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| 100 | 1 | _aKumar, Suresh. | |
| 245 | 1 | 0 |
_aElectric Circuits and Networks : _bFor GTU. |
| 250 | _a0 | ||
| 300 | _a1 online resource (561 pages) | ||
| 505 | 0 | _aCover -- Contents -- Preface -- Road Map to the Syllabus -- Chapter 1: Circuit Variables and Circuit Elements -- Introduction -- 1.1 Electromotive Force, Potential and Voltage -- 1.1.1 Force Between Two Moving Point Charges and Retardation Effect -- 1.1.2 Electric Potential and Voltage -- 1.1.3 Electromotive Force and Terminal Voltage of a Steady Source -- 1.2 a Voltage Source with a Resistance Connected at its Terminals -- 1.2.1 Steady-State Charge Distribution in the System -- 1.2.2 Drift Velocity and Current Density -- 1.2.3 Current Intensity -- 1.2.4 Conduction and Energy Transfer Process -- 1.2.5 Two-terminal Resistance Element -- 1.2.6 A Time-Varying Voltage Source with Resistance Across it -- 1.3 Two-terminal Capacitance -- 1.4 Two-terminal Inductance -- 1.4.1 Induced Electromotive Force and its Location in a Circuit -- 1.4.2 Relation Between Induced Electromotive Force and Current -- 1.4.3 Faraday's Law and Induced Electromotive Force -- 1.4.4 The Issue of a Unique Voltage Across a Two-terminal Element -- 1.4.5 The Two-terminal Inductance -- 1.5 Ideal Independent Two-terminal Electrical Sources -- 1.5.1 Ideal Independent Voltage Source -- 1.5.2 Ideal Independent Current Source -- 1.5.3 Ideal Short-Circuit Element and Ideal Open-circuit Element -- 1.6 Power and Energy Relations for Two-terminal Elements -- 1.6.1 Passive Sign Convention -- 1.6.2 Power and Energy in Two-terminal Elements -- 1.7 Classification of Two-terminal Elements -- 1.7.1 Lumped and Distributed Elements -- 1.7.2 Linear and Non-Linear Elements -- 1.7.3 Bilateral and Non-Bilateral Elements -- 1.7.4 Passive and Active Elements -- 1.7.5 Time-Invariant and Time-Variant Elements -- 1.8 Multi-terminal Circuit Elements -- 1.8.1 Mutual Inductance Element -- 1.8.2 Why Should M12 be Equal to M21? -- 1.8.3 Ideal Dependent Sources -- 1.9 Summary -- 1.10 Problems. | |
| 505 | 8 | _aChapter 2: Basic Circuit Laws -- Introduction -- 2.1 Kirchhoff's Voltage Law (KVL) -- 2.2 Kirchhoff's Current Law (KCL ) -- 2.3 Interconnections of Ideal Sources -- 2.4 Analysis of a Single-Loop Circuit -- 2.5 Analysis of a Single-Node-Pair Circuit -- 2.6 Analysis of Multi-Loop, Multi-Node Circuits -- 2.7 Summary -- 2.8 Problems -- Chapter 3: Single Element Circuits -- Introduction -- 3.1 The Resistor -- 3.1.1 Series Connection of Resistors -- 3.1.2 Parallel Connection of Resistors -- 3.2 The Inductor -- 3.2.1 Instantaneous Inductor Current Versus Instantaneous Inductor Voltage -- 3.2.2 Change in Inductor Current Function Versus Area Under Voltage Function -- 3.2.3 Average Applied Voltage for a Given Change in Inductor Current -- 3.2.4 Instantaneous Change in Inductor Current -- 3.2.5 Inductor with Alternating Voltage Across it -- 3.2.6 Inductor with Exponential and Sinu so Idal Voltage Input -- 3.2.7 Linearity of Inductor -- 3.2.8 Energy Storage in an Inductor -- 3.3 Series Connection of Inductors -- 3.3.1 Series Connection of Inductors with Same Initial Current -- 3.3.2 Series Connection with Unequal Initial Currents -- 3.4 Parallel Connection of Inductors -- 3.4.1 Parallel Connection of Initially Relaxed Inductors -- 3.4.2 Parallel Connection of Inductors with Initial Energy -- 3.5 The Capacitor -- 3.6 Series Connection of Capacitors -- 3.6.1 Series Connection of Capacitors with Zero Initial Energy -- 3.6.2 Series Connection of Capacitors with Non-Zero Initial Energy -- 3.7 Parallel Connection of Capacitors -- 3.8 Summary -- 3.9 Questions -- 3.10 Problems -- Chapter 4: Nodal Analysis and Mesh Analysis of Memoryless Circuits -- Introduction -- 4.1 The Circuit Analysis Problem -- 4.2 Nodal Analysis of Circuits Containing Resistors with Independent Current Sources -- 4.3 Nodal Analysis of Circuits Containing Independent Voltage Sources. | |
| 505 | 8 | _a4.4 Source Transformation Theorem and its Use in Nodal Analysis -- 4.4.1 Source Transformation Theorem -- 4.4.2 Applying Source Transformation Theorem in Nodal Analysis of Circuits -- 4.5 Nodal Analysis of Circuits Containing Dependent Current Sources -- 4.6 Nodal Analysis of Circuits Containing Dependent Voltage Sources -- 4.7 Mesh Analysis of Circuits with Resistors and Independent Voltage Sources -- 4.7.1 Principle of Mesh Analysis -- 4.7.2 Is Mesh Current Measurable? -- 4.8 Mesh Analysis of Circuits with Independent Current Sources -- 4.9 Mesh Analysis of Circuits Containing Dependent Sources -- 4.10 Summary -- 4.11 Problems -- Chapter 5: Circuit Theorems -- Introduction -- 5.1 Linearity of a Circuit and Superposition Theorem -- 5.1.1 Linearity of a Circuit -- 5.2 Star-Delta Transformation Theorem -- 5.3 Substitution Theorem -- 5.4 Compensation Theorem -- 5.5 Thevenin's Theorem and Norton's Theorem -- 5.6 Determination of Equivalents for Circuits with Dependent Sources -- 5.7 Reciprocity Theorem -- 5.8 Maximum Power Transfer Theorem -- 5.9 Millman's Theorem -- 5.10 Summary -- 5.11 Problems -- Chapter 6: Simple RL Circuits in Time-Domain -- Introduction -- 6.1 The Series RL Circuit -- 6.1.1 The Series RL Circuit Equations -- 6.1.2 Need for Initial Condition Specification -- 6.1.3 Sufficiency of Initial Condition -- 6.2 Series RL Circuit with Unit Step Input - Qualitative Analysis -- 6.2.1 From T = 0- to T = 0+ -- 6.2.2 Inductor Current Growth Process -- 6.3 Series RL Circuit with Unit Step Input - Power Series Solution -- 6.3.1 Series RL Circuit Current as a Power Series -- 6.4 Step Response of an RL Circuit by Solving Differential Equation -- 6.4.1 Interpreting the Input Forcing Functions in Circuit Differential Equations -- 6.4.2 Solving the Series RL Circuit Equation by Integrating Factor Method. | |
| 505 | 8 | _a6.4.3 Complementary Function and Particular Integral -- 6.5 Features of RL Circuit Step Response -- 6.5.1 Step Response Waveforms in Series RL Circuit -- 6.5.2 The Time Constant of a Series RL Circuit -- 6.5.3 Rise Time and Fall Time in First Order Circuits -- 6.5.4 Effect of Non-Zero Initial Condition on Step Response of RL Circuit -- 6.5.5 Free Response of Series RL Circuit -- 6.6 Steady-State Response and Forced Response -- 6.6.1 The DC Steady-State -- 6.6.2 The Sinusoidal Steady-State -- 6.6.3 The Periodic Steady-State -- 6.7 Linearity and Superposition Principle in Dynamic Circuits -- 6.8 Unit Impulse Response of Series RL Circuit -- 6.8.1 Unit Impulse Response of RL Circuit with Non-Zero Initial Current -- 6.8.2 Zero-State Response for Other Inputs from Zero-State Impulse Response -- 6.9 Series RL Circuit with Exponential Inputs -- 6.9.1 Zero-State Response for a Real Exponential Input -- 6.9.2 Zero-State Response for Sinusoidal Input -- 6.10 General Analysis Procedure for Single Time Constant RL Circuits -- 6.11 Summary -- 6.12 Questions -- 6.13 Problems -- Chapter 7: RC and RLC Circuits in Time-Domain -- Introduction -- 7.1 RC Circuit Equations -- 7.2 Zero-Input Response of RC Circuit -- 7.3 Zero-State Response of RC Circuits for Various Inputs -- 7.3.1 Impulse Response of First-Order RC Circuits -- 7.3.2 Step Response of First-Order RC Circuits -- 7.3.3 Ramp Response of Series RC Circuit -- 7.3.4 Series RC Circuit with Real Exponential Input -- 7.3.5 Zero-State Response of Parallel RC Circuit for Sinu Soidal Input -- 7.4 Periodic Steady-State in a Series RC Circuit -- 7.5 Sinusoidal Steady-State Frequency Response of First-Order RC Circuits -- 7.5.1 The Use of Frequency Response -- 7.5.2 Frequency Response and Linear Distortion -- 7.5.3 Jean Baptiste Joseph Fourier and Frequency Response -- 7.5.4 First-Order RC Circuits as Averaging Circuits. | |
| 505 | 8 | _a7.5.5 Capacitor as a Signal-Coupling Element -- 7.5.6 Parallel RC Circuit for Signal Bypassing -- 7.6 The Series RLC Circuit - Zero-Input Response -- 7.6.1 Source-Free Response of Series RLC Circuit -- 7.6.2 The Series LC Circuit - A Special Case -- 7.6.3 The Series LC Circuit with Small Damping -Another Special Case -- 7.6.4 Standard Formats for Second-Order Circuit Zero-Input Response -- 7.7 Impulse Response of Series RLC Circuit -- 7.8 Step Response of Series RLC Circuit -- 7.9 Standard Time-Domain Specifications for Second-Order Circuits -- 7.10 Examples on Impulse and Step Response of Series RLC Circuits -- 7.11 Frequency Response of Series RLC Circuit -- 7.11.1 Sinusoidal Forced-Response from Differential Equation -- 7.11.2 Frequency Response from Phasor Equivalent Circuit -- 7.11.3 Qualitative Discussion on Frequency Response of Series RLC Circuit -- 7.11.4 A More Detailed Look at the Band-Pass Output of Series RLC Circuit -- 7.11.5 Quality Factor of Inductor and Capacitor -- 7.12 The Parallel RLC Circuit -- 7.12.1 Zero-Input Response and Zero-State Response of Parallel RLC Circuit -- 7.12.2 Sinusoidal Steady-State Frequency Response of Parallel RLC Circuit -- 7.13 Summary -- 7.14 Questions -- 7.15 Problems -- Chapter 8: Higher Order Circuits in Time-Domain -- Introduction -- 8.1 Analysis of Multi-Mesh and Multi-Node Dynamic Circuits -- 8.2 Generalisations for an nth Order Linear Time-Invariant Circuit -- 8.3 Time-Domain Convolution Integral -- 8.3.1 Zero-State Response to Narrow Rectangular Pulse Input -- 8.3.2 Expansion of an Arbitrary Input Function in Terms of Impulse Functions -- 8.3.3 The Convolution Integral -- 8.3.4 Graphical Interpretation of Convolution in Time-Domain -- 8.3.5 Frequency Response Function from Convolution Integral -- 8.3.6 A Circuit with Multiple Sources - Applying Convolution Integral. | |
| 505 | 8 | _a8.3.7 Zero-Input Response by Convolution Integral. | |
| 520 | _aElectric Circuits and Networks: For GTU is designed to serve as a textbook for an undergraduate course on basic electric circuits and networks. Spread over eleven chapters, it can be taught with varying degrees of emphasis depending on the course requirements. | ||
| 590 | _aElectronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2018. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries. | ||
| 655 | 4 | _aElectronic books. | |
| 776 | 0 | 8 |
_iPrint version: _aKumar, Suresh _tElectric Circuits and Networks : For GTU _dNoida : Pearson India,c2010 |
| 797 | 2 | _aProQuest (Firm) | |
| 856 | 4 | 0 |
_uhttps://ebookcentral.proquest.com/lib/cethalassery/detail.action?docID=5125155 _zClick to View |
| 942 |
_2ddc _cBK |
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