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Electricity
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Electrical Circuit Analysis
Electric Circuit
Resistance
Series DC Circuits
Parallel DC Circuits
Series Parallel Circuits
Methods of Analysis
Network Theorems
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Magnetic Circuits
Inductors
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Electrical Circuit Analysis
1. Electric Circuit
1.1. Circuit Elements
1.1.1. Active Circuit Elements
1.1.2. Passive Circuit Elements
1.2. Ohms Law
1.3. Open Circuits
1.4. Short Circuits
2. Resistance
2.1. Resistance of Circular Wires
2.1.1. Circular Mils
2.1.2. Electrical Cables
2.1.3. Wire Gauge
2.2. Temperature Effect on Resistance
2.2.1. Inferred Absolute Temperature
2.2.2. Temperature Coefficient of Resistance
2.2.3. PPM per degree Centigrade
2.3. Resistor
2.4. Color coding and Standard Resistor Values
2.5. Metric Units of Resistance
3. Series DC Circuits
3.1. Series Circuit
3.2. Circuit Instrumentation
3.3. Series Circuit Power Distribution
3.4. Series Voltage Sources
3.5. Kirchhoffs Voltage Law
3.6. Voltage Division in a Series Circuit
3.7. Interchanging Series Elements
3.8. Circuit Analysis Notation
3.8.1. Single and Double Subscript Notation
3.9. Internal Resistance of Voltage Sources
3.10. Voltage Regulation
3.11. Loading Effects of Instruments
4. Parallel DC Circuits
4.1. Parallel Circuits
4.2. Power Distribution
4.3. Kirchhoffs Current law
4.4. Current Divider Rule
4.5. Voltage Sources in Parallel
4.6. Voltmeter Loading Effect
4.7. Troubleshooting Techniques
4.8. Parallel DC Circuits Applications
5. Series Parallel Circuits
5.1. Reduce and Return Approach
5.2. Block Diagram Approach
5.3. Ladder Networks
5.4. Voltage Divider Supply
5.5. Potentiometer Loading
5.6. Iron Vane Movement
5.6.1. Ammeter Design
5.6.2. Voltmeter Design
5.6.3. Ohmmeter Design
6. Methods of Analysis
6.1. Current Sources
6.1.1. Source Conversion
6.1.2. Current Sources in Parallel
6.1.3. Current Sources in Series
6.2. Branch Current Analysis
6.3. Mesh Analysis
6.4. Mesh Analysis with Current Sources
6.5. Nodal Analysis
6.6. Nodal Analysis with Voltage Sources
6.7. Bridge Networks
6.8. Star Delta Transformation
7. Network Theorems
7.1. Linearity Property
7.2. Superposition Theorem
7.3. Thevenins Theorem
7.4. Nortons Theorem
7.5. Maximum Power Transfer Theorem
7.6. Application of Maximum Power Transfer Method
7.7. Millmans Theorem
7.8. Substitution Theorem
7.9. Reciprocity Theorem
8. Capacitors
8.1. Capacitance
8.2. Types of capacitor
8.3. Initial Conditions of capacitor
8.4. Capacitor Charging Phase
8.5. Capacitor Discharging Phase
8.6. Instantaneous Values of Capacitor
8.7. Thevenin Equivalent Circuit of Capacitor
8.8. Current through capacitor
8.9. Capacitors in series and parallel
8.10. Energy Stored by a Capacitor
8.11. Stray Capacitance
9. Magnetic Circuits
9.1. Magnetic Flux Density
9.2. Permeability
9.3. Magnetic Reluctance
9.4. Ohms Law for Magnetic Circuits
9.5. Magnetizing Force
9.6. Hysteresis Curve
9.7. Domain Theory of Magnetism
9.8. Amperes Circuital Law
9.9. Series Magnetic Circuits
9.10. Magnetic Circuit Air Gaps
9.11. Series and Parallel Magnetic Circuits
9.12. Application of Magnetic circuits
9.12.1. Speakers and Microphones
9.12.2. Computer Hard Disks
9.12.3. Hall Effect Sensor
9.12.4. Magnetic Reed Switch
9.12.5. Magnetic Resonance Imaging
10. Inductors
10.1. Faradays Law of Induction
10.2. Lenz law
10.3. Self Inductance
10.4. Types of Inductors
10.5. Inductor values
10.6. Induced Voltage
10.7. Transient Response of RL Circuit
10.8. Initial Values of an Inductor
10.9. Decay of Current in RL Circuit
10.10. Thevenin Equivalent Circuit of Inductor
10.11. Inductors in Series and Parallel
10.12. RL and RLC Circuits with DC Inputs
10.13. Energy Stored by an Inductor
10.14. Applications of inductor
11. Sinusoidal Alternating Waveforms
11.1. Sinusoidal AC Voltage Generation
11.2. Sinusoidal AC Waveform Definitions
11.3. The Sine Wave
11.4. General Format for the Sinusoidal Voltage or Current
11.5. Phase Relationship of a Sinusoidal Waveform
11.6. Average Value of Sinusoidal Waveform
11.7. Root Mean Square value of Sinusoidal waveform
11.8. AC meters and Instruments
12. Basic Elements of AC Circuit and Phasors
12.1. The Derivative of Sinusoidal Waveform
12.2. Response of Resistor to a Sinusoidal Voltage
12.3. Response of Inductor to a Sinusoidal Voltage
12.4. Response of Capacitor to a Sinusoidal Voltage
12.5. Frequency Effects on L and C in DC Circuits
12.6. Frequency Response of the Basic Elements
12.7. Average Power of Sinusoidal Voltage
12.8. AC Power Factor
12.9. Complex Numbers
12.9.1. Rectangular Form
12.9.2. Polar Form
12.9.3. Conversation between Complex Number Forms
12.9.4. Mathematical Operations with Complex Numbers
12.10. Phasors
13. Series and Parallel ac Circuits
13.1. Impedance and the Phasor Diagram
13.1.1. Impedance of Resistive Elements
13.1.2. Impedance of Inductive Reactance
13.1.3. Impedance of Capacitive Reactance
13.1.4. Impedance Diagram
13.2. AC Series Configuration
13.2.1. RL Series Circuit
13.2.2. RC Series Circuit
13.2.3. RLC Series Circuit
13.3. AC Voltage Divider Rule
13.4. Frequency Response of the RC Circuit
13.5. SUMMARY of Series AC Circuits
13.6. Admittance and Susceptance
13.7. Parallel ac Networks
13.7.1. RL Parallel Circuit
13.7.2. RC Parallel Circuit
13.7.3. RLC Parallel Circuit
13.8. Current Divider Rule of ac Circuits
13.9. Frequency Response of Parallel RL Network
13.10. Parallel ac Networks Summary
13.11. AC Equivalent Circuit
13.12. Phase Shift Measurement with Dual Trace Oscilloscope
13.13. Application of Series and Parallel ac Circuits
13.13.1. Home Wiring
13.13.2. Speaker Systems
14. Methods of Analysis of AC Network
14.1. Independent Versus Dependent Controlled Sources
14.2. Source Conversion of ac Circuits
14.3. Mesh Analysis for ac Circuits
14.4. Nodal Analysis for ac Circuits
14.5. AC Bridge Networks
14.6. Star Delta Transformation (AC)
15. Network Theorem (AC)
15.1. Superposition Theorem (ac)
15.2. Thevenins Theorem (ac)
15.3. Nortons Theorem (ac)
15.4. Maximum Power Transfer Theorem (ac)
16. Power (AC)
16.1. Resistive (AC) Circuit Power Calculation
16.2. Apparent Power
16.3. Reactive Power in Inductive Circuit
16.4. Reactive Power in Capacitive Circuit
16.5. The Power Triangle
16.6. The Total Apparent, Active and Reactive Power
16.7. Power Factor Correction
16.8. Wattmeters and Power Factor Meters
16.9. Effective Resistance
17. Resonance
17.1. Series Resonant Circuit
17.2. The Quality Factor (Q)
17.3. Total Impedance Versus Frequency
17.4. Selectivity of Frequency
17.5. Magnitudes of Voltages across RLC versus Frequency
17.6. Examples of Series Resonance Circuits
17.7. Parallel Resonant Circuit
17.7.1. Resonace Frequency of a Parallel Resonant Circuit
17.8. Selectivity Curve for Parallel Resonant Circuits
17.9. Effect of Quality Factor greater than or Equal to 10
17.9.1. Inductive Reactance
17.9.2. Resonant Frequency (Unity Power Factor)
17.9.3. Parallel Resistance across Inductance
17.9.4. Total impedance at resonance
17.9.5. Quality Factor
17.9.6. Bandwidth (BW)
17.9.7. Current through Capacitor and Inductor
17.10. Examples of Parallel Resonance
17.11. Applications of Resonance Circuits
18. Transformer
18.1. Mutual Inductance
18.2. The Iron Core Transformer
18.3. Reflected Impedance and Power
18.3.1. Transformer as a Impedance Matching
18.3.2. Transformer as an Isolation Device
18.4. Iron Core Transformer Equivalent Circuit
18.5. Transformer Frequency Considerations
18.6. Series Connection of Mutually Coupled Coils
18.7. Air Core Transformer
18.8. Transformer Nameplate Data
18.9. Types of Transformers
18.10. Tapped and Multiple Load Transformers
18.11. Networks with Magnetically Coupled Coils
18.12. Applications of Transformer
18.12.1. Transformer for Low Voltage Compensation
18.12.2. Ballast Transformer
19. Polyphase Systems
19.1. The Three Phase Generator
19.2. The Y Connected Generator
19.2.1. Phase Sequence (Y CONNECTED GENERATOR)
19.2.2. Y connected Generator connected to a Y connected load
19.3. The Y Delta System
19.4. The Delta Connected Generator
19.5. The Delta Delta, Delta Y Three Phase Systems
19.6. Power Calculation of Y Connected Balanced Load
19.7. Power Calculation of Delta Connected Balanced Load
19.8. The Three Wattmeter Method
19.9. The Two Wattmeter Method
19.10. Unbalanced Three phase Four wire, Y Connected Load
19.11. Unbalanced, Three phase, Three wire, Y Connected Load
20. Frequency Response
20.1. Logarithm
20.2. Decibels
20.2.1. Decibels with Power Gain
20.2.2. Decibels with Voltage Gain
20.2.3. The Human Auditory Response
20.2.4. Decibels Instrumentations
20.3. Transfer Function
20.4. Filters
20.4.1. RC Low Pass Filters
20.4.2. RC High Pass Filters
20.4.3. Pass Band Filters
20.4.4. Stop Band Filters
20.4.5. Double Tuned Filters
20.5. Bode Plots
20.5.1. High Pass RC Filter
20.5.2. Low Pass RC Filter
20.6. Sketching the Bode Response
20.7. Low Pass Filter with Limited Attenuation
20.8. High Pass Filter with Limited Attenuation
20.9. Crossover Networks
20.10. Application of Filters
20.10.1. Attenuators
20.10.2. Noise Filters
21. Pulse Waveform and the RC Response
21.1. Ideal versus Actual Pulse Waveform
21.2. Properties of a Pulse Waveform
21.3. Pulse Repetition Rate and Duty Cycle
21.4. Average Value of a Pulse Waveform
21.5. Transient in RC Network
21.6. RC Response to Square Wave Inputs
21.7. Oscilloscope Attenuator
21.8. Compensating Attenuator Probe
21.9. Application of Pulse Waveform
22. The Laplace Transform
22.1. Properties of The Laplace Transform
22.1.1. Linearity Property of The Laplace Transform
22.1.2. Scaling Property of The Laplace Transform
22.1.3. Time Shift Property of The Laplace Transform
22.1.4. Frequency Shift Property of The Laplace Transform
22.1.5. Time Differentiation Property of The Laplace Transform
22.1.6. Time Integral Property of The Laplace Transform
22.1.7. Frequency Differentiation Property of The Laplace Transform
22.1.8. Time Periodicity Property of The Laplace Transform
22.1.9. Initial and Final Values Properties of The Laplace Transform
22.2. List of the Properties of The Laplace Transform
22.3. Examples of The Laplace Transform
22.4. The Inverse Laplace Transform
22.4.1. Simple Poles
22.4.2. Repeated Poles
22.4.3. Complex Poles
22.5. Examples of The Inverse Laplace Transform
22.6. Circuit Application of The Laplace Transform
22.7. Transfer Function of The Laplace Transform
22.8. The Convolution Integral
22.9. Application to Integrodifferential Equations
22.10. Application of The Laplace Transform to the Network Stability
22.11. Application of The Laplace Transform to the Network Synthesis
23. The Fourier Series
23.1. Trigonometric Fourier Series
23.2. Symmetry Considerations of The Fourier Series
23.2.1. Even Symmetry
23.2.2. Odd Symmetry
23.2.3. Half Wave Symmetry
23.3. Common Functions of The Fourier Series
23.4. Circuit Application of The Fourier Series
23.5. Average Power and RMS Values of The Fourier Series
23.6. Exponential Fourier Series
23.7. Application of the Fourier Series to Spectrum Analyzers
23.8. Application of the Fourier Series to Filters
24. Fourier Transform
24.1. Properties of the Fourier Transform
24.1.1. Linearity property of the Fourier Transform
24.1.2. Time Scaling property of the Fourier Transform
24.1.3. Time Shifting property of the Fourier Transform
24.1.4. Frequency Shifting property of the Fourier Transform
24.1.5. Time Differenciation property of the Fourier Transform
24.1.6. Time Integration property of the Fourier Transform
24.1.7. Reversal property of the Fourier Transform
24.1.8. Duality property of the Fourier Transform
24.1.9. Convolution property of the Fourier Transform
24.1.10. Summary of the Properties of the Fourier Transform
24.2. Examples of the Fourier Transform
24.3. Examples of the Inverse Fourier Transform
24.4. Circuit Application of the Fourier Transform
24.5. Parsevals Theorem
24.6. Comparing the Fourier and Laplace Transform
24.7. Application of the Fourier Transform to the Amplitude Modulation
24.8. Application of the Fourier Transform to the Sampling
25. Two Port Networks
25.1. Impedance Parameters
25.2. Admittance Parameters
25.3. Hybrid Parameters
25.4. Transmission Parameters
25.5. Relationships between Parameters
25.6. Interconnection of Networks
25.7. Application of the Two Port Networks to the Transistor Circuits
25.8. Application of the Two Port Networks to the Ladder Network Synthesis
26. Nonsinusoidal Circuits
26.1. Circuit Response to a Nonsinusoidal Input
26.2. Addition and Subtraction of Nonsinusoidal Waveforms
Application of Series and Parallel ac Circuits
Electrical Circuit Analysis
>
Series and Parallel ac Circuits
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