Contents
1. | Basic Circuit Elements and Waveforms | ||
1.1 | Circuit Components | ||
1.2 | Definitions of Electrical Circuits | ||
1.3 | Conservation of Energy | ||
1.4 | Source of Electrical Energy | ||
1.5 | Standard Input Signals | ||
1.6 | Sinusoidal Signal | ||
2. | Mesh and Node Analysis | ||
2.1 | Kirchhoff's Laws | ||
2.2 | Source Transformation | ||
2.3 | Mesh and Node Analysis | ||
2.4 | Network Equations for RLC Network | ||
2.5 | Magnetic Coupling | ||
3. | Graph Theory and Network Equation | ||
3.1 | Incidence Matrix | ||
3.2 | Cut-Set Matrix | ||
3.3 | Tie-Set Matrix and Loop Currents | ||
3.4 | Trees of a Graph | ||
3.5 | Analysis of Networks | ||
3.6 | Network Equilibrium Equation | ||
3.7 | Duality | ||
3.8 | General Network Transformations | ||
4. | Fourier Series | ||
4.1 | Trigonometric Fourier Series | ||
4.2 | Evaluation of Fourier Coefficients | ||
4.3 | Waveform Symmetry | ||
4.4 | Fourier Series in Optimal Sense | ||
4.5 | Exponential Form of Fourier Series | ||
4.6 | Fourier Transform | ||
5. | The Laplace Transform | ||
5.1 | Laplace Transformation | ||
5.2 | Some Basic Theorems | ||
5.3 | Gate Function | ||
5.4 | Impulse Function | ||
5.5 | Laplace Transform of Periodic Functions | ||
6. | Application Laplace Transform | ||
6.1 | Solution of Linear Differential Equation | ||
6.2 | Heaviside's Partial Fraction Expansion | ||
6.3 | Kirchhoff's Laws | ||
6.4 | Solution of Network Problems | ||
7. | Network Theorems | ||
7.1 | Superposition Theorem | ||
7.2 | Reciprocity Theorem | ||
7.3 | Thevenin's Theorem | ||
7.4 | Norton's Theorem | ||
7.5 | Millman's Theorem | ||
7.6 | Maximum Power Transfer Theorem | ||
7.7 | Substitution Theorem | ||
7.8 | Compensation Theorem | ||
7.9 | Tellegen's Theorem | ||
8. | Resonance | ||
8.1 | Series Resonance | ||
8.2 | Parallel Resonance | ||
9. | Analogous System | ||
9.1 | Mechanical Elements | ||
9.2 | D'Alembert's Principle | ||
9.3 | Force-Voltage Analogy | ||
9.4 | Force-Current Analogy | ||
9.5 | Mechanical Couplings | ||
9.6 | Electro-Mechanical System | ||
9.7 | Liquid-Level System | ||
10. | Two-Port Network | ||
10.1 | Characterization of Linear Time-Invariant Two-Port Networks | ||
10.2 | Open-Circuit Impedance Parameters | ||
10.3 | Short-Circuit Admittance Parameters | ||
10.4 | Transmission Parameters | ||
10.5 | Inverse Transmission Parameters | ||
10.6 | Hybrid Parameters | ||
10.7 | Inverse Hybrid Parameters | ||
10.8 | Interrelationships between the Parameters | ||
10.9 | Interconnection of Two-Port Networks | ||
10.10 | Two-Port Symmetry | ||
10.11 | Input Impedance in terms of Two-Port Parameters | ||
10.12 | Output Impedance | ||
10.13 | Image Impedance | ||
10.14 | Transistors as Two-Port Active Network | ||
10.15 | Network Components | ||
11. | Attenuators | ||
11.1 | Nepers, Decibels | ||
11.2 | Lattice Attenuator | ||
11.3 | T-Type Attenuator | ||
11.4 | π-Type Attenuator | ||
11.5 | L-Type |ittenuator | ||
11.6 | Ladder type Attenuator | ||
11.7 | Balanced Attenuators | ||
11.8 | Insertion Loss | ||
12. | Conventional Filters | ||
12.1 | Image Impedance | ||
12.2 | Hyperbolic Trigonometry | ||
12.3 | Propagation Constant | ||
12.4 | Properties of Symmetrical Network | ||
12.5 | Filter Fundamentals | ||
13. | Convolution Integral | ||
13.1 | Graphical Convolution | ||
14. | State Variable Analysis | ||
14.1 | Transfer Function | ||
14.2 | State Transition Matrix | ||
15. | Network Functions | ||
15.1 | Poles and Zeros | ||
15.2 | Transient Responses | ||
16. | Passive Network Synthesis | ||
16.1 | Driving Point and Transfer Impedence Function | ||
16.2 | LC Network | ||
16.3 | Two Terminal R-L and R-C Network | ||
17. | Feedback System | ||
17.1 | Block Diagram Representation | ||
17.2 | Signal Flow Graph | ||
17.3 | Routh-Hurwitz Stability Criterion | ||
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