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B-TECH-M-TECH in Electrical Electronics Engineering at Shanmugha Arts Science Technology & Research Academy (SASTRA)
Thanjavur, Tamil Nadu
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About the Specialization
What is Electrical & Electronics Engineering at Shanmugha Arts Science Technology & Research Academy (SASTRA) Thanjavur?
This Integrated M.Tech. Power System Engineering program at SASTRA Deemed University focuses on providing a comprehensive understanding of the generation, transmission, distribution, and control of electrical power. The curriculum integrates core electrical engineering principles with advanced studies in power system dynamics, smart grids, and renewable energy, preparing students for the evolving challenges of the Indian power sector. It emphasizes both theoretical foundations and practical applications relevant to modern energy infrastructure.
Who Should Apply?
This program is ideal for ambitious fresh 10+2 graduates seeking a deep dive into power engineering from an early stage, working professionals in the power industry looking to advance their technical expertise in areas like smart grids or renewables, and career changers with a strong analytical background desiring to transition into India''''s rapidly growing energy sector. Candidates should possess a strong aptitude for mathematics, physics, and problem-solving.
Why Choose This Course?
Graduates of this program can expect to pursue India-specific career paths in power generation companies (e.g., NTPC, Adani Power), transmission utilities (e.g., PGCIL), distribution companies (various state DISCOMs), renewable energy firms, and R&D organizations. Entry-level salaries typically range from INR 4-7 LPA, growing to INR 10-25+ LPA with experience. The program aligns with skills required for professional certifications in energy management and power system protection, fostering growth trajectories in leadership and specialized engineering roles within Indian companies.
Student Success Practices
Foundation Stage
Master Core Engineering Mathematics & Physics- (Semester 1-2)
Dedicate consistent time to build a strong foundation in calculus, linear algebra, differential equations, and classical/modern physics. Utilize online platforms like NPTEL for supplementary lectures, engage in peer study groups, and practice problem-solving rigorously. Early mastery of these subjects is crucial for advanced electrical engineering concepts.
Tools & Resources
NPTEL courses, Khan Academy, MIT OpenCourseware, Peer Study Groups
Career Connection
Strong fundamentals enable clearer understanding of advanced topics like circuit analysis, control systems, and power system stability, leading to better academic performance and interview readiness for technical roles.
Develop Foundational Programming Skills in C/C++ or Python- (Semester 1-2)
Enroll in introductory programming courses seriously and actively participate in lab sessions. Practice coding regularly using platforms like HackerRank or CodeChef. Focus on logic building, data structures, and algorithms relevant to engineering applications. Seek feedback from instructors and peers.
Tools & Resources
HackerRank, CodeChef, GeeksforGeeks, Online Python/C++ Tutorials
Career Connection
Proficiency in programming is increasingly vital for power engineers for simulation, data analysis, smart grid development, and automation roles, significantly enhancing employability.
Engage in Hands-on General Engineering Labs- (Semester 1-2)
Actively participate in workshops and general engineering labs. Understand the basic working principles of electrical components, mechanical tools, and measurement instruments. Focus on safe operating procedures and accurate data collection. Proactively ask questions to lab assistants.
Tools & Resources
Departmental Labs, Workshop Manuals, Basic Electronics Kits
Career Connection
Practical skills are highly valued in the industry. Early exposure to engineering tools and components builds a foundation for advanced lab work and real-world project execution, crucial for internships and entry-level positions.
Intermediate Stage
Build a Portfolio of Mini-Projects in Core EEE Domains- (Semester 3-5)
Beyond lab assignments, identify small projects related to electric circuits, electronics, or microcontrollers. Utilize kits like Arduino or Raspberry Pi. Document your projects thoroughly, showcasing your problem-solving approach and technical skills. Present these projects at departmental events or online.
Tools & Resources
Arduino/Raspberry Pi kits, Proteus/Multisim simulation software, GitHub
Career Connection
A strong project portfolio demonstrates initiative, practical application of knowledge, and problem-solving abilities, making you a more attractive candidate for internships and core engineering roles.
Seek Early Industry Exposure through Internships or Workshops- (Semester 4-5)
Actively look for short-term internships or industrial training programs during summer breaks, even if unpaid, in local power substations, manufacturing units, or small energy firms. Attend industry-specific workshops and webinars. Network with alumni and industry professionals through LinkedIn.
Tools & Resources
LinkedIn, SASTRA Placement Cell, Industry Connect Events, Internshala
Career Connection
Early exposure provides practical insights into the industry, helps clarify career interests, and builds a valuable professional network, often leading to better internship and placement opportunities in subsequent years.
Participate in Technical Competitions and Student Clubs- (Semester 3-5)
Join relevant student technical clubs (e.g., IEEE Student Branch, Robotics Club) and participate in inter-college technical fests or hackathons focused on electrical and electronics challenges. This hones teamwork, problem-solving, and time management skills under pressure.
Tools & Resources
IEEE Student Chapter, Departmental Technical Clubs, National Engineering Fests
Career Connection
Participation enhances your resume, demonstrates leadership and collaborative skills, and provides opportunities to apply theoretical knowledge to solve real-world problems, which are highly valued by recruiters.
Advanced Stage
Undertake a Comprehensive Research/Industrial Project- (Semester 6-10)
Identify a significant project in your specialization (Power System Engineering) during your B.Tech final year and M.Tech years. Work closely with a faculty mentor or an industry partner. Focus on developing innovative solutions or conducting in-depth analysis. Aim for publication in conferences or journals.
Tools & Resources
MATLAB/Simulink, ETAP/PSCAD/PowerFactory, Research Labs, Faculty Mentors
Career Connection
A strong final year/M.Tech project is critical for placements, especially in R&D or specialized engineering roles. It showcases advanced technical skills, research aptitude, and the ability to deliver complex solutions.
Intensify Placement Preparation and Niche Skill Development- (Semester 7-9)
Beyond core subjects, identify specific high-demand skills in Power Systems (e.g., Smart Grid protocols, Renewable Energy integration software, Power System Protection algorithms) and gain proficiency. Regularly practice aptitude, technical, and HR interview questions. Attend mock interviews conducted by the placement cell.
Tools & Resources
SASTRA Placement Cell, Online Aptitude Portals, NPTEL Advanced Courses, Coursera/edX for specialized certifications
Career Connection
Tailored skill development and rigorous interview practice significantly increase your chances of securing placements in top-tier core electrical companies, consultancies, and PSUs, aligning with your specialization.
Build a Professional Network and Mentorship Relationships- (Semester 7-10)
Actively engage with alumni working in the power sector, attend industry conferences, and seek out mentors. Utilize LinkedIn to connect with professionals and follow industry leaders. Mentors can provide guidance on career paths, job search strategies, and industry trends.
Tools & Resources
LinkedIn, Alumni Association, Industry Conferences (e.g., ELECRAMA, India Smart Grid Week)
Career Connection
A robust professional network can open doors to hidden job opportunities, provide invaluable career advice, and support long-term professional growth in a competitive industry.
Program Structure and Curriculum
Eligibility:
- Minimum 60% aggregate in 10+2 examinations (or equivalent) with Physics, Chemistry, and Mathematics. Admission based on JEE Main scores and/or SASTRA''''s own entrance exam.
Duration: 5 years / 10 semesters
Credits: 194 (as per Integrated M.Tech Power System Engineering scheme of study) Credits
Assessment: Internal: 50%, External: 50%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAC101 | Mathematics I | Core | 4 | Calculus of one variable, Multivariable Calculus, Linear Algebra basics, Ordinary Differential Equations, Numerical methods for equations |
| PHC101 | Physics I | Core | 4 | Mechanics and Waves, Thermal Physics, Electromagnetism, Optics, Modern Physics Introduction |
| CHC101 | Chemistry I | Core | 4 | Atomic Structure & Bonding, Thermodynamics & Kinetics, Electrochemistry, Spectroscopy, Polymer Chemistry |
| PDC101 | Professional Development I | Skill/Elective | 1 | Communication Skills, Presentation Techniques, Teamwork, Basic Etiquette, Self-awareness |
| CSC101 | Introduction to Computer Programming | Core | 3 | Programming Constructs, Conditional Statements, Loops, Functions, Arrays and Strings |
| CSL101 | Computer Programming Lab | Lab | 1 | Hands-on C programming, Debugging techniques, Problem solving with code, Algorithm implementation, Data structures practice |
| GEL101 | General Engineering Lab I | Lab | 1 | Basic Electrical circuits, Workshop practices, Measurement techniques, Material properties, Safety protocols |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAC102 | Mathematics II | Core | 4 | Vector Calculus, Complex Analysis, Laplace Transforms, Fourier Series, Partial Differential Equations |
| PHC102 | Physics II | Core | 4 | Quantum Mechanics, Solid State Physics, Semiconductor Physics, Lasers and Fiber Optics, Nuclear Physics |
| CHC102 | Chemistry II | Core | 4 | Environmental Chemistry, Corrosion and its control, Water Treatment, Fuel Chemistry, Green Chemistry principles |
| PDC102 | Professional Development II | Skill/Elective | 1 | Critical Thinking, Problem Solving, Time Management, Interpersonal Skills, Goal Setting |
| CEC101 | Engineering Graphics | Core | 3 | Orthographic Projections, Isometric Projections, Sectional Views, Development of Surfaces, AutoCAD Basics |
| GEL102 | General Engineering Lab II | Lab | 1 | Basic Electronics components, Circuit building, Fluid mechanics basics, Thermodynamics experiments, Engineering measurement tools |
| HUC101 | Technical English | Humanities | 3 | Technical Report Writing, Research Paper Writing, Effective Oral Presentation, Business Correspondence, Grammar and Vocabulary for Engineers |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAC201 | Numerical Methods & Probability | Core | 4 | Root Finding Methods, Interpolation, Numerical Integration, Probability Distributions, Statistical Inference |
| EEC201 | Electric Circuits Analysis | Core | 4 | Network Theorems, AC Circuits, Transient Analysis, Two-port Networks, Resonance and Coupled Circuits |
| EEC202 | Electronic Devices & Circuits | Core | 4 | Diode Characteristics, Transistor Biasing, FETs and MOSFETs, Amplifier Circuits, Oscillators and Multivibrators |
| EEC203 | Electromagnetic Field Theory | Core | 4 | Vector Calculus for EM, Electrostatics, Magnetostatics, Maxwell''''s Equations, Electromagnetic Waves |
| EEL201 | Electric Circuits Lab | Lab | 1 | Verification of Network Theorems, AC and DC circuit experiments, Frequency response analysis, Power measurement, Resonance circuits |
| EEL202 | Electronic Devices Lab | Lab | 1 | Diode and Zener characteristics, Transistor amplifier design, FET and MOSFET experiments, Rectifiers and filters, Oscillator circuits |
| PDC201 | Professional Development III | Skill/Elective | 1 | Quantitative Aptitude, Logical Reasoning, Verbal Ability, Data Interpretation, Interview Skills |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EEC204 | Analog & Digital Integrated Circuits | Core | 4 | Operational Amplifiers, Digital Logic Gates, Combinational Circuits, Sequential Circuits, Memory and Programmable Logic |
| EEC205 | Electrical Machines I | Core | 4 | DC Machines, Transformers, Three-Phase Circuits, Induction Motors, Synchronous Machines |
| EEC206 | Control Systems | Core | 4 | System Modeling, Time Domain Analysis, Frequency Domain Analysis, Stability Analysis, Controller Design |
| EEC207 | Power Electronics | Core | 4 | Power Semiconductor Devices, Rectifiers, AC Voltage Controllers, DC-DC Converters, Inverters |
| EEL203 | Digital Circuits Lab | Lab | 1 | Logic gate implementation, Combinational circuit design, Sequential circuit design, Microcontroller interfacing, FPGA/CPLD basics |
| EEL204 | Electrical Machines Lab | Lab | 1 | DC motor/generator testing, Transformer characteristics, Induction motor experiments, Synchronous machine operation, Speed control of motors |
| PDC202 | Professional Development IV | Skill/Elective | 1 | Resume Building, Interview Preparation, Group Discussion Techniques, Corporate Etiquette, Career Planning |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EEC301 | Microprocessors & Microcontrollers | Core | 4 | 8085/8086 Architecture, Assembly Language Programming, Peripheral Interfacing, 8051 Microcontroller, Embedded System Basics |
| EEC302 | Power System Analysis | Core | 4 | Per Unit System, Bus Admittance/Impedance Matrix, Load Flow Studies, Symmetrical Fault Analysis, Unsymmetrical Fault Analysis |
| EEC303 | Measurements & Instrumentation | Core | 4 | Measurement Standards, Analog & Digital Instruments, Transducers, Bridge Circuits, Data Acquisition Systems |
| EEC304 | Digital Signal Processing | Core | 4 | Discrete-Time Signals & Systems, Z-Transforms, DFT and FFT, IIR Filter Design, FIR Filter Design |
| EEL301 | Microprocessors & Microcontrollers Lab | Lab | 1 | Assembly language programming, Interfacing I/O devices, Timer/Counter programming, Serial communication, Project development |
| EEL302 | Power Electronics Lab | Lab | 1 | SCR, MOSFET, IGBT characteristics, Controlled rectifiers, Choppers and inverters, AC voltage controllers, PWM techniques |
| HUC301 | Indian Constitution & Professional Ethics | Humanities | 2 | Constitutional framework, Fundamental Rights, Engineering Ethics, Professional Responsibility, Environmental Laws |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EEC305 | Power System Protection & Switchgear | Core | 4 | Protective Relays, Circuit Breakers, Fault Detection, Generator & Transformer Protection, Transmission Line Protection |
| EEC306 | High Voltage Engineering | Core | 4 | Breakdown Mechanisms, Generation of High Voltages, Measurement of High Voltages, Insulation Systems, HVDC Transmission |
| EEC307 | Renewable Energy Systems | Core | 4 | Solar Photovoltaic Systems, Wind Energy Systems, Hydro & Geothermal Energy, Biomass & Fuel Cells, Energy Storage Technologies |
| EEC308 | Electric Drives | Core | 4 | Dynamics of Electric Drives, DC Motor Drives, Induction Motor Drives, Synchronous Motor Drives, Control of Electric Drives |
| EEL303 | Power System Simulation Lab | Lab | 1 | Load flow studies using ETAP/PSCAD, Fault analysis simulations, Stability analysis, Protection scheme simulation, Renewable energy system modeling |
| EEL304 | Control Systems Lab | Lab | 1 | Time and frequency response, PID controller tuning, Lead-lag compensator design, PLC programming basics, System identification |
| EEC38X | Program Elective I | Elective | 3 | Advanced topics in Power Systems, Smart Grid Technologies, Power System Dynamics, Energy Management, Custom Power Devices |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MAC401 | Optimization Techniques | Core (M.Tech) | 4 | Linear Programming, Non-Linear Programming, Dynamic Programming, Genetic Algorithms, Network Optimization |
| PSE401 | Advanced Power System Analysis | Core (M.Tech Specialization) | 4 | State Estimation, Contingency Analysis, Economic Load Dispatch, Unit Commitment, Security Analysis |
| PSE402 | Power System Dynamics & Stability | Core (M.Tech Specialization) | 4 | Rotor Angle Stability, Voltage Stability, Small Signal Stability, Transient Stability, Excitation Systems |
| PSE403 | Advanced Control of Power Systems | Core (M.Tech Specialization) | 4 | Load Frequency Control, Voltage Reactive Power Control, FACTS Devices, Power System Stabilizers, Wide Area Measurement Systems (WAMS) |
| PSEL401 | Advanced Power System Lab I | Lab (M.Tech) | 1 | Advanced protection relays, HVDC/FACTS experimental setup, Power quality analysis, Smart grid components testing, Renewable energy integration |
| PSE4XX | Program Elective II | Elective (M.Tech) | 3 | Distributed Generation, Electric Vehicles & Charging, Power Quality Improvement, HVDC and FACTS, SCADA Systems |
| HUC401 | Research Methodology | Humanities (M.Tech) | 3 | Research Problem Formulation, Literature Review, Data Collection Methods, Statistical Analysis, Report Writing |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| PSE404 | Smart Grid Technologies | Core (M.Tech Specialization) | 4 | Smart Grid Architecture, Advanced Metering Infrastructure, Demand Side Management, Cyber Security in Smart Grid, Microgrids and Grid Integration |
| PSE405 | Advanced Power System Protection | Core (M.Tech Specialization) | 4 | Digital Relaying, Substation Automation, Adaptive Protection, Communication in Protection, Protection of Microgrids |
| PSEL402 | Advanced Power System Lab II | Lab (M.Tech) | 1 | Smart grid simulations, IoT in power systems, Machine learning for grid operations, Energy management systems, Capstone project preparation |
| PSE4XX | Program Elective III | Elective (M.Tech) | 3 | Energy Economics, Power System Restructuring, Asset Management in Power Systems, Grid Integration of Renewables, Machine Learning in Power Systems |
| PSE498 | Project Work Phase I | Project | 6 | Problem identification, Literature survey, Methodology development, Initial design/simulation, Report writing |
| PDC401 | Professional Development (M.Tech) | Skill/Elective | 1 | Technical Writing for Research, Patent Filing, Entrepreneurship Basics, Project Management, Ethics in Research |
Semester 9
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| PSE501 | Advanced Renewable Energy Systems | Core (M.Tech Specialization) | 4 | Hybrid Renewable Energy Systems, Distributed Energy Resources, Power Electronics for Renewables, Grid Integration Challenges, Energy Storage Optimization |
| PSE502 | Power System Operation & Control | Core (M.Tech Specialization) | 4 | Economic Dispatch with Constraints, Unit Commitment Algorithms, Automatic Generation Control, Energy Management Systems (EMS), Cyber-Physical System Security |
| PSE5XX | Program Elective IV | Elective (M.Tech) | 3 | Real-Time Digital Simulators, Power System Resilience, Demand Response, Blockchain in Energy Systems, AI applications in Power Grid |
| PSE599 | Project Work Phase II | Project | 10 | Advanced system design, Experimental validation, Data analysis and interpretation, Result optimization, Thesis writing and defense |
Semester 10
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| PSE5XX | Program Elective V | Elective (M.Tech) | 3 | Power System Reliability, Hydrogen Energy Systems, Cyber-Physical Power Systems, Grid Modernization, Energy Trading |
| PSE599 | Project Work Phase II (Continued) | Project | 10 | Final project implementation, Comprehensive testing, Performance evaluation, Professional documentation, Presentation and Viva Voce |
