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Foundations of analog and digital electronic circuits:

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Bibliographische Detailangaben
1. Verfasser:	Agarwal, Anant (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Amsterdam [u.a.] Elsevier 2005
Schlagworte:	Circuitos eletrônicos Circuits électroniques Electronic circuits > Textbooks Elektronische Schaltung Digitalschaltung Digitaltechnik Operationsverstärker MOS-FET Analogschaltung Lehrbuch
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	Includes bibliographical references and index
Beschreibung:	XXIV, 984 S. Ill., graph. Darst.
ISBN:	1558607358 9781558607354

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Datensatz im Suchindex

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adam_text	Titel: Foundations of analog and digital electronic circuits Autor: Agarwal, Anant Jahr: 2005 CONTENTS Material marked with IVH l . l appears on the Internet (please see Preface for detail s). Preface ......................................................................................... xvü Approach ............................................................................ xvü Overview ............................................................................ xrx Course Organization............................................................. xx Adcnowledgments................................................................ xxi CHAPTtR i The Circuit Abstraction ......................................... 3 1.1 The Power of Abstraction...................................................... 3 1.2 The Lumped Circuit Abstraction............................................. 5 1.3 The Lumped Matter Disdpline............................................... 9 1.4 Limitations of the Lumped Circuit Abstraction.......................... 13 1.5 Practical Two-Terminal Elements............................................ 15 1.5.1 Batteries................................................................ 16 1.5.2 Linear Resistors ...................................................... 18 1.5.3 Associated Variables Convention ............................... 25 1.6 Ideal Two-Terminal Elements ................................................ 29 1.6.1 Ideal Voltage Sources, Wires, and Resistors.................. 30 1.6.2 ElementLaws ........................................................ 32 1.6.3 The Current Source ? Another Ideal Two- Terminal Element................................................................ 33 1.7 Modeling Physical Elements................................................... 36 1.8 Signal Representation............................................................ 40 1.8.1 Analog Signals ....................................................... 41 1.8.2 Digital Signals?Value Discretization........................ 43 1.9 Summary and Exercises......................................................... 46 chapter z ResistiveNetworks ............................................... 53 2.1 Terminobgy........................................................................ 54 2.2 Kirchhofs Laws................................................................... 55 2.2.1 KCL ................................................................... 56 2.2.2 KVL ..................................................................... 60 2.3 Circuit Analysis: Basic Method ............................................... 66 2.3.1 Single-Resistor Circuits ............................................ 67 232 Quick Intuitive Analysis of Single-Resistor Circuits........ 70 2.3.3 Energy Conservation............................................... 71 2.3.4 Voltage and Current Dividers ................................... 73 2.3.5 A More Complex Circuit ......................................... 84 2.4 Intuitive Method of Circuit Analysis: Series and Parallel Sirnplification............................................................. 89 2.5 More Circuit Examples.......................................................... 95 2.6 Dependent Sources and the Control Concept............................ 98 2.6.1 Circuits with Dependent Sources ............................... 102 EZZQ 2.7 A Formulation Suitable for a Computer Solution ....................... 107 2.8 Summary and Exercises......................................................... 108 chapter 3 Network Theorems .............................................. 119 3.1 Introduction ........................................................................ 119 3.2 The Node Voltage................................................................ 119 3.3 The Node Method................................................................ 125 3.3.1 Node Method: A Second Example ............................. 130 3.3.2 Floating Independent Voltage Sources......................... 135 3.3.3 Dependent Sources and the Node Method ................... 139 maHiÄ 3.3.4 The Conductance and Source Matrices ........................ 145 ESM 3.4 Loop Method...................................................................... 145 3.5 Superposition....................................................................... 145 3.5.1 Superposition Rules for Dependent Sources.................. 153 3.6 Thevenin s Theorem and Norton s Theorem............................ 157 3.6.1 The Thevenin Equivalent Network............................ 157 3.6.2 The Norton Equivalent Network ............................... 167 3.6.3 More Examples ...................................................... 171 3.7 Summary and Exercises......................................................... 177 chapter 4 Analysis of Nonlinear Circuits ................................ 193 4.1 Introduction to Nonlinear Elements ........................................ 193 4.2 Analytical Solutions.............................................................. 197 4.3 Graphical Analysis................................................................ 203 4.4 Piecewise Linear Analysis....................................................... 206 CEO 4.4.1 Improved Piecewise Linear Models for Nonlinear Elements............................................................... 214 4.5 Incremental Analysis............................................................. 214 4.6 Summary and Exercises......................................................... 229 chapter 5 The Digital Abstraction .......................................... 243 5.1 Voltage Levels and the Stade Discipline.................................... 245 5.2 Boolean Logic...................................................................... 256 5.3 Combinational Gates ............................................................ 258 5.4 Standard Sum-of-Products Representation................................ 261 5.5 Simplifying Logic Expressions................................................ 262 5.6 Number Representation......................................................... 267 5.7 Summary and Exercises......................................................... 274 chapter 6 The MOSFET Switch ........................................... 285 6.1 The Switch.......................................................................... 285 6.2 Logic Functions Using Switches.............................................. 288 6.3 The MOSFET Device and Its S Model..................................... 288 6.4 MOSFET Switch Implementation of Logic Gates ...................... 291 6.5 Static Analysis Using the S Model ........................................... 296 6.6 The SR Model of the MOSFET.............................................. 300 6.7 Physical Structure of the MOSFET.......................................... 301 6.8 Static Analysis Using the SR Model......................................... 306 6.8.1 Static Analysis ofthe NAND Gate Using the SRModel .............................................................. 311 6.9 Signal Restoration, Gain, and Nonlinearity ............................... 314 6.9.1 Signal Restoration and Gain ..................................... 314 6.9.2 Signal Restoration and Nonlinearity ........................... 317 6.9.3 Buffer Transfer Characteristics and the Static Disäpline .............................................................. 318 6.9.4 Inverter Transfer Characteristics and the Static Disäpline .............................................................. 319 6.10 Power Consumption in Logic Gates........................................ 320 6.11 Active Pullups ...................................................................... 321 6.12 Summary and Exercises......................................................... 322 chapter 7 The MOSFET Amplifier........................................ 331 7.1 Signal Amplification.............................................................. 331 7.2 Review of Dependent Sources ................................................ 332 7.3 Actual MOSFET Characteristics.............................................. 335 7.4 The Switch-Current Source (SCS) MOSFET Model ................... 340 7.5 The MOSFET Amplifier........................................................ 344 7.5.1 Biasing the MOSFET Amplifier................................. 349 7.5.2 The Amplifier Abstraction and the Saturation Disäpline .............................................................. 352 7.6 Large-Signal Analysis of the MOSFET Amplifier ....................... 353 7.6.1 vftt Versus vcxjt in the Saturation Region ................... 353 7.6.2 Valid Input and Output Voltage Ranges ..................... 356 7.6.3 Alternative Metlxxl for Valid Input and Output Voltage Ranges....................................................... 363 7.7 Operating Point Selection ...................................................... 365 7.8 Switch Unified (SU) MOSFET Model...................................... 386 7.9 Summary and Exercises......................................................... 389 chapter 8 The Small-Signal Model......................................... 405 8.1 Overview of the Nonlinear MOSFET Amplifier......................... 405 8.2 The Small-Signal Model......................................................... 405 8.2.1 Small-Signal Circuit Representation ........................... 413 8.2.2 Small-Signal Circuit for the MOSFET Amplifier ........... 418 8.2.3 Selecting an Operating Point..................................... 420 8.2.4 Input and Output Resistance, Current and Power Gain ........................................................... 423 8.3 Summary and Exercises......................................................... 447 chapter 9 Energy Storage Elements ....................................... 457 9.1 Constitutive Laws................................................................. 461 9.1.1 Capacitors ............................................................. 461 9.1.2 Inductors............................................................... 466 9.2 Series and Parallel Connections ............................................... 470 9.2.1 Capacitors ............................................................. 471 9.2.2 Inductors............................................................... 472 9.3 Special Examples.................................................................. 473 9.3.1 MOSFET Gate Capacitance ..................................... 473 9.3.2 Wiring Loop Inductance .......................................... 476 9.3.3 IC Wiring Capacitance and Inductance ....................... 477 9.3.4 Transformers ......................................................... 478 9.4 Simple Circuit Examples........................................................ 480 ESM 9.4.1 Sinusoidal Inputs .................................................... 482 9.4.2 Steplnputs ............................................................ 482 9.4.3 Impulse Inputs ....................................................... 488 EXS3 9.4.4 RoleReversal ......................................................... 489 9.5 Energy, Charge, and Flux Conservation ................................... 489 9.6 Summary and Exercises......................................................... 492 chapter io First-Order Transients in Linear Electrical Networks ..................................................................................... 503 10.1 Analysis ofRC Circuits.......................................................... 504 10.1.1 Parallel RC Circuit, Step Input .................................. 504 10.1.2 RC Discharge Transient ........................................... 509 10.1.3 Series RC Circuit, Step Input..................................... 511 10.1.4 Series RC Circuit, Square-Wave Input........................ 515 10.2 Analysis of RL Circuits.......................................................... 517 10.2.1 Series RL Circuit, Step Input ..................................... 517 10.3 Intuitive Analysis.................................................................. 520 10.4 Propagation Delay and the Digital Abstraction .......................... 525 10.4.1 Definitionsof Propagation Delays .............................. 527 10.4.2 Computing fa fromthe SRC MOSFET Model ......... 529 10.5 State and State Variables........................................................ 538 10.5.1 The Concept of State............................................... 538 10.5.2 Computer Analysis Using the State Equation ............... 540 10.5.3 Zero-Input and Zero-State Response.......................... 541 VMM 10.5.4 Solution by Integrating Factors .................................. 544 10.6 Additional Examples............................................................. 545 10.6.1 Effect ofWire Inductance in Digital Circuits ................. 545 10.6.2 Ramp Inputs and Linearity ....................................... 545 10.6.3 Response ofan RC Circuit to Short Pulses and the Impulse Response ................................................... 550 10.6.4 Intuitive Method for the Impulse Response................... 553 10.6.5 Clock Signals and Clock Fanout ................................ 554 UX!0 10.6.6 RC Response to Decaying Exponential ....................... 558 10.6.7 Series RL Circuit with Sine-Wave Input ...................... 558 10.7 Digital Memory.................................................................... 561 10.7.1 The Concept of Digital State ..................................... 561 10.7.2 An Ahstract Digital Memory Element ......................... 562 10.7.3 Design of the Digital Memory Element ....................... 563 10.7.4 A Static Memory Element ........................................ 567 10.8 Summary and Exercises......................................................... 568 chapter ii Energy and Power in Digital Circuits ..................... 595 11.1 Power and Energy Relations for a Simple RC Circuit.................. 595 11.2 Average Power in an RC Circuit ............................................. 597 11.2.1 Energy Dissipated During Interval T ......................... 599 11.2.2 Energy Dissipated During Interval Ti ......................... 601 11.2.3 Total Energy Dissipated........................................... 603 11.3 Power Dissipation in Logic Gates............................................ 604 11.3.1 Static Power Dissipation .......................................... 604 11.3.2 Total Power Dissipation .......................................... 605 11.4 NMOS Logic....................................................................... 611 11.5 CMOS Logic....................................................................... 611 11.5.1 CMOS Logic Gate Design ........................................ 616 11.6 Summary and Exercises......................................................... 618 chapter ii Transients in Second-Order Circuits ...................... 625 12.1 Undriven LC Circuit.............................................................. 627 12.2 Undriven, Series RLC Circuit.................................................. 640 12.2.1 Under-Damped Dynamics........................................ 644 12.2.2 Over-Damped Dynamics ......................................... 648 12.2.3 Criticaüy-Damped Dynamics.................................... 649 12.3 Stored Energy in Transient, Series RLC Circuit.......................... 651 12.4 Undriven, Parallel RLC Circuit................................................ 654 ECO 12.4.1 Under-Damped Dynamics ........................................ 654 ECO 12.4.2 Over-Damped Dynamics ......................................... 654 ECO 12.4.3 Critically-Damped Dynamics .................................... 654 12.5 Driven, Series RLC Circuit ..................................................... 654 12.5.1 StepResponse ........................................................ 657 12.5.2 Impulse Response ................................................... 661 12.6 Driven, Parallel RLC Circuit.................................................... 678 ECO 12.6.1 StepResponse ........................................................ 678 ECO 12.6.2 Impulse Response ................................................... 678 12.7 Intuitive Analysis of Second-Order Circuits............................... 678 12.8 Two-Capacitor or Two-Inductor Circuits................................. 684 12.9 State-Variable Method........................................................... 689 12.10 State-Space Analysis.............................................................. 691 ECO 12.10.1 Numerical Solution ................................................. 691 12.11 Higher-Order Circuits ........................................................... 691 12.12 Summary and Exercises......................................................... 692 chapter 13 Sinusoidal Steady State: Impedance and Frequency Response ...................................................................... 703 13.1 Introduction ........................................................................ 703 13.2 Analysis Using Complex Exponential Drive.............................. 706 13.2.1 Homogeneous Solution ........................................... 706 13.2.2 Particular Solution .................................................. 707 13.2.3 Complete Solution .................................................. 710 13.2.4 Sinusoidal Steady-State Response .............................. 710 13.3 The Boxes: Impedance.......................................................... 712 13.3.1 Example: Series RL Circuit....................................... 718 13.3.2 Example: Another RC Circuit ................................... 722 13.3.3 Example: RC Circuit with Two Capacitors ................ 724 13.3.4 Example: Analysis ofSmall Signal Amplifier with Capaätive Load ..................................................... 729 13.4 Frequency Response: Magnitude and Phase versus Frequency...... 731 13.4.1 Frequency Response of Capaätors, Inductors, and Resistors ......................................................... 732 13.4.2 Intuitively Sketching the Frequency Response ofRC and RL Circuits............................................................ 737 ECO 13.4.3 The Bode Plot: Sketching the Frequency Response of General Functions................................................... 741 13.5 Filters ................................................................................. 742 13.5.1 Filter Design Example: Crossover Network.................. 744 13.5.2 Decoupling Amplifier Stages ..................................... 746 13.6 Time Domain versus Frequency Domain Analysis using Voltage-Divider Example....................................................... 751 13.6.1 Frequency Domain Analysis ..................................... 751 13.6.2 Time Domain Analysis ............................................ 754 13.6.3 Comparing Time Domain and Frequency Domain Analyses................................................................ 756 13.7 Power and Energy in an Impedance......................................... 757 13.7.1 Arbitrary Impedance ............................................... 758 13.7.2 Pure Resistance ....................................................... 760 13.7.3 Pure Reactance ....................................................... 761 13.7.4 Example: Power in an RC Circuit.............................. 763 13.8 Summary and Exercises......................................................... 765 chapter 14 Sinusoidal Steady State: Resonance ....................... 777 14.1 Parallel RLC, Sinusoidal Response........................................... 777 14.1.1 Homogeneous Solution ........................................... 778 14.1.2 Particular Solution .................................................. 780 14.1.3 Total Solution for the Parallel RLC Circuit.................. 781 14.2 Frequency Response for Resonant Systems............................... 783 14.2.1 The Resonant Region of the Frequency Response .......... 792 _____ 14.3 Series RLC........................................................................... 801 ECO 14.4 The Bode Hot for Resonant Functions..................................... 808 14.5 Filter Examples..................................................................... 808 14.5.1 Band-pass Filter...................................................... 809 14.5.2 Low-pass Filter ...................................................... 810 14.53 High-pass Filter ...................................................... 814 14.5.4 NotchFilter ........................................................... 815 14.6 Stored Energy in a Resonant Circuit........................................ 816 14.7 Summary and Exercises......................................................... 821 chapter 15 The Operational Amplifier Abstraction .................. 837 15.1 Introduction ........................................................................ 837 15.1.1 Historical Perspective ............................................... 838 15.2 Device Properties of the Operational Amplifier.......................... 839 15.2.1 The Op Amp Model ............................................... 839 15.3 Simple Op Amp Circuits........................................................ 842 15.3.1 The Non-lnverting Op Amp..................................... 842 15.3.2 ASecondExample: TheInvertingConnection ............. 844 15.33 Sensäivity.............................................................. 846 15.3.4 A Special Case: The Voltage Foüower......................... 847 153S An Additional Constraint: v+ - v~ ^ 0..................... 848 15.4 Input and Output Resistances................................................. 849 15.4.1 Output Resistance, InvertmgOpAmp ........................ 849 15.4.2 Input Resistance, Inverting Connection ....................... 851 15.4.3 Input and Output R For Non-Inverting Op Amp ......... 853 ECO 15.4.4 Generalization on Input Resistance............................. 855 15.4.5 Example: Op Amp Current Source ............................ 855 15.5 Additional Examples ............................................................. 857 15.5.1 Adder................................................................... 858 15.5.2 Subtracter.............................................................. 858 15.6 Op Amp RC Circuits ............................................................ 859 15.6.1 Op Amp Integrator................................................. 859 15.6.2 Op Amp Differentiator ............................................ 862 15.6.3 An RC Active Filter................................................. 863 15.6.4 The RC Active Filter?Impedance Analysis ................. 865 ECO 15.6.5 Sallen-Key Filter ..................................................... 866 15.7 Op Amp in Saturation........................................................... 866 15.7.1 Op Amp Integrator in Saturation ............................... 867 15.8 Positive Feedback.................................................................. 869 15.8.1 RCOscillator......................................................... 869 15.9 Two-Ports........................................................................... 872 15.10 Summary and Exercises......................................................... 873 chapter i 6 Diodes .............................................................. 905 16.1 Introduction ........................................................................ 905 16.2 Semiconductor Diode Characteristics....................................... 905 16.3 Analysis of Diode Circuits...................................................... 908 16.3.1 Method of Assumed States........................................ 908 16.4 Nonlinear Analysis with RL and RC........................................ 912 16.4.1 PeakDetector......................................................... 912 16.4.2 Example: Clamping Circuit ...................................... 915 ECO 16.4.3 ASwitched Power Supply using a Diode ..................... 918 ECO 16.5 Additional Examples............................................................. 918 ECO 16.5.1 Piecewise Linear Example: Clipping Circuit................. 918 ECO 16.5.2 Exponentiation Circuit ............................................ 918 ECO 16.5.3 Piecewise Linear Example: Limiter............................. 918 OSO 16.5.4 Example: Full-Wave Diode Bridge............................. 918 ECO 16.5.5 Incremental Example: Zener-Diode Regulator.............. 918 ECO 16.5.6 Incremental Example: Diode Attenuator ..................... 918 16.6 Summary and Exercises......................................................... 919 appendix a Maxwell s Equations and the Lumped Matter Discipline ..................................................................................... 927 A.1 The Lumped Matter Discipline............................................... 927 A.1.1 The First Constraintof the Lumped Matter Disäpline .... 927 A.1.2 The Second Constraint ofthe Lumped Matter Disäpline .............................................................. 930 A. 1.3 The Third Constraint of the Lumped Matter Disäpline .............................................................. 932 A.1.4 The Lumped Matter Discipline Applied to Circuits........ 933 A.2 Deriving Kirchhoffs Laws...................................................... 934 A3 Deriving the Resistance ofaPieceof Material............................ 936 appendix b Trigonometrie Functions and Identities .................. 941 B.l Negative Arguments............................................................. 941 B.2 Phase-Shifted Arguments ....................................................... 942 B.3 Sum and Difference Arguments .............................................. 942 B.4 Products.............................................................................. 943 B.5 Half-Angle and Twice-Angle Arguments.................................. 943 B.6 Squares............................................................................... 943 B.7 Miscellaneous ...................................................................... 943 B.8 Taylor Series Expansions ....................................................... 944 B.9 Relations to e e .................................................................... 944 appendix c ComplexNumbers ............................................. 947 C.l Magnitude and Phase............................................................ 947 C.2 Polar Representation............................................................. 948 C.3 Addition and Subtraction....................................................... 949 C.4 Multiplication and Division.................................................... 949 C.5 Complex Conjugate.............................................................. 950 C.6 Propertiesofe 0 ................................................................... 951 C.7 Rotation.............................................................................. 951 C.8 Complex Functions of Time................................................... 952 C.9 Numerical Examples............................................................. 952 appendix d Solving Simultaneous Linear Equations ................. 957 Answers to Selected Problems ......................................................... 959 Figure Credits ............................................................................... 971 Index ........................................................................................... 973
adam_txt	Titel: Foundations of analog and digital electronic circuits Autor: Agarwal, Anant Jahr: 2005 CONTENTS Material marked with IVH'l'.'l appears on the Internet (please see Preface for detail s). Preface . xvü Approach . xvü Overview . xrx Course Organization. xx Adcnowledgments. xxi CHAPTtR i The Circuit Abstraction . 3 1.1 The Power of Abstraction. 3 1.2 The Lumped Circuit Abstraction. 5 1.3 The Lumped Matter Disdpline. 9 1.4 Limitations of the Lumped Circuit Abstraction. 13 1.5 Practical Two-Terminal Elements. 15 1.5.1 Batteries. 16 1.5.2 Linear Resistors . 18 1.5.3 Associated Variables Convention . 25 1.6 Ideal Two-Terminal Elements . 29 1.6.1 Ideal Voltage Sources, Wires, and Resistors. 30 1.6.2 ElementLaws . 32 1.6.3 The Current Source ? Another Ideal Two- Terminal Element. 33 1.7 Modeling Physical Elements. 36 1.8 Signal Representation. 40 1.8.1 Analog Signals . 41 1.8.2 Digital Signals?Value Discretization. 43 1.9 Summary and Exercises. 46 chapter z ResistiveNetworks . 53 2.1 Terminobgy. 54 2.2 Kirchhofs Laws. 55 2.2.1 KCL . 56 2.2.2 KVL . 60 2.3 Circuit Analysis: Basic Method . 66 2.3.1 Single-Resistor Circuits . 67 232 Quick Intuitive Analysis of Single-Resistor Circuits. 70 2.3.3 Energy Conservation. 71 2.3.4 Voltage and Current Dividers . 73 2.3.5 A More Complex Circuit . 84 2.4 Intuitive Method of Circuit Analysis: Series and Parallel Sirnplification. 89 2.5 More Circuit Examples. 95 2.6 Dependent Sources and the Control Concept. 98 2.6.1 Circuits with Dependent Sources . 102 EZZQ 2.7 A Formulation Suitable for a Computer Solution . 107 2.8 Summary and Exercises. 108 chapter 3 Network Theorems . 119 3.1 Introduction . 119 3.2 The Node Voltage. 119 3.3 The Node Method. 125 3.3.1 Node Method: A Second Example . 130 3.3.2 Floating Independent Voltage Sources. 135 3.3.3 Dependent Sources and the Node Method . 139 maHiÄ 3.3.4 The Conductance and Source Matrices . 145 ESM 3.4 Loop Method. 145 3.5 Superposition. 145 3.5.1 Superposition Rules for Dependent Sources. 153 3.6 Thevenin's Theorem and Norton's Theorem. 157 3.6.1 The Thevenin Equivalent Network. 157 3.6.2 The Norton Equivalent Network . 167 3.6.3 More Examples . 171 3.7 Summary and Exercises. 177 chapter 4 Analysis of Nonlinear Circuits . 193 4.1 Introduction to Nonlinear Elements . 193 4.2 Analytical Solutions. 197 4.3 Graphical Analysis. 203 4.4 Piecewise Linear Analysis. 206 CEO 4.4.1 Improved Piecewise Linear Models for Nonlinear Elements. 214 4.5 Incremental Analysis. 214 4.6 Summary and Exercises. 229 chapter 5 The Digital Abstraction . 243 5.1 Voltage Levels and the Stade Discipline. 245 5.2 Boolean Logic. 256 5.3 Combinational Gates . 258 5.4 Standard Sum-of-Products Representation. 261 5.5 Simplifying Logic Expressions. 262 5.6 Number Representation. 267 5.7 Summary and Exercises. 274 chapter 6 The MOSFET Switch . 285 6.1 The Switch. 285 6.2 Logic Functions Using Switches. 288 6.3 The MOSFET Device and Its S Model. 288 6.4 MOSFET Switch Implementation of Logic Gates . 291 6.5 Static Analysis Using the S Model . 296 6.6 The SR Model of the MOSFET. 300 6.7 Physical Structure of the MOSFET. 301 6.8 Static Analysis Using the SR Model. 306 6.8.1 Static Analysis ofthe NAND Gate Using the SRModel . 311 6.9 Signal Restoration, Gain, and Nonlinearity . 314 6.9.1 Signal Restoration and Gain . 314 6.9.2 Signal Restoration and Nonlinearity . 317 6.9.3 Buffer Transfer Characteristics and the Static Disäpline . 318 6.9.4 Inverter Transfer Characteristics and the Static Disäpline . 319 6.10 Power Consumption in Logic Gates. 320 6.11 Active Pullups . 321 6.12 Summary and Exercises. 322 chapter 7 The MOSFET Amplifier. 331 7.1 Signal Amplification. 331 7.2 Review of Dependent Sources . 332 7.3 Actual MOSFET Characteristics. 335 7.4 The Switch-Current Source (SCS) MOSFET Model . 340 7.5 The MOSFET Amplifier. 344 7.5.1 Biasing the MOSFET Amplifier. 349 7.5.2 The Amplifier Abstraction and the Saturation Disäpline . 352 7.6 Large-Signal Analysis of the MOSFET Amplifier . 353 7.6.1 vftt Versus vcxjt in the Saturation Region . 353 7.6.2 Valid Input and Output Voltage Ranges . 356 7.6.3 Alternative Metlxxl for Valid Input and Output Voltage Ranges. 363 7.7 Operating Point Selection . 365 7.8 Switch Unified (SU) MOSFET Model. 386 7.9 Summary and Exercises. 389 chapter 8 The Small-Signal Model. 405 8.1 Overview of the Nonlinear MOSFET Amplifier. 405 8.2 The Small-Signal Model. 405 8.2.1 Small-Signal Circuit Representation . 413 8.2.2 Small-Signal Circuit for the MOSFET Amplifier . 418 8.2.3 Selecting an Operating Point. 420 8.2.4 Input and Output Resistance, Current and Power Gain . 423 8.3 Summary and Exercises. 447 chapter 9 Energy Storage Elements . 457 9.1 Constitutive Laws. 461 9.1.1 Capacitors . 461 9.1.2 Inductors. 466 9.2 Series and Parallel Connections . 470 9.2.1 Capacitors . 471 9.2.2 Inductors. 472 9.3 Special Examples. 473 9.3.1 MOSFET Gate Capacitance . 473 9.3.2 Wiring Loop Inductance . 476 9.3.3 IC Wiring Capacitance and Inductance . 477 9.3.4 Transformers . 478 9.4 Simple Circuit Examples. 480 ESM 9.4.1 Sinusoidal Inputs . 482 9.4.2 Steplnputs . 482 9.4.3 Impulse Inputs . 488 EXS3 9.4.4 RoleReversal . 489 9.5 Energy, Charge, and Flux Conservation . 489 9.6 Summary and Exercises. 492 chapter io First-Order Transients in Linear Electrical Networks . 503 10.1 Analysis ofRC Circuits. 504 10.1.1 Parallel RC Circuit, Step Input . 504 10.1.2 RC Discharge Transient . 509 10.1.3 Series RC Circuit, Step Input. 511 10.1.4 Series RC Circuit, Square-Wave Input. 515 10.2 Analysis of RL Circuits. 517 10.2.1 Series RL Circuit, Step Input . 517 10.3 Intuitive Analysis. 520 10.4 Propagation Delay and the Digital Abstraction . 525 10.4.1 Definitionsof Propagation Delays . 527 10.4.2 Computing fa fromthe SRC MOSFET Model . 529 10.5 State and State Variables. 538 10.5.1 The Concept of State. 538 10.5.2 Computer Analysis Using the State Equation . 540 10.5.3 Zero-Input and Zero-State Response. 541 VMM 10.5.4 Solution by Integrating Factors . 544 10.6 Additional Examples. 545 10.6.1 Effect ofWire Inductance in Digital Circuits . 545 10.6.2 Ramp Inputs and Linearity . 545 10.6.3 Response ofan RC Circuit to Short Pulses and the Impulse Response . 550 10.6.4 Intuitive Method for the Impulse Response. 553 10.6.5 Clock Signals and Clock Fanout . 554 UX!0 10.6.6 RC Response to Decaying Exponential . 558 10.6.7 Series RL Circuit with Sine-Wave Input . 558 10.7 Digital Memory. 561 10.7.1 The Concept of Digital State . 561 10.7.2 An Ahstract Digital Memory Element . 562 10.7.3 Design of the Digital Memory Element . 563 10.7.4 A Static Memory Element . 567 10.8 Summary and Exercises. 568 chapter ii Energy and Power in Digital Circuits . 595 11.1 Power and Energy Relations for a Simple RC Circuit. 595 11.2 Average Power in an RC Circuit . 597 11.2.1 Energy Dissipated During Interval T\ . 599 11.2.2 Energy Dissipated During Interval Ti . 601 11.2.3 Total Energy Dissipated. 603 11.3 Power Dissipation in Logic Gates. 604 11.3.1 Static Power Dissipation . 604 11.3.2 Total Power Dissipation . 605 11.4 NMOS Logic. 611 11.5 CMOS Logic. 611 11.5.1 CMOS Logic Gate Design . 616 11.6 Summary and Exercises. 618 chapter ii Transients in Second-Order Circuits . 625 12.1 Undriven LC Circuit. 627 12.2 Undriven, Series RLC Circuit. 640 12.2.1 Under-Damped Dynamics. 644 12.2.2 Over-Damped Dynamics . 648 12.2.3 Criticaüy-Damped Dynamics. 649 12.3 Stored Energy in Transient, Series RLC Circuit. 651 12.4 Undriven, Parallel RLC Circuit. 654 ECO 12.4.1 Under-Damped Dynamics . 654 ECO 12.4.2 Over-Damped Dynamics . 654 ECO 12.4.3 Critically-Damped Dynamics . 654 12.5 Driven, Series RLC Circuit . 654 12.5.1 StepResponse . 657 12.5.2 Impulse Response . 661 12.6 Driven, Parallel RLC Circuit. 678 ECO 12.6.1 StepResponse . 678 ECO 12.6.2 Impulse Response . 678 12.7 Intuitive Analysis of Second-Order Circuits. 678 12.8 Two-Capacitor or Two-Inductor Circuits. 684 12.9 State-Variable Method. 689 12.10 State-Space Analysis. 691 ECO 12.10.1 Numerical Solution . 691 12.11 Higher-Order Circuits . 691 12.12 Summary and Exercises. 692 chapter 13 Sinusoidal Steady State: Impedance and Frequency Response . 703 13.1 Introduction . 703 13.2 Analysis Using Complex Exponential Drive. 706 13.2.1 Homogeneous Solution . 706 13.2.2 Particular Solution . 707 13.2.3 Complete Solution . 710 13.2.4 Sinusoidal Steady-State Response . 710 13.3 The Boxes: Impedance. 712 13.3.1 Example: Series RL Circuit. 718 13.3.2 Example: Another RC Circuit . 722 13.3.3 Example: RC Circuit with Two Capacitors . 724 13.3.4 Example: Analysis ofSmall Signal Amplifier with Capaätive Load . 729 13.4 Frequency Response: Magnitude and Phase versus Frequency. 731 13.4.1 Frequency Response of Capaätors, Inductors, and Resistors . 732 13.4.2 Intuitively Sketching the Frequency Response ofRC and RL Circuits. 737 ECO 13.4.3 The Bode Plot: Sketching the Frequency Response of General Functions. 741 13.5 Filters . 742 13.5.1 Filter Design Example: Crossover Network. 744 13.5.2 Decoupling Amplifier Stages . 746 13.6 Time Domain versus Frequency Domain Analysis using Voltage-Divider Example. 751 13.6.1 Frequency Domain Analysis . 751 13.6.2 Time Domain Analysis . 754 13.6.3 Comparing Time Domain and Frequency Domain Analyses. 756 13.7 Power and Energy in an Impedance. 757 13.7.1 Arbitrary Impedance . 758 13.7.2 Pure Resistance . 760 13.7.3 Pure Reactance . 761 13.7.4 Example: Power in an RC Circuit. 763 13.8 Summary and Exercises. 765 chapter 14 Sinusoidal Steady State: Resonance . 777 14.1 Parallel RLC, Sinusoidal Response. 777 14.1.1 Homogeneous Solution . 778 14.1.2 Particular Solution . 780 14.1.3 Total Solution for the Parallel RLC Circuit. 781 14.2 Frequency Response for Resonant Systems. 783 14.2.1 The Resonant Region of the Frequency Response . 792 _ 14.3 Series RLC. 801 ECO 14.4 The Bode Hot for Resonant Functions. 808 14.5 Filter Examples. 808 14.5.1 Band-pass Filter. 809 14.5.2 Low-pass Filter . 810 14.53 High-pass Filter . 814 14.5.4 NotchFilter . 815 14.6 Stored Energy in a Resonant Circuit. 816 14.7 Summary and Exercises. 821 chapter 15 The Operational Amplifier Abstraction . 837 15.1 Introduction . 837 15.1.1 Historical Perspective . 838 15.2 Device Properties of the Operational Amplifier. 839 15.2.1 The Op Amp Model . 839 15.3 Simple Op Amp Circuits. 842 15.3.1 The Non-lnverting Op Amp. 842 15.3.2 ASecondExample: TheInvertingConnection . 844 15.33 Sensäivity. 846 15.3.4 A Special Case: The Voltage Foüower. 847 153S An Additional Constraint: v+ - v~ ^ 0. 848 15.4 Input and Output Resistances. 849 15.4.1 Output Resistance, InvertmgOpAmp . 849 15.4.2 Input Resistance, Inverting Connection . 851 15.4.3 Input and Output R For Non-Inverting Op Amp . 853 ECO 15.4.4 Generalization on Input Resistance. 855 15.4.5 Example: Op Amp Current Source . 855 15.5 Additional Examples . 857 15.5.1 Adder. 858 15.5.2 Subtracter. 858 15.6 Op Amp RC Circuits . 859 15.6.1 Op Amp Integrator. 859 15.6.2 Op Amp Differentiator . 862 15.6.3 An RC Active Filter. 863 15.6.4 The RC Active Filter?Impedance Analysis . 865 ECO 15.6.5 Sallen-Key Filter . 866 15.7 Op Amp in Saturation. 866 15.7.1 Op Amp Integrator in Saturation . 867 15.8 Positive Feedback. 869 15.8.1 RCOscillator. 869 15.9 Two-Ports. 872 15.10 Summary and Exercises. 873 chapter i 6 Diodes . 905 16.1 Introduction . 905 16.2 Semiconductor Diode Characteristics. 905 16.3 Analysis of Diode Circuits. 908 16.3.1 Method of Assumed States. 908 16.4 Nonlinear Analysis with RL and RC. 912 16.4.1 PeakDetector. 912 16.4.2 Example: Clamping Circuit . 915 ECO 16.4.3 ASwitched Power Supply using a Diode . 918 ECO 16.5 Additional Examples. 918 ECO 16.5.1 Piecewise Linear Example: Clipping Circuit. 918 ECO 16.5.2 Exponentiation Circuit . 918 ECO 16.5.3 Piecewise Linear Example: Limiter. 918 OSO 16.5.4 Example: Full-Wave Diode Bridge. 918 ECO 16.5.5 Incremental Example: Zener-Diode Regulator. 918 ECO 16.5.6 Incremental Example: Diode Attenuator . 918 16.6 Summary and Exercises. 919 appendix a Maxwell's Equations and the Lumped Matter Discipline . 927 A.1 The Lumped Matter Discipline. 927 A.1.1 The First Constraintof the Lumped Matter Disäpline . 927 A.1.2 The Second Constraint ofthe Lumped Matter Disäpline . 930 A. 1.3 The Third Constraint of the Lumped Matter Disäpline . 932 A.1.4 The Lumped Matter Discipline Applied to Circuits. 933 A.2 Deriving Kirchhoffs Laws. 934 A3 Deriving the Resistance ofaPieceof Material. 936 appendix b Trigonometrie Functions and Identities . 941 B.l Negative Arguments. 941 B.2 Phase-Shifted Arguments . 942 B.3 Sum and Difference Arguments . 942 B.4 Products. 943 B.5 Half-Angle and Twice-Angle Arguments. 943 B.6 Squares. 943 B.7 Miscellaneous . 943 B.8 Taylor Series Expansions . 944 B.9 Relations to e'e . 944 appendix c ComplexNumbers . 947 C.l Magnitude and Phase. 947 C.2 Polar Representation. 948 C.3 Addition and Subtraction. 949 C.4 Multiplication and Division. 949 C.5 Complex Conjugate. 950 C.6 Propertiesofe'0 . 951 C.7 Rotation. 951 C.8 Complex Functions of Time. 952 C.9 Numerical Examples. 952 appendix d Solving Simultaneous Linear Equations . 957 Answers to Selected Problems . 959 Figure Credits . 971 Index . 973
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spelling	Agarwal, Anant Verfasser aut Foundations of analog and digital electronic circuits Anant Agarwal ; Jeffrey H. Lang Amsterdam [u.a.] Elsevier 2005 XXIV, 984 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Includes bibliographical references and index Circuitos eletrônicos larpcal Circuits électroniques ram Electronic circuits Textbooks Elektronische Schaltung (DE-588)4113419-9 gnd rswk-swf Digitalschaltung (DE-588)4012295-5 gnd rswk-swf Digitaltechnik (DE-588)4012303-0 gnd rswk-swf Operationsverstärker (DE-588)4043590-8 gnd rswk-swf MOS-FET (DE-588)4207266-9 gnd rswk-swf Analogschaltung (DE-588)4122796-7 gnd rswk-swf (DE-588)4123623-3 Lehrbuch gnd-content Analogschaltung (DE-588)4122796-7 s Digitalschaltung (DE-588)4012295-5 s DE-604 Digitaltechnik (DE-588)4012303-0 s MOS-FET (DE-588)4207266-9 s Operationsverstärker (DE-588)4043590-8 s Elektronische Schaltung (DE-588)4113419-9 s Lang, Jeffrey Sonstige oth HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=014276669&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Agarwal, Anant Foundations of analog and digital electronic circuits Circuitos eletrônicos larpcal Circuits électroniques ram Electronic circuits Textbooks Elektronische Schaltung (DE-588)4113419-9 gnd Digitalschaltung (DE-588)4012295-5 gnd Digitaltechnik (DE-588)4012303-0 gnd Operationsverstärker (DE-588)4043590-8 gnd MOS-FET (DE-588)4207266-9 gnd Analogschaltung (DE-588)4122796-7 gnd
subject_GND	(DE-588)4113419-9 (DE-588)4012295-5 (DE-588)4012303-0 (DE-588)4043590-8 (DE-588)4207266-9 (DE-588)4122796-7 (DE-588)4123623-3
title	Foundations of analog and digital electronic circuits
title_auth	Foundations of analog and digital electronic circuits
title_exact_search	Foundations of analog and digital electronic circuits
title_exact_search_txtP	Foundations of analog and digital electronic circuits
title_full	Foundations of analog and digital electronic circuits Anant Agarwal ; Jeffrey H. Lang
title_fullStr	Foundations of analog and digital electronic circuits Anant Agarwal ; Jeffrey H. Lang
title_full_unstemmed	Foundations of analog and digital electronic circuits Anant Agarwal ; Jeffrey H. Lang
title_short	Foundations of analog and digital electronic circuits
title_sort	foundations of analog and digital electronic circuits
topic	Circuitos eletrônicos larpcal Circuits électroniques ram Electronic circuits Textbooks Elektronische Schaltung (DE-588)4113419-9 gnd Digitalschaltung (DE-588)4012295-5 gnd Digitaltechnik (DE-588)4012303-0 gnd Operationsverstärker (DE-588)4043590-8 gnd MOS-FET (DE-588)4207266-9 gnd Analogschaltung (DE-588)4122796-7 gnd
topic_facet	Circuitos eletrônicos Circuits électroniques Electronic circuits Textbooks Elektronische Schaltung Digitalschaltung Digitaltechnik Operationsverstärker MOS-FET Analogschaltung Lehrbuch
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=014276669&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
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