First Year Sem-1 MU NEP 2024 [ M1 – P1 – C1 – Mech – BEEE ]
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Course Overview
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[ Basic Electrical Engineering ] Module: Introduction
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[ Basic Electrical Engineering ] Module 01:- DC Circuits
- BEE introduction (voltage , current ,resistance ) (DC Circuits)
- How to add voltage ,current and resistance in series and parallel circuit (DC Circuits)
- Nodal analysis with solved example (DC Circuits)
- Nodal analysis of Supernode (DC Circuits)
- Thevenin theorem with solved examples (DC Circuits)
- Equivalent resistance problems with solved Examples (DC Circuits)
- Nortons theorem with solved examples (DC Circuits)
- Source Transformation with solved example (DC Circuits)
- Superposition Theorem with solved example (DC Circuits)
- Mesh analysis for SUPERMESH (DC Circuits)
- Mesh analysis best trick (DC Circuits)
- Star Delta Introduction (DC Circuits)
- Delta to star conversion (Easy trick ) Vice versa with solved example (DC Circuits)
- Numerical Of Star Delta (DC Circuits)
- Maximum power transfer theorem (DC Circuits)
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[ Basic Electrical Engineering ] Module 02:- AC Analysis & Three Phase
- A General Approach to solve an AC Circuit (AC Analysis)
- Introduction to AC (AC Analysis)
- Ways of Representing a Phasor (AC Analysis)
- Elements_R_L_C (AC Analysis)
- Series_RL_RC_Circuits (AC Analysis)
- Series RLC Circuit (AC Analysis)
- Parallel_RL_RC_RLC_Circuits (AC Analysis)
- Detailed Numerical on Series RL Circuit (AC Analysis)
- Detailed Numerical on Series RLC_Circuit (AC Analysis)
- PYQ on Series circuits (AC Analysis)
- Numericals on Parallel Circuits-1 (AC Analysis)
- Numericals on Parallel Circuits-2 (AC Analysis)
- Active,Reactive and Apparent Power-1 (AC Analysis)
- Active,Reactive and Apparent Power-2 (AC Analysis)
- Active,Reactive and Apparent Power-3 (AC Analysis)
- Calculation of Complex Power(Series Circuit) (AC Analysis)
- Calculation of Complex Power(Parallel Circuit) (AC Analysis)
- Admittance of Circuit (AC Analysis)
- Numerical using Admittance Method (AC Analysis)
- What is RESONANCE in AC Circuits (AC Analysis)
- Series Resonant Circuit-1 (AC Analysis)
- Series Resonant Circuit-2 (AC Analysis)
- Numerical on Series Resonant Circuit-1 (AC Analysis)
- Numerical on Series Resonant Circuit-2 (AC Analysis)
- Parallel Resonance-1 (AC Analysis)
- Parallel Resonance-2 (AC Analysis)
- What is Average Value (AC Analysis)
- What is RMS Value (AC Analysis)
- Numericals on Avg _ RMS Values-1 (AC Analysis)
- Numericals on Avg _ RMS Values-2 (AC Analysis)
- What is a 3-phase Electrical System (Three Phase)
- How 3-Phase POWER is Generated (Three Phase)
- Line and Phase Quantities (Three Phase)
- Single phase v_s Three Phase (Three Phase)
- Star Connection-1 (Three Phase)
- Star Connection-2 (Three Phase)
- Delta Connection (Three Phase)
- Power Calculation in 3_Phase_Circuits (Three Phase)
- Numerical on Star Configuration (Three Phase)
- Numerical on Delta Configuration (Three Phase)
- Star-Delta Transformation-1 (Three Phase)
- Star-Delta Transformation-2 (Three Phase)
- Star-Delta Transformation-3 (Three Phase)
- Numerical on Star-Delta Transformation (Three Phase)
- Application of Star-Delta Transformation-1 (Three Phase)
- Application of Star-Delta Transformation-2 (Three Phase)
- Basics of Power Measurement (Three Phase)
- Two Wattmeter Method-1 (Three Phase)
- Two Wattmeter Method-2 (Three Phase)
- Numericals on 2-Wattmeter Method-1 (Three Phase)
- Numericals on 2-Wattmeter Method-2 (Three Phase)
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[ Basic Electrical Engineering ] Module 03:- Single Phase Transformer
- Phasor Algebra (Transformer)
- Open circuit tests and short circuit tests (Transformer)
- Open circuit Tests and Short Circuit Tests Numerical Steps (Transformer)
- Wattmeter reading (Transformer)
- Open circuit Tests and Short Circuit Tests With percentage Of Efficiency And Regulation (Transformer)
- Wattmeter Type Two (Transformer)
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[ Basic Electrical Engineering ] Module 04:- Electric Machine (DC GENERATOR AND DC MOTOR)
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[ Basic Electrical Engineering ] Module 05:- Special Purpose Diode
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[ Basic Electrical Engineering ] Module 06:- Introduction to Transistors
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[ Basic Electrical Engineering ] Importance And Notes
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Engineering Mechanics
- Introduction to Engineering Mechanics
- Module 1: Introduction to System of Forces
- Module 1: How to represent Forces in Vector form (For Non-Coplanar Forces) – 01
- Module 1: How to represent Forces in Vector form (For Non-Coplanar Forces) – 02
- Module 1: Forces in Vector form (For Non-Coplanar Forces)
- Module 1: Resultant of Concurrent Forces using Parallelogram Law (Concurrent Forces)
- Module 1: Moment of Force about a Point
- Module 1: Moment of Force about a Point (Numerical 01)
- Module 1: Moment of Force about a Point (Numerical 02)
- Module 1: Moment of a Force across the Specified Line or Axis
- Module 1: Moment of a Force across the Specified Line or Axis (Numerical)
- Module 2: Introduction to Centroid and Centre of Gravity
- Module 2: Numerical on Centroid #1
- Module 2: Numerical on Centroid #2
- Module 3: Equilibrium of System of Coplanar Forces
- Module 3: Lamis theorem
- Module 3: Couple Force (Full Concept)
- Module 3: Equilibrium of rigid bodies with free body diagrams
- Module 3: Friction
- Module 3: Basic Concepts of Friction ( angle of friction and angle of repose)
- Module 3: Basic and Wedge Numerical
- Module 3: Wedge Numerical
- Module 3: Ladder Numerical
- Module 4: Rectilinear Motion – Numerical #1
- Module 4: Rectilinear Motion – Numerical #2
- Module 4: Rectilinear Numerical – #3
- Module 4: s-t & a-t Curve
- Module 4: Curvilinear Motion Numerical – #1
- Module 4: Curvilinear Motion Numerical – #2
- Module 4: Curvilinear Motion Numerical – #3
- Module 4: Curvilinear Motion Numerical – #4
- Module 5: Impulse Momentum – Coefficient Of Restitution Numerical – #1
- Module 5: D’Alembert Principle Numerical – #1
- Module 5: D’Alembert Principle Numerical – #2
- How To Pass Engineering Mechanics
- Module 01 – System Of Forces [Notes]
- Module 02 – Centroid [Notes]
- Module 03 – Equilibrium & Friction [Notes]
- Module 04 – Kinematics Of Particles & Rigid Bodies [Notes]
- Module 05 – Kinetics Of Particles [Notes]
- Module 06 – Introduction To Robot Kinematics [Notes]
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Engineering Maths 1
- Introduction to Complex Numbers (Module 1)
- De Moivre’s Theorem (Module 1)
- Expansions of sin nθ and cos nθ (Module 1)
- Expansions of Sinⁿ θ and Cosⁿ θ (Module 1)
- Roots of Complex Numbers (Module 1)
- Log of Complex Numbers (Module 1)
- Introduction To Numerical Solutions And Regula Falsi Method (Module 2)
- Newton-raphson Method (Module 2)
- Gauss-jacobi’s Iterative Method (Module 2)
- Gauss-seidel Iterative Method (Module 2)
- Taylor Series (Module 2)
- Maclaurin Series (Module 2)
- Hyperbolic Functions Part 1 (Module 3)
- Hyperbolic Functions Part 2 (Module 3)
- Hyperbolic Functions separation Of Real And Imaginary Parts (Module 3)
- Inverse Hyperbolic Functions (Module 3)
- Introduction of Partial Differentiation (Module 4)
- Example of Function of Function (Module 4)
- Variable Treated As Constant (Module 4)
- Composite Function (Module 4)
- Composite Function Example (Module 4)
- Implicit Function (Module 4)
- Homogeneous Function (Eulers Theorem) (Module 4)
- Reducible To Homogeneous Function (Euler’s Modified Theorem) (Module 4)
- Maxima and Minima (Module 4)
- Introduction to Successive Differentiation [Type1] (Module 5)
- Successive Differentiation [Type 2] (Module 5)
- Leibnitz Theorem (Module 5)
- Basics of Matrix (Module 6)
- Rank of Matrix by Normal Form (Module 6)
- PAQ (Module 6)
- Linear Dependence and Independence (Module 6)
- complex Numbers [IMP Solution & Practice Problem]
- Hyperbolic Functions [IMP Solution & Practice Problem]
- Partial Differentiation [IMP Solution & Practice Problem]
- Matrices [IMP Solution & Practice Problem]
- Successive differentiation [IMP Solution & Practice Problem]
- Numerical Solution [IMP Solution & Practice Problem]
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[Engineering Chemistry 1] Module 01- Fuels & Combustion
- Introduction to Fuels
- Knocking In Fuels
- Anti-Knocking In Fuels
- Gasoline & It’s Refining Steps
- Cracking Of Petroleum #1
- Cracking Of Petroleum #2
- Cracking Of Petroleum #3
- Refining Of Petroleum
- Bio-Diesel In Fuels
- Liquid Fuels
- Ultimate Analysis Numerical #1
- Ultimate Analysis Numerical #2
- Ultimate Analysis Numerical #3
- Cetane Number
- Combustion In Fuels Numerical
- HCV / LCV / GCV / NCV In Fuels
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[Engineering Chemistry 1] Module 02: Corrosion
- Dry Corrosion #1
- Dry Corrosion #2
- Wet Corrosion #1
- Wet Corrosion #2
- Different Types Of Corrosion #1
- Different Types Of Corrosion #2
- Different Types Of Corrosion #3
- Factors Affecting Corrosion
- Prevention & Control Of Corrosion #1
- Prevention & Control Of Corrosion #2
- Prevention & Control Of Corrosion #3
- Prevention & Control Of Corrosion #4
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[Engineering Chemistry 1] Module 03 - Alloys
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[Engineering Chemistry 1] Module 04 - Introduction To Polymers
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[Engineering Chemistry 1] Module 06 - Green Chemistry
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[Engineering Chemistry 1] Importance And Notes
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Engineering Physics 1
- 1.1 Spontaneous Emission (Module 1)
- 1.2 Stimulated Emission (Module 1)
- 1.3 Population Inversion (Module 1)
- 1.4 Pumping (Module 1)
- 1.5 Resonant cavity,Active medium and active center (Module 1)
- 1.6 Coherence length, coherence time and characteristics of lasers (Module 1)
- 1.7 He-Ne laser (Module 1)
- 1.8 Fiber Laser (Module 1)
- 1.9 Application of Laser (Module 1)
- 2.1 Optical Fibre (Module 2)
- 2.2 Types of Fibers (Module 2)
- 2.3 Acceptance angle and Numerical aperture (Module 2)
- 2.4 Attenuation and fibre optic communication system (Module 2)
- 2.5 Numerical (Module 2)
- 2.6 Numerical (Module 2)
- 2.7 Numerical (Module 2)
- 3.1 Thin film (Module 3)
- 3.2 Interference in Thin Film Derivation (Module 3)
- 3.3 Newton rings (Module 3)
- 3.4 Newton ring to determine refractive index of liquid (Module 3)
- 3.5 Anti reflecting film (Module 3)
- 4.1 Introduction to Electrodynamics (Module 4)
- 4.2 Gradient (Module 4)
- 4.3 Divergence (Module 4)
- 4.4 Curl (Module 4)
- 4.5 Gauss’s law (Module 4)
- 4.6 Ampere circuital law (Module 4)
- 4.7 Faraday Law (Module 4)
- 4.8 Divergence Theorem (Module 4)
- 4.9 Stokes Theorem (Module 4)
- 4.10 Maxwell Equation in point form (Module 4)
- 4.11 Maxwell Equation in integral form (Module 4)
- 4.12 Physical significance of maxwell equations (Module 4)
- 5.1 De Broglie Hypothesis of Matter Waves (Module 5)
- 5.2 De Broglie Wavelength for Electrons (Module 5)
- 5.3 Properties of Matter Waves (Module 5)
- 5.4 Wave Function (Module 5)
- 5.5 Uncertainty principle (Module 5)
- 5.6 Phase, Group velocity and Significance of Schrödinger equation (Module 5)
- 6.1 Semiconductor- Introduction (Module 6)
- 6.2 Direct and Indirect Band Semiconductor (Module 6)
- 6.3 Intrensic and Extrensic Semiconductor (Module 6)
- 6.4 Electrical Conductivity of semiconductors (Module 6)
- 6.5 Drift velocity and Mobility and Conductivity in Conductors (Module 6)
- 6.6 Fermi Dirac Distribution Function (Module 6)
- 6.7 Fermi Level (Module 6)
- 6.8 Types of semiconductors (Module 6)
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Engineering Physics 1 Notes
