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B-TECH-M-TECH-DUAL-DEGREE in Electrical Engineering Vlsi Design And Nanoelectronics at Indian Institute of Technology Indore
Indore, Madhya Pradesh
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About the Specialization
What is Electrical Engineering (VLSI Design and Nanoelectronics) at Indian Institute of Technology Indore Indore?
This Electrical Engineering (VLSI Design and Nanoelectronics) program at Indian Institute of Technology Indore focuses on equipping students with advanced knowledge and practical skills in designing and analyzing integrated circuits. It is critical for India''''s growing electronics manufacturing and design industry. The program differentiates itself with a blend of foundational EE concepts and specialized VLSI modules, addressing the increasing demand for skilled chip designers in both domestic and global markets.
Who Should Apply?
This program is ideal for high-achieving fresh graduates with a strong aptitude for mathematics, physics, and problem-solving, typically those who excelled in JEE Advanced. It also suits engineering professionals seeking to upskill in cutting-edge semiconductor technologies or career changers aiming to transition into the thriving microelectronics industry within India''''s tech landscape.
Why Choose This Course?
Graduates of this program can expect diverse career paths in semiconductor design, fabrication, and verification roles across India. Entry-level salaries typically range from INR 8-15 LPA, growing significantly with experience. They can become VLSI Design Engineers, CAD Tool Developers, Analog/Digital IC Designers, or pursue R&D careers in top Indian and multinational companies, often aligning with global certifications.
Student Success Practices
Foundation Stage
Master Core Engineering Fundamentals- (Semester 1-2)
Dedicate significant effort to building a strong foundation in Calculus, Physics, Electrical Sciences, and Programming. Form study groups, solve a high volume of practice problems, and clarify concepts immediately with faculty or teaching assistants.
Tools & Resources
NPTEL courses for foundational subjects, Khan Academy for concept reinforcement, Peer study groups
Career Connection
A robust foundation is essential for understanding advanced topics in VLSI and excelling in technical interviews for core engineering roles. It underpins all subsequent specialization.
Develop Early Programming and Logic Skills- (Semester 1-3)
Beyond introductory courses, engage in competitive programming or personal projects involving C/C++ or Python. Focus on algorithmic thinking, data structures, and digital logic concepts through online platforms and mini-projects.
Tools & Resources
CodeChef, GeeksforGeeks, HackerRank, Logic simulation software (e.g., Logisim)
Career Connection
Strong programming and logical aptitude are vital for VLSI design automation, verification, and understanding underlying digital circuit principles, directly impacting placement opportunities.
Actively Participate in Labs and Design Projects- (Semester 1-3)
Treat lab sessions not just as completion tasks but as opportunities to understand practical implementation. Take initiative in design projects, even small ones, to gain hands-on experience with circuits and basic electronic components.
Tools & Resources
Lab equipment manuals, Circuit simulation software (e.g., LTspice, Proteus), Arduino/Raspberry Pi for basic projects
Career Connection
Practical exposure and problem-solving in labs directly translate to real-world engineering challenges, making students more competent and attractive to recruiters for hands-on roles.
Intermediate Stage
Deep Dive into VLSI-Relevant Electives and Labs- (Semester 4-6)
As soon as VLSI-specific electives become available (e.g., VLSI Design, Digital/Analog IC Design), prioritize them. Actively participate in associated labs, seeking opportunities to extend projects beyond curriculum requirements to build a strong portfolio.
Tools & Resources
Cadence/Synopsys EDA tools (if campus licenses available), Verilog/VHDL programming environments, Online tutorials for specific design flows
Career Connection
Specialized knowledge and practical experience in core VLSI subjects directly qualify students for specific design and verification roles within the semiconductor industry, enhancing employability.
Seek Internships in Semiconductor Industry- (Semester 5-7)
Actively search for summer internships at semiconductor design houses, electronics manufacturing firms, or R&D centers in India. Leverage college placement cells, alumni networks, and online platforms to secure relevant industry exposure.
Tools & Resources
College Placement Cell portal, LinkedIn, Internshala, Company career pages
Career Connection
Internships provide invaluable industry experience, help network with professionals, and often lead to pre-placement offers, significantly boosting career prospects upon graduation.
Engage in Advanced Design Projects and Competitions- (Semester 6-8)
Collaborate with peers or faculty on advanced design projects, especially those involving FPGA implementation, ASIC design flow, or custom IC design. Participate in national-level design competitions to showcase skills and gain recognition.
Tools & Resources
Advanced EDA tools, FPGA development boards, IEEE design competitions, Open-source VLSI projects
Career Connection
These experiences demonstrate initiative, problem-solving abilities, and practical application of knowledge, making a candidate highly competitive for specialized VLSI roles and fostering innovation.
Advanced Stage
Focus on M.Tech Thesis and Research- (Semester 8-10)
Dedicate substantial time and effort to the M.Tech thesis, aligning it with current industry challenges or cutting-edge research in VLSI. Aim for high-quality research that could lead to publications or patent applications.
Tools & Resources
Advanced simulation tools, Research papers (IEEE Xplore, ACM Digital Library), Mentorship from faculty and industry experts
Career Connection
A strong thesis showcases deep expertise, research capability, and problem-solving skills crucial for R&D roles, PhD admissions, and leadership positions in technology firms.
Develop Industry-Specific Software Proficiency- (Semester 7-9)
Beyond academic projects, gain proficiency in industry-standard Electronic Design Automation (EDA) tools like Cadence Virtuoso, Synopsys Design Compiler, or Mentor Graphics Calibre. Consider online certifications for specific tool suites.
Tools & Resources
Official EDA tool documentation, Online certification courses (e.g., through Coursera, edX for specific tools), Industry workshops and training programs
Career Connection
Direct proficiency in industry-standard tools is a critical requirement for most VLSI job roles, significantly reducing the training period for new hires and making students highly desirable.
Network and Prepare for Placements/Higher Studies- (Semester 9-10)
Actively network with alumni and industry professionals through conferences, webinars, and professional bodies like IEEE. Prepare rigorously for placement interviews, focusing on core VLSI concepts, problem-solving, and behavioral questions. Research higher study opportunities if interested.
Tools & Resources
LinkedIn for professional networking, Company technical blogs, Mock interview sessions, GATE/GRE preparation material
Career Connection
Effective networking can open doors to opportunities, while thorough preparation ensures success in the competitive job market or for securing admissions in leading global universities for further studies.
Program Structure and Curriculum
Eligibility:
- Successful completion of 10+2 (or equivalent) with Physics, Chemistry, and Mathematics, and a valid JEE Advanced rank.
Duration: 10 semesters / 5 years
Credits: 155 Credits
Assessment: Internal: undefined, External: undefined
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA101 | Calculus | Core | 4 | Limits and Continuity, Differentiation and Applications, Integration and Techniques, Sequences and Series, Multivariable Calculus |
| PH101 | Physics | Core | 4 | Classical Mechanics, Electromagnetism and Maxwell''''s Equations, Optics and Wave Phenomena, Quantum Mechanics Introduction, Thermodynamics and Statistical Physics |
| CS101 | Introduction to Programming | Core | 3 | Programming Fundamentals (C/C++), Data Types and Operators, Control Structures and Loops, Functions and Arrays, Basic Algorithms and Problem Solving |
| ME101 | Engineering Graphics | Core | 3 | Orthographic Projections, Isometric Views, Sectional Views and Conventions, Dimensioning and Tolerancing, Introduction to CAD Software |
| HS101 | English for Communication | Core | 2 | Grammar and Syntax, Vocabulary Building, Technical Writing Skills, Presentation and Public Speaking, Reading Comprehension |
| PH103 | Physics Lab | Lab | 2 | Experiments in Mechanics, Experiments in Optics, Experiments in Electromagnetism, Data Analysis and Error Calculation |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA102 | Linear Algebra & Differential Equations | Core | 4 | Matrices and Determinants, Vector Spaces and Subspaces, Eigenvalues and Eigenvectors, First Order Differential Equations, Higher Order Differential Equations |
| EE101 | Electrical Sciences | Core | 3 | DC and AC Circuits, Network Theorems, Semiconductor Devices, Transformers and Motors (Basics), Basic Electronic Circuits |
| CH101 | Chemistry | Core | 4 | Atomic Structure and Bonding, Thermodynamics and Kinetics, Organic Chemistry Fundamentals, Electrochemistry, Materials Science Introduction |
| CE101 | Engineering Mechanics | Core | 4 | Statics of Particles and Rigid Bodies, Equilibrium and Free Body Diagrams, Friction and Virtual Work, Dynamics of Particles, Work-Energy Principle |
| CH103 | Chemistry Lab | Lab | 2 | Volumetric Analysis, Gravimetric Analysis, Spectroscopic Techniques, Synthesis of Organic Compounds |
| EE102 | Electrical Sciences Lab | Lab | 2 | Basic Circuit Experiments, DC and AC Measurement, Diode and Transistor Characteristics, Operational Amplifier Applications |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE201 | Digital Circuits | Core | 3 | Boolean Algebra and Logic Gates, Combinational Logic Design, Sequential Logic Design (Flip-Flops, Registers, Counters), Finite State Machines, Semiconductor Memories |
| EE203 | Electromagnetic Theory | Core | 4 | Electrostatics (Coulomb''''s Law, Gauss''''s Law), Magnetostatics (Ampere''''s Law, Biot-Savart Law), Maxwell''''s Equations, Wave Propagation in Dielectrics and Conductors, Transmission Lines |
| EE202 | Signals and Systems | Core | 4 | Continuous and Discrete Time Signals, Linear Time Invariant Systems, Fourier Series and Fourier Transform, Laplace Transform, Z-Transform |
| MA201 | Probability and Statistics | Core | 4 | Axioms of Probability, Random Variables and Distributions, Joint Probability Distributions, Hypothesis Testing, Regression and Correlation |
| HS201 | Economics | Core | 3 | Microeconomics (Demand, Supply, Market Structures), Macroeconomics (National Income, Inflation), Indian Economy Overview, Monetary and Fiscal Policy, International Trade |
| EE204 | Digital Circuits Lab | Lab | 2 | Logic Gate Implementation, Combinational Circuit Design, Sequential Circuit Implementation, FPGA/CPLD Prototyping Basics |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE205 | Analog Circuits | Core | 3 | Diode Circuits and Rectifiers, BJT and MOSFET Amplifiers, Feedback Amplifiers, Operational Amplifiers (OP-AMPs), Oscillators and Waveform Generators |
| EE206 | Power Electronics | Core | 3 | Power Semiconductor Devices, DC-DC Converters (Buck, Boost), AC-DC Converters (Rectifiers), DC-AC Inverters, Motor Drives Introduction |
| EE207 | Control Systems | Core | 4 | System Modeling (Transfer Functions, State Space), Block Diagrams and Signal Flow Graphs, Stability Analysis (Routh-Hurwitz, Nyquist), Root Locus Techniques, Frequency Response (Bode Plot, Polar Plot) |
| CS201 | Data Structures | Core | 3 | Arrays and Linked Lists, Stacks and Queues, Trees and Graphs, Sorting Algorithms, Searching Algorithms |
| OE1 | Open Elective-I | Elective | 3 | Introduction to interdisciplinary topics based on student choice |
| EE208 | Analog Circuits Lab | Lab | 2 | BJT/MOSFET Amplifier Design, Feedback Circuit Implementation, OP-AMP Applications, Filter Design |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE301 | Microprocessors and Microcontrollers | Core | 3 | 8085/8086 Architecture, Assembly Language Programming, Memory and I/O Interfacing, Introduction to Microcontrollers (e.g., PIC/AVR), Interrupts and Timers |
| EE302 | Digital Signal Processing | Core | 3 | Discrete Fourier Transform (DFT), Fast Fourier Transform (FFT), FIR Filter Design, IIR Filter Design, Multirate Signal Processing |
| EE303 | Communication Systems | Core | 3 | Amplitude Modulation (AM, DSB-SC, SSB), Angle Modulation (FM, PM), Sampling and Quantization, Digital Modulation Techniques (ASK, FSK, PSK), Noise in Communication Systems |
| EE304 | Power Systems | Core | 3 | Power Generation and Transmission, Transmission Line Parameters, Per Unit System, Load Flow Studies, Fault Analysis (Symmetrical and Unsymmetrical) |
| EE305 | Microprocessors Lab | Lab | 2 | 8085/8086 Assembly Language Programming, Interfacing with Peripherals, Microcontroller Programming, Embedded System Development Basics |
| EE306 | Digital Signal Processing Lab | Lab | 2 | Signal Generation and Analysis, DFT/FFT Implementation, FIR/IIR Filter Design and Implementation, Audio and Image Processing Applications |
| DE1 | Discipline Elective-I | Elective | 3 | Selection from various EE domains based on student interest |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE307 | VLSI Design | Core | 3 | CMOS Technology and Fabrication, MOS Transistor Theory, Inverter Characteristics, Combinational and Sequential MOS Logic, VLSI Design Flow and Tools |
| EE308 | Machine Learning for EE | Core | 3 | Introduction to Machine Learning, Supervised Learning (Regression, Classification), Unsupervised Learning (Clustering), Neural Networks and Deep Learning Basics, Applications in Electrical Engineering |
| DE2 | Discipline Elective-II | Elective | 3 | Selection from various EE domains based on student interest |
| OE2 | Open Elective-II | Elective | 3 | Introduction to interdisciplinary topics based on student choice |
| EE311 | VLSI Design Lab | Lab | 2 | CMOS Logic Design and Simulation (SPICE), Verilog/VHDL for Digital Design, FPGA/ASIC Design Flow Practice, Layout Design (using EDA tools) |
| EE312 | Design Project | Project | 2 | Problem Identification and Formulation, System Design and Implementation, Testing and Validation, Technical Report Writing, Presentation Skills |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| DE3 | Discipline Elective-III (VLSI Focused) | Elective | 3 | Advanced VLSI Design (e.g., Interconnects, Clocking), Digital IC Design (e.g., Logic Styles, Static/Dynamic CMOS), Analog IC Design (e.g., Current Mirrors, Differential Amps), Semiconductor Devices and Technology (e.g., Device Physics, Fabrication), CAD for VLSI (e.g., Logic Synthesis, Placement and Routing) |
| DE4 | Discipline Elective-IV (VLSI Focused) | Elective | 3 | Nanoelectronics (e.g., Quantum Mechanics, Nanostructures), Mixed-Signal VLSI Design (e.g., ADC/DAC, PLLs), RF IC Design (e.g., LNA, Mixers, Oscillators), Low Power VLSI Design (e.g., Power Analysis, Voltage Scaling), VLSI Testing and Verification (e.g., DFT, ATPG) |
| DE5 | Discipline Elective-V (VLSI Focused) | Elective | 3 | Advanced Digital Signal Processing for VLSI, Memory Design and Architectures, FPGA Architectures and Applications, Embedded System Design for VLSI, High-Level Synthesis for Digital Systems |
| OE3 | Open Elective-III | Elective | 3 | Introduction to interdisciplinary topics based on student choice |
| EE491 | B.Tech Project-I | Project | 3 | Literature Survey and Problem Definition, Research Methodology, Initial Design and Simulation, Feasibility Study, Project Proposal Development |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| DE6 | Discipline Elective-VI (VLSI Focused) | Elective | 3 | Advanced Topics in Semiconductor Devices, VLSI System Design, Hardware Security in VLSI, AI Accelerators and Neuromorphic Computing, Flexible and Organic Electronics |
| DE7 | Discipline Elective-VII (VLSI Focused) | Elective | 3 | VLSI Interconnects and Packaging, System-on-Chip (SoC) Design, Design for Manufacturability (DFM), Process Design Kit (PDK) Development, Special Topics in Nanoelectronics |
| EE492 | B.Tech Project-II | Project | 3 | Detailed Design and Implementation, Extensive Simulation and Verification, Performance Analysis and Optimization, Interim Report and Presentation, Preparation for M.Tech Thesis |
Semester 9
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| DE8 | Discipline Elective-VIII (VLSI Focused) | Elective | 3 | Emerging Memory Technologies, Quantum Computing Hardware, Bio-VLSI Interfaces, Advanced Device Characterization, Fault Tolerant VLSI Design |
| EE599 | M.Tech Thesis Part-I | Project | 6 | In-depth Literature Review, Problem Statement Refinement, Methodology Development, Initial Research and Experimentation, Preliminary Results and Analysis |
Semester 10
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EE599 | M.Tech Thesis Part-II | Project | 12 | Advanced Research and Experimentation, Comprehensive Data Analysis, Final Design and Implementation, Thesis Writing and Presentation, Defense of Research Work |
