Solve Differential Equations Really Fast
  • Chapter 13: Tackling First-Order Circuits
    • Solving First-Order Circuits with Diff EQ
      • Guessing at the solution with the natural exponential function
      • Using the characteristic equation for a fi rst-order equation
    • Analyzing a Series Circuit with a Single Resistor and Capacitor
      • Starting with the simple RC series circuit
      • Finding the zero-input response
      • Finding the zero-state response by focusing on the input source
      • Adding the zero-input and zero-state responses to find the total response
    • Analyzing a Parallel Circuit with a Single Resistor and Inductor
      • Starting with the simple RL parallel circuit
      • Calculating the zero-input response for an RL parallel circuit
      • Calculating the zero-state response for an RL parallel circuit
      • Adding the zero-input and zero-state responses to find the total response
  • Chapter 14: Analyzing Second-Order Circuits
    • Examining Second-Order Differential Equations with Constant Coefficients
      • Guessing at the elementary solutions: The natural exponential function
      • From calculus to algebra: Using the characteristic equation
    • Analyzing an RLC Series Circuit
      • Setting up a typical RLC series circuit
      • Determining the zero-input response
      • Calculating the zero-state response
      • Finishing up with the total response
    • Analyzing an RLC Parallel Circuit Using Duality
      • Setting up a typical RLC parallel circuit
      • Finding the zero-input response
      • Arriving at the zero-state response
      • Getting the total response
• Part V: Advanced Techniques and Applications in Circuit Analysis
  • Chapter 15: Phasing in Phasors for Wave Functions
    • Taking a More Imaginative Turn with Phasors
      • Finding phasor forms
      • Examining the properties of phasors
    • Using Impedance to Expand Ohm’s Law to Capacitors and Inductors
      • Understanding impedance
      • Looking at phasor diagrams
      • Putting Ohm’s law for capacitors in phasor form
      • Putting Ohm’s law for inductors in phasor form
    • Tackling Circuits with Phasors
      • Using divider techniques in phasor form
      • Adding phasor outputs with superposition
      • Simplifying phasor analysis with Thévenin and Norton
      • Getting the nod for nodal analysis
      • Using mesh-current analysis with phasors
  • Chapter 16: Predicting Circuit Behavior with Laplace Transform Techniques
    • Getting Acquainted with the Laplace Transform and Key Transform Pairs
    • Getting Your Time Back with the Inverse Laplace Transform
      • Rewriting the transform with partial fraction expansion
      • Expanding Laplace transforms with complex poles
      • Dealing with transforms with multiple poles
    • Understanding Poles and Zeros of F(s)
    • Predicting the Circuit Response with Laplace Methods
      • Working out a first-order RC circuit
      • Working out a first-order RL circuit
      • Working out an RLC circuit
  • Chapter 17: Implementing Laplace Techniques for Circuit Analysis
    • Starting Easy with Basic Constraints
      • Connection constraints in the s-domain
      • Device constraints in the s-domain
        • Independent and dependent sources
        • Passive elements: Resistors, capacitors, and inductors
        • Op-amp devices
      • Impedance and admittance
    • Seeing How Basic Circuit Analysis Works in the s-Domain
      • Applying voltage division with series circuits
      • Turning to current division for parallel circuits
      • Conducting Complex Circuit Analysis in the s-Domain
        • Using node-voltage analysis
        • Using mesh-current analysis
        • Using superposition and proportionality
        • Using the Thévenin and Norton equivalents
  • Chapter 18: Focusing on the Frequency Responses
    • Describing the Frequency Response and Classy Filters
      • Low-pass filter
      • High-pass filter
      • Band-pass filters
      • Band-reject filters
    • Plotting Something: Showing Frequency Response à la Bode
      • Looking at a basic Bode plot
      • Poles, zeros, and scale factors: Picturing Bode plots from transfer functions
    • Turning the Corner: Making Low-Pass and High-Pass Filters with RC Circuits
      • First-order RC low-pass filter (LPF)
      • First-order RC high-pass filter (HPF)
    • Creating Band-Pass and Band-Reject Filters with RLC or RC Circuits
      • Getting serious with RLC series circuits
        • RLC series band-pass fi lter (BPF)
        • RLC series band-reject fi lter (BRF)
      • Climbing the ladder with RLC parallel circuits
      • RC only: Getting a pass with a band-pass and band-reject filter
• Part VI: The Part of Tens
  • Chapter 19: Ten Practical Applications for Circuits
    • Potentiometers
    • Homemade Capacitors: Leyden Jars
    • Digital-to-Analog Conversion Using Op Amps
    • Two-Speaker Systems
    • Interface Techniques Using Resistors
    • Interface Techniques Using Op Amps
    • The Wheatstone Bridge
    • Accelerometers
    • Electronic Stud Finders
    • 555 Timer Circuits
  • Chapter 20: Ten Technologies Affecting Circuits
    • Smartphone Touchscreens
    • Nanotechnology
    • Carbon Nanotubes
    • Microelectromechanical Systems
    • Supercapacitors
    • The Memristor
    • Superconducting Digital Electronics
    • Wide Bandgap Semiconductors
    • Flexible Electronics
    • Microelectronic Chips that Pair Up with Biological Cells
• Index
• EULA

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