.png&w=1920&q=75)
B-TECH in Electrical And Electronics Engineering at School of Technology and Applied Sciences, Mahatma Gandhi University
Kottayam, Kerala
.png&w=1920&q=75)
About the Specialization
What is Electrical and Electronics Engineering at School of Technology and Applied Sciences, Mahatma Gandhi University Kottayam?
This Electrical and Electronics Engineering program at School of Technology and Applied Sciences, Mahatma Gandhi University focuses on developing robust foundational and advanced skills in power systems, control systems, electronics, and instrumentation. It is designed to meet the evolving demands of the Indian energy sector and emerging smart technologies, integrating theoretical knowledge with practical applications relevant to modern industry. The curriculum emphasizes both traditional and renewable energy sources, smart grids, and automation.
Who Should Apply?
This program is ideal for fresh graduates with a strong aptitude for physics and mathematics seeking entry into core engineering domains. It also caters to aspiring professionals interested in power generation, distribution, industrial automation, and embedded systems. Students from diverse backgrounds who possess analytical thinking and problem-solving skills will thrive, with a keen interest in contributing to India''''s technological and energy infrastructure.
Why Choose This Course?
Graduates of this program can expect diverse career paths in power generation companies, manufacturing industries, automation firms, and public sector undertakings across India. Entry-level salaries typically range from INR 4-7 lakhs per annum, with significant growth trajectories for experienced engineers (INR 8-20+ lakhs). Opportunities extend to roles in design, research, project management, and entrepreneurship, aligning with certifications from professional bodies like IEI or skill development programs.
Student Success Practices
Foundation Stage
Strengthen Core Math and Science Fundamentals- (Semester 1-2)
Dedicate consistent time to master concepts in Applied Linear Algebra, Calculus, Physics, and Chemistry. Utilize online platforms like Khan Academy and NPTEL for supplementary learning and problem-solving. Form study groups to discuss complex topics and practice regularly with past year question papers to build a strong academic base.
Tools & Resources
Khan Academy, NPTEL, University Library Resources, Peer Study Groups
Career Connection
A solid grasp of fundamentals is crucial for understanding advanced engineering subjects and excelling in technical interviews and competitive exams for core engineering roles.
Develop Early Programming Skills (C/Python)- (Semester 1-2)
Actively participate in the Introduction to Computing and Problem Solving course and its lab. Practice coding challenges on platforms like HackerRank and CodeChef using C or Python. Understanding basic algorithms and data structures will be invaluable for future embedded systems and automation courses.
Tools & Resources
HackerRank, CodeChef, GeeksforGeeks, Local Programming Clubs
Career Connection
Proficiency in programming is increasingly vital for EEE engineers in automation, data analysis, and IoT roles, enhancing employability in tech-driven industries.
Engage in Basic Workshop and Lab Activities- (Semester 1-2)
Pay close attention during Electrical & Electronics and Civil & Mechanical workshop sessions. Hands-on experience with tools, circuit building, and basic mechanical fabrication fosters practical engineering intuition. Document all lab work meticulously to reinforce learning and prepare for advanced practical courses.
Tools & Resources
Departmental Labs, Workshop Manuals, Online Simulation Tools (e.g., TinkerCAD for basic circuits)
Career Connection
Early practical exposure improves troubleshooting skills and provides confidence for mini-projects and internships, which are key for securing roles in manufacturing and R&D.
Intermediate Stage
Build Practical Skills through Simulation and Projects- (Semester 3-5)
Beyond theoretical courses like Power Electronics and Control Systems, actively use simulation software (e.g., MATLAB/Simulink, PSIM, LTSpice) to model and analyze circuits. Seek out faculty-mentored mini-projects to apply knowledge and gain hands-on design and implementation experience in areas like embedded systems or power electronics.
Tools & Resources
MATLAB/Simulink, PSIM/LTSpice, Arduino/Raspberry Pi kits, Departmental Project Labs
Career Connection
Demonstrating practical project experience and simulation proficiency is highly valued by recruiters for internships and entry-level engineering positions in R&D and design.
Participate in Technical Competitions and Workshops- (Semester 3-5)
Join departmental technical clubs (e.g., IEEE Student Chapter) and actively participate in inter-college technical competitions (robotics, circuit design, hackathons) and workshops. This exposure enhances problem-solving, teamwork, and introduces students to emerging technologies and industry trends.
Tools & Resources
IEEE Student Branch, Technical Fests, Industry-led Workshops, Online MOOCs
Career Connection
Participation in such events showcases initiative, practical skills, and a competitive spirit, making profiles attractive for diverse engineering roles, including those in automation and core EEE.
Explore Electives Strategically for Specialization- (Semester 5)
Carefully choose electives in areas like Artificial Intelligence, Renewable Energy Systems, or Smart Grid based on emerging industry trends and personal career interests. Research the syllabus for each elective thoroughly and consider how it aligns with your desired specialization for future job roles.
Tools & Resources
Departmental Elective Guides, Career Counseling Cells, Industry Journals and Reports
Career Connection
Strategic elective choices allow for early specialization, making students more competitive for niche roles in high-demand areas like renewable energy, IoT, or advanced control systems in India.
Advanced Stage
Focus on Industry-Relevant Final Year Project- (Semester 7-8)
Select a final year project that addresses a real-world problem or utilizes advanced technologies (e.g., IoT, ML in power systems, EV charging solutions). Collaborate with industry experts or research labs if possible. Document the project meticulously and prepare for robust presentations and demonstrations.
Tools & Resources
Access to Research Papers, Industry Mentors, Advanced Simulation Software, Fabrication Facilities
Career Connection
A strong final year project is a powerful resume booster, showcasing deep technical knowledge, research capabilities, and problem-solving skills highly sought after by recruiters for advanced engineering roles.
Intensive Placement and Interview Preparation- (Semester 7-8)
Engage in rigorous aptitude training, technical interview preparation focusing on core EEE subjects, and soft skills development. Practice mock interviews with faculty and seniors. Prepare a compelling resume highlighting projects, internships, and skill sets. Attend campus recruitment drives actively.
Tools & Resources
Career Services Cell, Online Aptitude Portals, Interview Preparation Books, Mock Interview Panels
Career Connection
Thorough preparation directly impacts placement success, leading to offers from top core engineering companies, IT firms, and public sector organizations in India.
Network Professionally and Explore Higher Studies/Entrepreneurship- (Semester 7-8)
Attend industry seminars, conferences, and alumni meets to build a professional network. Explore options for higher studies (M.Tech/MS) in specialized fields or entrepreneurial ventures related to EEE. Seek guidance from faculty on competitive exams like GATE for postgraduate admissions or public sector jobs.
Tools & Resources
LinkedIn, Professional Conferences, Alumni Network, GATE Coaching Centers, Startup Incubators
Career Connection
Networking opens doors to advanced career opportunities, research positions, or enables the pursuit of innovative startup ideas, contributing to India''''s technological ecosystem.
Program Structure and Curriculum
Eligibility:
- No eligibility criteria specified
Duration: 8 semesters / 4 years
Credits: 150 Credits
Assessment: Internal: 40%, External: 60%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTCH101 | Applied Linear Algebra and Calculus | Core | 4 | Matrices and Linear Transformations, Eigenvalues and Eigenvectors, Partial Differentiation and Applications, Vector Calculus and Theorems, Multiple Integrals |
| BTCH102 | Engineering Physics | Core | 3 | Wave Optics and Interference, Lasers and Fiber Optics, Quantum Mechanics and Applications, Superconductivity, Nanomaterials |
| BTCH103 | Engineering Chemistry | Core | 3 | Electrochemistry and Cells, Corrosion and its Control, Water Treatment Technology, Polymer Chemistry, Fuel Technology |
| BTCH104 | Engineering Graphics | Core | 3 | Orthographic Projections, Isometric Projections, Sections of Solids, Development of Surfaces, Perspective Projections |
| BTCH105 | Introduction to Computing and Problem Solving | Core | 3 | Introduction to Programming, Data Types and Operators, Control Structures, Functions and Arrays, Pointers and Strings |
| BTCH106 | Engineering Physics Lab | Lab | 1 | Measurement of Wavelength, Determination of Refractive Index, Hall Effect Experiment, Semiconductor Diode Characteristics, Photoelectric Effect |
| BTCH107 | Engineering Chemistry Lab | Lab | 1 | Volumetric Analysis, Potentiometric Titration, pH Metry, Hardness of Water Determination, Conductometric Titration |
| BTCH108 | Computer Programming Lab | Lab | 2 | C Programming Fundamentals, Conditional Statements and Loops, Functions and Arrays, Structures and Pointers, File Operations |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTCH201 | Differential Equations | Core | 4 | First Order Differential Equations, Higher Order Linear ODEs, Laplace Transforms, Fourier Series, Partial Differential Equations |
| BTCH202 | Engineering Mechanics | Core | 3 | Statics of Particles and Rigid Bodies, Equilibrium Equations, Friction and its Applications, Centroids and Moments of Inertia, Dynamics of Particles |
| BTCH203 | Basic Electrical and Electronics Engineering | Core | 3 | DC Circuits and Network Theorems, AC Circuits and Phasors, Single-Phase Transformers, Semiconductor Diodes, Bipolar Junction Transistors |
| BTCH204 | Basic Civil and Mechanical Engineering | Core | 3 | Building Materials and Construction, Surveying and Leveling, Thermodynamics Laws, Internal Combustion Engines, Refrigeration and Air Conditioning |
| BTCH205 | Engineering Design | Core | 3 | Design Process and Thinking, Engineering Materials Selection, Safety and Ergonomics in Design, Sustainable Design Principles, Product Lifecycle Management |
| BTCH206 | Basic Electrical & Electronics Engineering Lab | Lab | 1 | Verification of Ohm''''s Law, Kirchhoff''''s Laws Verification, RC and RL Circuits, Diode Characteristics, Transistor Amplifier Circuits |
| BTCH207 | Basic Civil & Mechanical Engineering Workshop | Lab | 1 | Carpentry and Joinery, Fitting Operations, Welding Techniques, Plumbing Practice, Sheet Metal Work |
| BTCH208 | Professional Communication | Core | 2 | Technical Report Writing, Oral Presentation Skills, Group Discussion Techniques, Interview Skills, Business Correspondence |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTEEE301 | Engineering Mathematics III | Core | 4 | Complex Numbers and Functions, Complex Integration, Probability Distributions, Sampling and Estimation, Linear Programming |
| BTEEE302 | Electrical Circuit Analysis | Core | 4 | Network Theorems, Transient Analysis of RLC Circuits, AC Circuit Analysis, Resonance and Coupled Circuits, Two-Port Networks |
| BTEEE303 | Analog Electronic Circuits | Core | 4 | Diode Rectifiers and Filters, Transistor Biasing and Amplifiers, Frequency Response of Amplifiers, Feedback Amplifiers and Oscillators, Operational Amplifiers |
| BTEEE304 | Digital Electronics | Core | 4 | Boolean Algebra and Logic Gates, Combinational Logic Circuits, Sequential Logic Circuits, Registers and Counters, Memory Devices |
| BTEEE305 | Electrical Machines I | Core | 4 | DC Generators and Motors, Transformers (Single and Three Phase), Three-Phase Induction Motors, Synchronous Generators, Special Electrical Machines |
| BTEEE306 | Electrical & Electronics Lab | Lab | 2 | Network Theorem Verification, Transient Response of RLC Circuits, Diode and Zener Characteristics, Transistor Amplifier Studies, Logic Gate Implementation |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTEEE401 | Signals and Systems | Core | 4 | Classification of Signals and Systems, Linear Time-Invariant Systems, Fourier Series and Transform, Laplace Transform and Applications, Z-Transform and Discrete-Time Systems |
| BTEEE402 | Electrical Measurements and Instrumentation | Core | 4 | Measurement of Resistance, Inductance, Capacitance, AC and DC Bridges, Transducers and Sensors, Data Acquisition Systems, Digital Instruments |
| BTEEE403 | Power Electronics | Core | 4 | Power Semiconductor Devices (SCR, MOSFET, IGBT), Controlled Rectifiers (Converters), DC to DC Converters (Choppers), DC to AC Converters (Inverters), AC Voltage Controllers and Cycloconverters |
| BTEEE404 | Microprocessors and Microcontrollers | Core | 4 | 8085 Microprocessor Architecture, 8085 Instruction Set and Programming, Interfacing Memory and I/O Devices, 8051 Microcontroller Architecture, 8051 Assembly Language Programming |
| BTEEE405 | Control Systems | Core | 4 | System Modeling and Transfer Functions, Block Diagram and Signal Flow Graph, Time Domain Analysis of Control Systems, Stability Analysis (Routh-Hurwitz, Root Locus), Frequency Domain Analysis (Bode Plot, Nyquist Plot) |
| BTEEE406 | Electrical Measurements and Digital Electronics Lab | Lab | 2 | Measurement of R, L, C using Bridges, Characteristics of Transducers, Basic Logic Gates Realization, Combinational Circuit Design, Sequential Circuit Implementation |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTEEE501 | Power Systems I | Core | 4 | Power Generation Methods, Transmission Line Parameters, Per Unit System, Distribution Systems, HVDC Transmission |
| BTEEE502 | Electric Drives | Core | 4 | Dynamics of Electric Drives, DC Motor Drives, AC Motor Drives (Induction & Synchronous), Control of Electric Drives, Industrial Applications of Drives |
| BTEEE503 | Electromagnetic Field Theory | Core | 4 | Vector Calculus and Coordinate Systems, Electrostatic Fields, Magnetostatic Fields, Maxwell''''s Equations, Electromagnetic Wave Propagation |
| BTEEE504 | Professional Ethics | Core | 3 | Engineering Ethics Principles, Moral Values and Theories, Professional Responsibility, Rights of Engineers, Global Ethical Issues |
| BTEEE505.1 | Artificial Intelligence | Elective | 3 | Introduction to AI, Problem Solving by Search, Knowledge Representation, Machine Learning Concepts, Neural Networks |
| BTEEE505.2 | Power Plant Engineering | Elective | 3 | Thermal Power Plants, Hydroelectric Power Plants, Nuclear Power Plants, Diesel Power Plants, Gas Turbine Power Plants |
| BTEEE505.3 | High Voltage DC Transmission | Elective | 3 | Introduction to HVDC Systems, HVDC Converters, Control of HVDC Systems, Harmonics and Filters, Reactive Power Control |
| BTEEE506 | Power Electronics and Control Systems Lab | Lab | 2 | Characteristics of SCR and MOSFET, Controlled Rectifier Circuits, DC-DC Converter Experiments, Open Loop and Closed Loop Control, PID Controller Tuning |
| BTEEE507 | Mini Project | Project | 2 | Problem Identification, Literature Review, Design and Simulation, Hardware/Software Implementation, Report Writing and Presentation |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTEEE601 | Power Systems II | Core | 4 | Load Flow Analysis, Fault Analysis in Power Systems, Power System Stability, Protection of Generators and Transformers, Circuit Breakers and Relays |
| BTEEE602 | High Voltage Engineering | Core | 4 | Conduction and Breakdown in Gases, Conduction and Breakdown in Liquid/Solid Dielectrics, Generation of High Voltages, Measurement of High Voltages and Currents, Insulators and Lightning Arresters |
| BTEEE603 | Advanced Control Systems | Core | 4 | State Space Analysis, Controllability and Observability, Digital Control Systems, Non-Linear Control Systems, Optimal Control Theory |
| BTEEE604 | Professional Practice | Core | 3 | Project Management Techniques, Contracts and Legal Aspects, Safety Management in Industry, Intellectual Property Rights, Entrepreneurship Development |
| BTEEE605.1 | Renewable Energy Systems | Elective | 3 | Solar Photovoltaic Systems, Wind Energy Conversion Systems, Hydroelectric Power Generation, Biomass and Geothermal Energy, Grid Integration of Renewables |
| BTEEE605.2 | Electrical System Design | Elective | 3 | Design of Lighting Systems, Design of Earthing Systems, Industrial Wiring Design, Substation Layout Design, Protection System Design |
| BTEEE605.3 | Special Electrical Machines | Elective | 3 | Stepper Motors, Switched Reluctance Motors, Permanent Magnet Synchronous Motors, Brushless DC Motors, Linear Induction Motors |
| BTEEE606 | Power Systems Lab | Lab | 2 | Transmission Line Parameter Measurement, Fault Analysis Experiments, Characteristics of Overcurrent Relays, Load Flow Studies using Software, Power Factor Improvement |
| BTEEE607 | Microprocessor & Microcontroller Lab | Lab | 2 | 8085 Assembly Language Programs, Interfacing with 8085, 8051 Microcontroller Programming, ADC and DAC Interfacing, Motor Control using Microcontroller |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTEEE701 | Design of Electrical Machines | Core | 4 | General Design Principles, Design of Transformers, Design of DC Machines, Design of Induction Motors, Design of Synchronous Machines |
| BTEEE702 | Electric Vehicles | Core | 4 | EV Architectures and Components, Electric Drive Train Systems, Energy Storage Systems (Batteries, Fuel Cells), Charging Infrastructure and Standards, Hybrid Electric Vehicle Concepts |
| BTEEE703.1 | Smart Grid | Elective | 3 | Smart Grid Architecture, Advanced Metering Infrastructure (AMI), Renewable Energy Integration, Demand Side Management, Cyber Security in Smart Grid |
| BTEEE703.2 | Electrical Machine Design | Elective | 3 | Design Considerations, Design of Transformers, Design of DC Machines, Design of Induction Machines, Design of Synchronous Machines |
| BTEEE703.3 | Advanced Power Electronics | Elective | 3 | Multilevel Inverters, Resonant Converters, Matrix Converters, Power Quality Improvement, Applications of Power Electronics |
| BTEEE704.1 | VLSI Design | Elective | 3 | CMOS Technology and Fabrication, MOSFET Characteristics, Combinational and Sequential Logic Design, VLSI Testing and Verification, FPGA Architectures |
| BTEEE704.2 | Computer Networks | Elective | 3 | Network Topologies, OSI and TCP/IP Models, Data Link Layer Protocols, Network Layer Protocols, Transport and Application Layers |
| BTEEE704.3 | Digital Signal Processing | Elective | 3 | Discrete-Time Signals and Systems, Z-Transform and DTFT, Discrete Fourier Transform (DFT), Fast Fourier Transform (FFT), FIR and IIR Filter Design |
| BTEEE705 | Power Systems Simulation Lab | Lab | 2 | MATLAB/Simulink Basics, Load Flow Studies Simulation, Fault Analysis Simulation, Stability Studies Simulation, Power Quality Analysis Tools |
| BTEEE706 | Project Phase I | Project | 2 | Identification of Project Topic, Comprehensive Literature Survey, Problem Definition and Objectives, Methodology and Planning, Preliminary Design/Simulation |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BTEEE801 | Industrial Automation and PLC | Core | 4 | Introduction to Industrial Automation, Programmable Logic Controllers (PLCs), SCADA Systems, Distributed Control Systems (DCS), Industrial Communication Protocols |
| BTEEE802.1 | Internet of Things for EEE | Elective | 3 | IoT Architecture and Protocols, Sensors and Actuators for IoT, IoT Communication Technologies, Data Analytics in IoT, IoT Applications in Power Systems |
| BTEEE802.2 | Electric and Hybrid Vehicles | Elective | 3 | Components of EV/HEV, Power Train Architectures, Battery Management Systems, Charging Technologies, Vehicle Control Systems |
| BTEEE802.3 | Bio-Medical Instrumentation | Elective | 3 | Biopotential Electrodes, Biomedical Transducers, Physiological Measurement Systems, Medical Imaging Systems, Therapeutic and Prosthetic Devices |
| BTEEE803 | Industrial Management | Core | 3 | Functions of Management, Production and Operations Management, Marketing Management, Financial Management, Human Resource Management |
| BTEEE804 | Project Phase II | Project | 6 | Detailed Design and Implementation, Testing and Validation, Results Analysis and Discussion, Technical Report Writing, Project Defense and Presentation |
