| Year & Semester | Course Name | Course Code | Course Objectives (COs) |
|---|---|---|---|
| I Year | English | EE101 |
EE101.1: Recall and reproduce the theme in a given context. EE101.2: Interpret the contextual meaning of words. EE101.3: Appraise renowned personalities through biographies and identify contributions. EE101.4: Examine content and comprehend the writer's opinion. EE101.5: Express views with proper justification. EE101.6: Develop coherent and cohesive technical reports. |
| I Year | Mathematics - I | EE102 |
EE102.1: Test convergence of series using D'Alembert's and Raabe's tests. EE102.2: Interpret applications of Mean Value Theorems. EE102.3: Evaluate multiple integrals and calculate area and volume. EE102.4: Solve differential equations and engineering applications. EE102.5: Apply Laplace Transforms to solve ODEs. EE102.6: Demonstrate vector differentiation and integration applications. |
| I Year | Mathematics - II | EE103 |
EE103.1: Determine rank, echelon form, eigenvalues and eigenvectors. EE103.2: Solve linear systems and diagonalize matrices. EE103.3: Solve algebraic, transcendental and differential equations. EE103.4: Construct curves and calculate derivatives and integrals. EE103.5: Construct Fourier series for periodic functions. EE103.6: Build and solve partial differential equations. |
| I Year | Applied Physics | EE104 |
EE104.1: Classify bonding types in solids and their properties. EE104.2: Analyze crystal structures using X-Ray diffraction. EE104.3: Compare particle properties and solve wave functions. EE104.4: Distinguish semiconductor devices and properties. EE104.5: Select dielectric and magnetic materials based on properties. EE104.6: Apply optics in fiber cables and explain nanomaterials and acoustics. |
| I Year | Chemistry | EE105 |
EE105.1: Explain conductance, electrodes, corrosion and EMF calculations. EE105.2: Identify corrosion prevention methods. EE105.3: Compare properties of polymers. EE105.4: Identify boiler troubles and water treatment methods. EE105.5: Explain energy sources and calorific value calculations. EE105.6: Elaborate alloy formation and adsorption concepts. |
| I Year | Engineering Graphics | EE106 |
EE106.1: Construct engineering curves and scales. EE106.2: Draw projections of points, lines and planes. EE106.3: Construct projections and sections of solids. EE106.4: Draw intersections and penetrations of solids. EE106.5: Convert orthographic and isometric views. EE106.6: Develop surfaces of solids. EE106.7: Draw perspective projections. |
| I Year | Programming for Problem Solving | EE107 |
EE107.1: Demonstrate computer systems and program development. EE107.2: Design algorithms and programs using control structures. EE107.3: Develop programs using functions and arrays. EE107.4: Use pointers and string processing. EE107.5: Organize heterogeneous data and files. EE107.6: Implement linear data structures. |
| I Year | Programming for Problem Solving Lab | EE108 |
EE108.1: Design algorithms, flowcharts and pseudocode. EE108.2: Develop C programs using control structures. EE108.3: Develop C programs using functions and arrays. EE108.4: Manage memory and process strings in C. EE108.5: Process files and heterogeneous data. EE108.6: Implement linear data structures in C. |
| I Year | Applied Physics Lab | EE109 |
EE109.1: Analyze properties of light and related parameters. EE109.2: Build electronic circuits using suitable components. EE109.3: Use modern instruments for solution analysis. EE109.4: Determine equivalence points in titrations. EE109.5: Interpret data and draw conclusions from graphs. |
| I Year | English Language and Communication Skills Lab | EE110 |
EE110.1: Adopt active listening skills. EE110.2: Acquire standard pronunciation. EE110.3: Develop effective reading skills. EE110.4: Communicate confidently with fluency and accuracy. EE110.5: Compose concise, clear and coherent write-ups. |
| I-I (Common) | Basic Electrical Engineering | EE104ES |
CO1: Introduce electrical circuits and components. CO2: Understand magnetic circuits, DC and AC circuits. CO3: Study transformers. CO4: Study DC and AC machines. CO5: Introduce switches and batteries. |
| I-I (Common) | Basic Electrical Engineering Lab | EE109ES |
CO1: Understand circuit laws and network theorems. CO2: Measure voltage, current, power and impedance. CO3: Study transformers and electrical machines. CO4: Verify three-phase circuits and transformer connections. CO5: Analyze circuit and machine performance experimentally. |
| I-I | Electrical Circuits – I | EE104ES |
CO1: Understand network elements and circuit laws. CO2: Analyze single-phase AC circuits. CO3: Analyze balanced and unbalanced three-phase circuits. CO4: Apply network theorems. CO5: Understand magnetic coupled circuits. |
| I-II | Electrical Circuits – II | EE205ES |
CO1: Analyze transient behavior of RL, RC and RLC circuits. CO2: Apply Laplace transforms. CO3: Understand network topology concepts. CO4: Analyze two-port networks. CO5: Understand electrical filters. |
| I-II | Electrical Circuits Lab | EE209ES |
CO1: Simulate electrical circuits using LT Spice. CO2: Verify resonance and network theorems. CO3: Study two-port network parameters. CO4: Analyze three-phase power measurements. CO5: Study coupled circuits and filters. |
| II-I | Electromagnetic Fields | EE301PC |
CO1: Apply mathematical techniques to EM fields. CO2: Apply EM theory to devices. CO3: Design electrodynamic systems. CO4: Gain experience in EM measurements. CO5: Appreciate engineering applications. |
| II-I | Electrical Machines – I | EE302PC |
CO1: Understand DC generators. CO2: Compare DC motor characteristics. CO3: Test DC machines. CO4: Study single-phase transformers. CO5: Determine transformer efficiency and regulation. |
| II-I | Power Systems – I | EE304PC |
CO1: Learn conventional power generation methods. CO2: Understand hydro power plants. CO3: Study distribution systems. CO4: Learn substation layouts and equipment. CO5: Analyze power generation economics. |
| II-II | Electrical Machines – II | EE402PC |
CO1: Understand induction motors. CO2: Analyze synchronous machines. CO3: Study parallel operation of alternators. CO4: Learn speed control methods. CO5: Study special AC motors. |
| II-II | Power Systems – II | EE403PC |
CO1: Design insulators for transmission lines. CO2: Understand cable construction and grading. CO3: Examine AC/DC distribution systems. CO4: Analyze traveling waves and line sag. CO5: Compare AIS and GIS substations. |
| II-II | Control Systems | EE405PC |
CO1: Learn control system principles. CO2: Study transfer functions and time response. CO3: Analyze stability methods. CO4: Assess time-domain performance. CO5: Assess frequency-domain performance. |
| III-I | Power Electronics | EE501PC |
CO1: Understand semiconductor devices. CO2: Apply thyristor triggering techniques. CO3: Analyze AC-DC converters. CO4: Analyze DC-DC converters. CO5: Evaluate inverters and AC controllers. |
| III-II | Power System Protection | EE602PC |
CO1: Understand circuit breakers. CO2: Design protection schemes. CO3: Learn protection coordination. CO4: Study surge protection. CO5: Evaluate protection systems. |
| IV-I | Power Electronic Applications to Renewable Energy Systems | EE701PC |
CO1: Understand renewable energy systems. CO2: Analyze solar and wind converters. CO3: Design renewable energy control strategies. CO4: Evaluate storage and grid integration. CO5: Apply simulation tools. |
| IV-II | Electrical Distribution Systems | EE862PE |
CO1: Automate distribution systems. CO2: Design feeder systems. CO3: Determine substation locations. CO4: Analyze distribution systems. CO5: Evaluate reliability and automation. |
| IV-II | Project Stage-II Including Seminar | EE801PC |
CO1: Solve real-world engineering problems. CO2: Develop teamwork and communication skills. CO3: Analyze project outcomes. CO4: Present technical reports and seminars. CO5: Demonstrate professional ethics and lifelong learning. |

