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1. Electric and Magnetic Circuits
1.1(a) EMF,
1.1(b) Current,
1.1(c) Potential Difference
1.1(d) Power and Energy
1.2(a) M.M.F,
1.2(b) magnetic force,
1.2(c) permeability,
1.2(d) hysteresis loop,
1.2(e) reluctance,
1.2(f) leakage factor
1.2(g) B-H curve.
1.3 Analogy between electric and magnetic circuits.
1.4(a) Electromagnetic induction,
1.4(b) Faraday’s laws of electromagnetic induction,
1.4(c) Lenz’s law,
1.4(d) Dynamically induced emf
1.5(a) Statically induced emf.-(a) Self induced emf (b) Mutually induced emf;
1.5(b) Self Induced
1.5(c) Mutual Induced
2. A.C Circuits
2.1(a) Cycle, Frequency, Periodic time, Amplitude, RMS value, Average value.
2.1(b) Angular velocity,
2.1(c) impedance,
2.1(d) phase angle,
2.1(e) Form Factor and power factor
2.2(a) Mathematical and phasor representation of alternating emf and current;
2.2(b) Voltage and Current relationship in Star and Delta connections.
2.3(a) A.C. in resistors, inductors and capacitors;
2.3(b) A.C. in R-L series,
2.3(c) A.C. in R-C series,
2.3(d) A.C. in R-L-C series
2.3(e) A.C. in R-L parallel circuits
2.3(f) A.C. in R-C parallel circuits
2.3(g) A.C. in R-L-C parallel circuits
2.3(h) Power in A. C. Circuits
2.3(i) Power Triangle in A. C. Circuits
3. Transformer and Single Phase Induction
3.1(a) General Construction and Principle of Transformers
3.1(b) Different Type of Transformers
3.1(c) Emf Equation
3.1(d) Transformation ratio of transformers
3.2 Auto transformers
3.3 Construction and Working principle of single phase A.C. motor.
3.4(a) Types of single phase motors,
3.4(b) applications of single phase motors
4. Electronic Components and Signals
4.1(a) Active and passive components;
4.1(b) Capacitor symbols, colour codes, specifications
4.1(c) Inductor symbols, colour codes, specifications
4.1(d) Resistor symbols, colour codes, specifications
4.2 Voltage and Current Sources
4.3(a) Signals: waveform (sinusoidal, triangular and square)
4.3(b) time and frequency domain representation
4.3(c) amplitude, frequency, phase, wavelength
5. Diodes and Applications
5.1 P-N junction diode: symbol. construction , working and applications.
5.2(a) Zener diode: working, symbol, voltage regulator.
5.2(b) Zener diode as voltage regulator
5.3(a) Rectifiers: Half wave, Full wave,
5.3(b) Rectifiers: Bridge Rectifier,
5.3(c) Ripple Factor of Half wave, Full wave
5.3(d) PIV & Efficiency of Half wave
5.3(e) PIV & Efficiency of Full wave
5.4(a) Filters: circuit diagram and working of ‘L’, ‘C’
5.4(b) Filters: circuit diagram and working of ‘Pie' filter
5.5 Light Emitting Diodes: symbol, construction, working principle and applications.
6. Bipolar Junction Transistor
6.1 BJT: symbol, construction and working principle.
6.2(a) Transistor as Switch
6.2(b) Transistor as Amplifier
6.3 Input and Output characteristics: CE, CB and CC configurations
6.4 Operating regions: Cut-off, saturation and Active.
6.5 Transistor parameters: CB gain (alpha) CE gain (beta), input resistance. output resistance, relation between (alpha) and (beta).
Books / Notes PDF
Important Questions PDF
Lab Manual Answers PDF
External Pratical VIVA / Oral Practice Question PDF
MSBTE Diploma in Basic
Electrical & Electronics Engineering
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work is at the core of this field. It's like deciphering a map that leads
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- Diodes and Transistors: These tiny
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generated, transmitted, and distributed - it's like the lifeblood of our
modern world.
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