First Year Full Course
₹1,999.00
₹999.00
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Basic Electrical Engineering
- Basic Electrical And Electronics Introduction (Module 1)
- BEE introduction (voltage , current ,resistance ) (Module 2)
- How to add voltage ,current and resistance in series and parallel circuit (Module 2)
- Nodal analysis with solved example (Module 2)
- Nodal analysis of Supernode (Module 2)
- Thevenin theorem with solved examples (Module 2)
- Equivalent resistance problems with solved Examples (Module 2)
- Nortons theorem with solved examples (Module 2)
- Superposition Theorem with solved example (Module 2)
- Source Transformation with solved example (Module 2)
- Superposition Theorem with solved example (part 2 ) (Module 2)
- Mesh analysis for SUPERMESH (Module 2)
- Mesh analysis best trick (Module 2)
- Star Delta Introduction (Module 2)
- Delta to star conversion (Easy trick ) Vice versa with solved example (Module 2)
- Numerical Of Star Delta (Module 2)
- Maximum power transfer theorem (Module 2)
- Alternating current full basics (Module 3)
- AC Circuit (Module 3)
- AC Terminology Sums (Module 3)
- AC Circuit Numerical (Module 3)
- Average Value Sums (Module 3)
- RC Circuit (Module 3)
- RLC Circuit Numerical (Module 3)
- RMS value numerical (Module 3)
- Peak, Average,RMS Values Of Current & Voltage (Module 3)
- Phasor Algebra (Module 4)
- Open circuit tests and short circuit tests (Module 4)
- Open circuit Tests and Short Circuit Tests Numerical Steps (Module 4)
- Wattmeter reading (Module 4)
- Open circuit Tests and Short Circuit Tests With percentage Of Efficiency And Regulation (Module 4)
- Wattmeter Type Two (Module 4)
- DC Motor (Module 5)
- EMF Equation of Generator (Module 5)
- Types of DC Motor (Module 5)
- Torque Equation of a DC motor (Module 5)
- DC series Motor (Module 5)
- How To Pass BEEE (Basic Electrical Engineering)
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Engineering Mechanics
- Introduction to Engineering Mechanics (Module 1)
- Introduction to Coplanar forces (Module 2)
- Resultant of General Forces (Module 2)
- Resultant of Concurrent Forces using Parallelogram law (Module 2)
- Resultant of Parallel System (Module 2)
- Resultant of Concurrent System using Method of Resolution (Module 2)
- Equilibrium in Coplanar Forces (Module 3)
- Lamis theorem (Equilibrium of Forces) (Module 3)
- Couple Full Concept in Mechanics (Module 3)
- Equilibrium of Connected Bodies with Solved Examples (Module 3)
- Introduction to Trusses with solved example (Module 4)
- Truss | Method of Section Explained with solved example (Module 4)
- Truss | Method of Section with solved example| part 2 | (Module 4)
- Method of Joints Explained | Analysis of Truss | (Module 4)
- Friction Full Basic Concept (Module 5)
- Angle of Friction and Angle of Repose (Module 5)
- Friction Solved Problem (Module 5)
- Ladder Friction Sums (Module 5)
- Ladder Solved Example (Module 5)
- Wedges Problems in Friction (Module 5)
- Centroid and Centre of Gravity Solve Example (Module 6)
- Introduction to Centroid Full Basics with solve example (Module 6)
- Centroid and Centre of Gravity Solve Example | Part 2 | (Module 6)
- Forces in Space with Solved Example (Module 7)
- Forces of Space problems solved (Module 7)
- Magnitude of Force and Direction with Solved Example (Module 7)
- Moment of a Force about a Point (Module 7)
- Moment of a force across the Specified axis or Line (Module 7)
- Moment of a force across the Specified axis or Line |part 2 | (Module 7)
- Moment of Force about a Point with Solved Example Part-1 (Module 7)
- Moment of Force about a Point with Solved Example Part-2 (Module 7)
- How To Pass Engineering Mechanics
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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)
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Engineering Chemistry 1
- Concept of Atomic Orbitals (Module 1)
- Aromatic Compound and its Characteristics (Module 2)
- Huckel Rule (Module 2)
- Molecular Orbital Structure of Benzene (Module 2)
- Intermolecular Forces and Critical Phenom (Module 3)
- Ionic Interactions (Module 3)
- Effect of Hydrogen Bonding (Module 3)
- Intermolecular Forces And Types(dipole-dipole, ion-dipole interaction) (Module 3)
- Dipole-Dipole Interaction (Module 3)
- Gibbs Phase Rule (Module 4)
- One Component System (Module 4)
- Two Component System (Module 4)
- Polymers Introduction (Module 5)
- Polymerization (Module 5)
- Compression and Injection Moulding Part #1 (Module 5)
- Compression and Injection Moulding Part #2 (Module 5)
- Extrusion and Transfer (Module 5)
- Glass Transition Temperature (Module 5)
- BOD and COD With Numerical (Module 6)
- Ion Exchange Process with Numerical (Module 6)
- Zeolite Part #1 (Module 6)
- Zeolite Part #2 (Module 6)
- Normal Hardness Numerical (Module 6)
- EDTA Numerical Part #1 (Module 6)
- EDTA Numerical Part #2 (Module 6)
- Engineering Chemistry 1 Importance
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Engineering Physics 1
- De Broglie’s Hypothesis (Module 1)
- Davisson and Germer (Module 1)
- Heisenberg’s Uncertainty Principle Part #1 (Module 1)
- Heisenberg’s Uncertainty Principle Part #2 (Module 1)
- Schrodinger Equation (Module 1)
- Wave Functions (Module 1)
- Quantam Computing (Module 1)
- Diamond Crystal structure (Module 2)
- Sodium Chloride (NaCl) (Module 2)
- HCP Crystal Structure (Module 2)
- Crystal Structure Numerical (Module 2)
- Braggs Spectrometer Part #1 (Module 2)
- Braggs Spectrometer Part #2 (Module 2)
- Sums of vacancy point defect Crystal (Module 2)
- Ligancy (Module 2)
- Fermi energy in conductors (Module 3)
- Fermi level in intrinsic semi conductors (Module 3)
- Hall Coefficient (Module 3)
- Drift Current and Mobility (Module 3)
- PN Junction Diode (Module 3)
- PN Junction Diode Numerical (Module 3)
- Photovoltaic Cell Part #1 (Module 3)
- Photovoltaic Cell Part #2 (Module 3)
- Curvature of Lens And Optical Flatness (Module 4)
- Determination of Thickness Of Very Thin Foil (Module 4)
- Determination of Thickness Of Very Thin Foil in Reflected System (Module 4)
- Refractive Index (Module 4)
- Superconductivity Part #1 (Module 5)
- Superconductivity Part #2 (Module 5)
- Superconductivity Part #3 (Module 5)
- Hysteresis curve and Loss (Module 5)
- Meissner Effect (Module 5)
- Diamagnetic (Module 5)
- Soft magnet material vs Hard magnet material (Module 5)
- Supercapacitors (Module 5)
- Introduction to Ultrasonic (Module 6)
- Magnetostriction effect and its working (Module 6)
- Piezoelectric Effect and How it Works (Module 6)
- Magnetostriction Oscillator (Module 6)
- Piezoelectric Oscillator (Module 6)
- Acoustics Basics Part #1 (Module 7)
- Acoustics Basics Part #2 (Module 7)
- Acoustics Basics Part #3 (Module 7)
- Condition for good Acoustics (Module 7)
- Condition for good Acoustics – II (Module 7)
- Method to design good Acoustics (Module 7)