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B-TECH in Electrical Engineering at Indian Institute of Technology Kanpur
Kanpur Nagar, Uttar Pradesh
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About the Specialization
What is Electrical Engineering at Indian Institute of Technology Kanpur Kanpur Nagar?
This Electrical Engineering program at Indian Institute of Technology Kanpur provides a robust foundation across core disciplines including electronics, power systems, control systems, communications, and signal processing. It is designed to cultivate innovative problem-solvers equipped to tackle complex challenges in India''''s evolving technological landscape. The curriculum uniquely blends theoretical rigor with hands-on practical experience, positioning graduates for impactful careers in both established industries and emerging technology sectors within the country.
Who Should Apply?
This program is ideal for bright, ambitious high school graduates who have excelled in the Joint Entrance Examination (JEE) Advanced and possess a strong foundational understanding of Physics, Chemistry, and Mathematics. It attracts students with a keen interest in electrical and electronic phenomena, a desire to innovate, and a passion for engineering solutions. It caters to those aiming for leadership roles in R&D, design, manufacturing, or seeking to pursue higher education and research in various facets of electrical engineering in India.
Why Choose This Course?
Graduates of this program are highly sought after, securing positions as design engineers, R&D scientists, system architects, and consultants in leading Indian and global firms. Entry-level salaries typically range from INR 10-25 LPA, with substantial growth potential. The rigorous curriculum develops strong analytical and problem-solving skills, which are crucial for success in India''''s competitive job market. Alumni often pursue further studies at top universities or embark on entrepreneurial ventures, contributing significantly to India''''s technological advancements.
Student Success Practices
Foundation Stage
Build a Strong Mathematical & Scientific Base- (Semester 1-2)
Dedicate significant time to mastering core concepts in Mathematics and Physics. Leverage online learning platforms like NPTEL and Khan Academy for supplementary explanations, and actively participate in tutorial sessions and peer-led study groups to solidify understanding. Prioritize problem-solving practice over rote memorization.
Tools & Resources
NPTEL courses, IITK tutorial classes, Departmental faculty office hours, Peer study networks
Career Connection
A robust foundation in MTH and PHY is indispensable for comprehending advanced EE subjects and performing well in technical interviews, forming the bedrock for all future engineering applications.
Cultivate Practical Coding & Design Skills- (Semester 1-2)
Beyond introductory programming, actively participate in coding contests on platforms like CodeChef and HackerRank. Undertake mini-projects involving microcontrollers (e.g., Arduino/Raspberry Pi) or basic circuit design. This fosters computational thinking and practical application of theory.
Tools & Resources
CodeChef, HackerRank, Arduino/Raspberry Pi kits, Open-source EDA tools (e.g., KiCad)
Career Connection
Strong programming skills are crucial for modern EE roles, spanning embedded systems, signal processing, and even power systems. Practical design experience enhances employability for hardware and software roles.
Engage with Faculty and Research Labs Early- (Semester 1-2)
Proactively approach professors to understand their research areas and explore opportunities for informal projects or assisting in labs. This exposure helps identify areas of interest, builds mentorship relationships, and provides early hands-on research experience beyond coursework.
Tools & Resources
Departmental research lab websites, Faculty profiles, Informal meetings with professors
Career Connection
Early research exposure builds a strong academic profile for higher studies, provides project experience for internships, and helps students decide on their specialization and future career trajectory.
Intermediate Stage
Seek Relevant Summer Internships- (Semester 3-5 (Summer breaks after 2nd and 3rd year))
Strategically apply for summer internships in core Electrical Engineering industries (e.g., power generation, electronics manufacturing, telecommunications) or research institutions. Leverage the IITK Career Development Centre and alumni network for leads and preparation.
Tools & Resources
IITK Career Development Centre (CDC), LinkedIn, Company career portals, Alumni mentorship programs
Career Connection
Internships are vital for practical industry exposure, networking, and often lead to pre-placement offers (PPOs), significantly enhancing job prospects and career clarity.
Specialize through Electives and Advanced Learning- (Semester 3-5)
Thoughtfully choose Departmental and Open Electives that align with your developing interests (e.g., VLSI, Power Electronics, Communication Systems, AI/ML in EE). Supplement coursework with advanced online certifications or NPTEL courses in your chosen specialization.
Tools & Resources
Departmental elective catalogs, Coursera/edX, NPTEL advanced modules, IEEE student chapters
Career Connection
Specialized knowledge makes you a strong candidate for targeted roles, distinguishing you in the job market and providing a competitive edge for specific industry or research domains.
Participate in Technical Clubs and Competitions- (Semester 3-5)
Actively join technical clubs (e.g., Robotics Club, IEEE Student Chapter, Electronics Club) and engage in national-level technical competitions like Smart India Hackathon or IEEExtreme. These activities build practical skills, teamwork, and problem-solving abilities outside the classroom.
Tools & Resources
IITK technical clubs'''' websites, Inter-IIT Tech Meet, National-level hackathons and project contests
Career Connection
Participation showcases practical application of knowledge, leadership, and resilience, which are highly valued by recruiters. It also expands your professional network and provides valuable project experience.
Advanced Stage
Undertake a High-Impact B.Tech Project (BTP)- (Semester 7-8)
Dedicate extensive effort to your B.Tech Project. Select a challenging topic, conduct thorough research, aim for innovative solutions, and ensure a high-quality implementation and detailed documentation. Treat it as a significant contribution to your chosen field.
Tools & Resources
Faculty advisors, Departmental research facilities, Advanced simulation/design software (e.g., MATLAB, ANSYS, Cadence)
Career Connection
A strong BTP is a powerful resume enhancer, demonstrating independent research, problem-solving, and practical engineering skills. It''''s a key talking point in interviews and can lead to publications or patent applications.
Strategize for Placements or Higher Education- (Semester 6-8)
Engage rigorously with the Career Development Centre for resume/CV building, mock interviews, and group discussion practice. For higher studies, diligently prepare for GATE, GRE, or GMAT exams, and meticulously research universities and specializations that align with your long-term career aspirations.
Tools & Resources
CDC workshops and resources, Alumni mentorship for interview preparation, GATE/GRE/GMAT study materials
Career Connection
Well-planned preparation is critical for securing top placements or admissions to prestigious national and international universities, defining your immediate career trajectory.
Network and Explore Diverse Career Paths- (Semester 7-8)
Actively network with alumni and industry professionals through webinars, conferences, and LinkedIn. Explore diverse career paths including core engineering, software development, consulting, research, and entrepreneurship. Engage with the IITK Incubation Centre if interested in launching a startup.
Tools & Resources
IITK alumni network events, LinkedIn for professional connections, Industry conferences, IITK Incubation Centre
Career Connection
Networking opens doors to hidden job markets, provides insights into various industries, and helps in making informed career decisions, whether pursuing corporate roles, academia, or entrepreneurial ventures in India''''s dynamic economy.
Program Structure and Curriculum
Eligibility:
- Successful completion of 10+2 with Physics, Chemistry, and Mathematics, and qualification in JEE Advanced as per JoSAA guidelines.
Duration: 8 semesters / 4 years
Credits: 176 Credits
Assessment: Assessment pattern not specified
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTH101A | Mathematics I | Core | 4 | Differential Calculus, Integral Calculus, Sequences and Series, Vector Calculus, Introduction to Ordinary Differential Equations |
| PHD101A | Physics I | Core | 4 | Classical Mechanics, Oscillations and Waves, Special Relativity, Electromagnetism Fundamentals, Introduction to Quantum Physics |
| PHY101A | Physics Lab | Lab | 2 | Measurement and Error Analysis, Mechanics Experiments, Heat and Thermodynamics Experiments, Electricity and Magnetism Experiments, Optics Experiments |
| LIF101A | Life Science I | Core | 2 | Cell Biology, Molecular Biology, Genetics and Genomics, Neuroscience Fundamentals, Bioenergetics and Metabolism |
| ESC101A | Introduction to Engineering | Core | 1 | Engineering Disciplines Overview, Design Thinking Process, Problem Identification and Solution, Ethics in Engineering, Sustainable Engineering Practices |
| HSS-I Elective | Humanities and Social Sciences Elective I | Elective | 3 | Introduction to Economics, Principles of Sociology, Psychology Basics, Philosophy and Ethics, Indian History and Culture |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTH102A | Mathematics II | Core | 4 | Linear Algebra, Vector Spaces and Transformations, Multivariable Calculus, Double and Triple Integrals, Probability and Statistics |
| CHM101A | Chemistry | Core | 4 | Atomic Structure and Bonding, Chemical Thermodynamics, Electrochemistry, Organic Chemistry Fundamentals, Polymer Chemistry |
| CHM101P | Chemistry Lab | Lab | 2 | Qualitative Analysis, Quantitative Analysis, Organic Synthesis Techniques, Electrochemistry Experiments, Spectroscopy Applications |
| CS101A | Introduction to Computer Science | Core | 4 | Programming with Python/C, Data Types and Control Structures, Functions and Modules, Object-Oriented Programming Concepts, Algorithm Design and Analysis |
| TA101A | Engineering Graphics | Core | 2 | Orthographic Projections, Isometric Projections, Sectional Views, Development of Surfaces, Computer-Aided Design (CAD) Software |
| HSS-I Elective | Humanities and Social Sciences Elective II | Elective | 3 | Communication Skills, Critical Thinking, Environmental Studies, Public Policy, Arts and Aesthetics |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTH203A | Complex Analysis and Differential Equations | Core | 4 | Complex Numbers and Functions, Analytic Functions, Cauchy-Riemann Equations, Series Solutions of Ordinary Differential Equations, Partial Differential Equations (PDEs) |
| EE200 | Digital Circuits | Core | 3 | Boolean Algebra and Logic Gates, Combinational Logic Design, Sequential Logic Design (Flip-Flops, Counters), Memory and Programmable Logic Devices, HDL for Digital Design |
| EE200P | Digital Circuits Lab | Lab | 2 | Logic Gate Realization, Combinational Circuit Implementation, Sequential Circuit Design, FPGA/CPLD Based Design, Digital IC Testing |
| EE210 | Signals, Systems & Networks | Core | 3 | Signal Classification and Properties, Linear Time-Invariant (LTI) Systems, Fourier Series and Transforms, Laplace Transform, Circuit Analysis using Transforms |
| EE230 | Electronics I | Core | 3 | Semiconductor Diodes and Rectifiers, Bipolar Junction Transistors (BJTs), Field-Effect Transistors (FETs), Transistor Biasing and Amplifiers, Operational Amplifiers (Op-Amps) |
| EE230P | Electronics I Lab | Lab | 2 | Diode Characteristics and Applications, Transistor Amplifier Design, FET Characteristics, Op-Amp Basic Circuits, Waveform Generation |
| ESO | Engineering Science Option I | Elective | 3 | Engineering Mechanics, Thermodynamics Principles, Material Science Introduction, Fluid Mechanics Basics, Mathematical Modeling in Engineering |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE240 | Electrical Machines & Power | Core | 3 | Magnetic Circuits, Transformers, DC Machines (Generators and Motors), Induction Machines, Synchronous Machines |
| EE240P | Electrical Machines & Power Lab | Lab | 2 | Transformer Characterization, DC Machine Performance, Induction Motor Testing, Synchronous Machine Operation, Power System Basics Experiments |
| EE250 | Control Systems | Core | 3 | System Modeling (Transfer Function, State Space), Time Domain Analysis, Stability Analysis (Routh-Hurwitz, Nyquist, Bode), Controller Design (PID, Lead-Lag), Root Locus Techniques |
| EE250P | Control Systems Lab | Lab | 2 | System Response Measurement, PID Controller Tuning, Motor Speed Control, Stability Analysis Experiments, Digital Control System Simulation |
| EE260 | Electromagnetics | Core | 3 | Vector Calculus for EM, Electrostatics (Gauss''''s Law, Potential), Magnetostatics (Ampere''''s Law, Biot-Savart Law), Maxwell''''s Equations, Electromagnetic Waves and Transmission Lines |
| EE270 | Data Structure & Algorithms | Core | 3 | Arrays, Linked Lists, Stacks, Queues, Trees (Binary, BST, AVL), Graphs (DFS, BFS, Shortest Path), Sorting and Searching Algorithms, Algorithm Analysis (Time and Space Complexity) |
| ESO | Engineering Science Option II | Elective | 3 | Computational Methods, Robotics Fundamentals, Applied Statistics, Manufacturing Processes, Renewable Energy Technologies |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE300 | Analog Circuits | Core | 3 | BJT and FET Amplifiers (Multi-stage), Frequency Response of Amplifiers, Feedback Amplifiers and Stability, Oscillators (RC, LC, Crystal), Active Filters (Op-Amp based) |
| EE300P | Analog Circuits Lab | Lab | 2 | Multi-stage Amplifier Design, Frequency Response Characterization, Feedback System Analysis, Oscillator Design and Testing, Filter Implementation using Op-Amps |
| EE310 | Communications | Core | 3 | Amplitude Modulation (AM), Angle Modulation (FM, PM), Noise in Communication Systems, Sampling and Quantization, Digital Modulation Techniques (ASK, FSK, PSK) |
| EE310P | Communications Lab | Lab | 2 | AM/FM Transmitter and Receiver Design, Pulse Modulation Techniques, Digital Modulation/Demodulation, Noise Measurement in Communication Systems, Spread Spectrum Techniques |
| EE320 | Power Electronics | Core | 3 | Power Semiconductor Devices (SCR, MOSFET, IGBT), DC-DC Converters (Buck, Boost, Buck-Boost), AC-DC Converters (Rectifiers), DC-AC Converters (Inverters), AC-AC Converters (Cycloconverters) |
| EE330 | Microprocessors & Microcontrollers | Core | 3 | Microprocessor Architecture (e.g., 8085/8086), Assembly Language Programming, Memory and I/O Interfacing, Microcontroller Architecture (e.g., 8051), Timers, Interrupts, and Serial Communication |
| EE330P | Microprocessors & Microcontrollers Lab | Lab | 2 | Assembly Language Programming Exercises, I/O Device Interfacing, Timer and Interrupt Programming, Serial Communication Protocols, Embedded System Development with Microcontrollers |
| HSS-II Elective | Humanities and Social Sciences Elective III | Elective | 3 | Advanced Economics Principles, Organizational Behavior, Public Speaking and Presentation, Indian Political System, Sociology of Science and Technology |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE340 | Power System Analysis | Core | 3 | Per Unit System and Network Matrices, Load Flow Studies (Gauss-Seidel, Newton-Raphson), Symmetrical and Unsymmetrical Fault Analysis, Power System Stability (Transient and Steady State), Economic Operation of Power Systems |
| EE340P | Power System Analysis Lab | Lab | 2 | Power System Modeling and Simulation, Load Flow Analysis using Software, Fault Analysis Simulation, Power System Protection Relays, Smart Grid Concepts Implementation |
| EE350 | Signal Processing | Core | 3 | Discrete-Time Signals and Systems, Z-Transform, Discrete Fourier Transform (DFT), Fast Fourier Transform (FFT), Digital Filter Design (FIR and IIR) |
| EE350P | Signal Processing Lab | Lab | 2 | Discrete Signal Generation and Analysis, DFT/FFT Implementations, Digital Filter Design and Testing, Audio Signal Processing, Image Processing Fundamentals |
| DE-1 | Department Elective I | Elective | 3 | Advanced Digital Communication, VLSI Design, Renewable Energy Systems, Machine Learning for Electrical Engineers, Advanced Control Theory |
| DE-2 | Department Elective II | Elective | 3 | Digital Image Processing, Microwave Engineering, Embedded Systems Design, Smart Grid Technology, Optimal Control Systems |
| OE-1 | Open Elective I | Elective | 3 | Entrepreneurship and Innovation, Data Science Fundamentals, Artificial Intelligence Concepts, Introduction to Financial Engineering, Project Management |
Semester 7
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| DE-4 | Department Elective IV | Elective | 3 | Wireless Communication Systems, High Voltage Engineering, Bio-medical Signal Processing, Quantum Computing for Electrical Engineers, Internet of Things (IoT) Architectures |
| OE-3 | Open Elective III | Elective | 3 | Economics of Infrastructure, Human Computer Interaction, Strategic Management, Financial Modeling, Sustainable Development Goals |
| BTP102 | B.Tech Project Part II | Project | 8 | Advanced System Design and Prototyping, Extensive Testing and Validation, Data Analysis and Interpretation, Comprehensive Final Report and Thesis, Project Defense and Presentation to Panel |
