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B-TECH in Electronics And Vlsi Engineering Eve at Indraprastha Institute of Information Technology Delhi
Delhi, Delhi
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About the Specialization
What is Electronics and VLSI Engineering (EVE) at Indraprastha Institute of Information Technology Delhi Delhi?
This Electronics and VLSI Engineering (EVE) program at IIIT-Delhi focuses on equipping students with deep knowledge in microelectronics, integrated circuits, and embedded systems. It addresses the growing demand for skilled engineers in India''''s semiconductor and electronics manufacturing sectors. The curriculum emphasizes both theoretical foundations and practical application, preparing graduates for cutting-edge roles in a rapidly evolving industry.
Who Should Apply?
This program is ideal for aspiring engineers passionate about designing and developing electronic systems, from chip-level components to complex embedded solutions. It suits fresh graduates aiming for R&D roles in semiconductor firms, product design companies, or those looking to pursue higher studies in VLSI or related fields. Strong analytical and problem-solving skills are beneficial prerequisites.
Why Choose This Course?
Graduates of this program can expect to secure roles as VLSI design engineers, embedded systems developers, firmware engineers, or hardware architects in top Indian and multinational companies. Entry-level salaries typically range from INR 6-12 LPA, with significant growth potential up to INR 25+ LPA for experienced professionals. The curriculum also prepares students for advanced certifications and specialized research in microelectronics.
Student Success Practices
Foundation Stage
Build a Strong Mathematical and Programming Core- (Semester 1-2)
Dedicate significant effort to mastering Linear Algebra, Probability, and Introduction to Programming. These subjects form the bedrock for advanced EVE concepts. Practice coding regularly to build logical thinking and problem-solving skills crucial for digital design and embedded systems.
Tools & Resources
NPTEL courses for Math, HackerRank/LeetCode for programming, GeeksforGeeks, Khan Academy for fundamental concepts
Career Connection
A solid foundation in math and programming is essential for understanding circuit analysis, signal processing, and for securing internships in core EVE roles or software-defined hardware roles.
Engage Actively in Lab Work and Mini-Projects- (Semester 1-2)
Beyond theoretical understanding, hands-on experience in labs (like Introduction to EVE, Digital Logic & Design, Circuit Analysis) is paramount. Take initiative to build mini-projects using development boards like Arduino/Raspberry Pi to apply learned concepts.
Tools & Resources
Arduino/Raspberry Pi kits, Breadboards and basic electronic components, Online tutorials (e.g., Adafruit, SparkFun)
Career Connection
Practical skills gained from labs and projects are highly valued by employers for entry-level engineering roles and provide a strong portfolio for advanced studies.
Cultivate Effective Communication Skills- (Semester 1-2)
Utilize the Professional Communication course to enhance technical writing, presentation, and interpersonal skills. Participate in debates, group discussions, and club activities to refine verbal communication, which is crucial for collaborating in team projects and client interactions.
Tools & Resources
Grammarly, Toastmasters International, IIIT-Delhi Communication Lab resources
Career Connection
Strong communication skills differentiate candidates in job interviews and enable effective teamwork, leading to better project outcomes and career progression.
Intermediate Stage
Deep Dive into VLSI and Embedded Systems Core- (Semester 3-5)
Focus intently on core EVE subjects like Analog Electronics, Signals & Systems, Microprocessors, DSP, and VLSI Design. Participate in advanced lab sessions and explore open-source tools for circuit simulation and FPGA programming beyond coursework.
Tools & Resources
LTSpice/Cadence Virtuoso for Analog Design, Xilinx Vivado/Intel Quartus for FPGA, MATLAB/Python for DSP, EDA Playground
Career Connection
Proficiency in these core areas is directly linked to securing specialized internships and full-time positions in semiconductor companies, product development, and research institutions.
Seek Industry Internships and Workshops- (Semester 3-5)
Actively apply for summer internships at electronics, semiconductor, or embedded systems companies in India. Attend industry-specific workshops and seminars to understand current trends and network with professionals.
Tools & Resources
IIIT-Delhi Placement Cell resources, LinkedIn, Industry event calendars (e.g., SemiconIndia events)
Career Connection
Internships provide invaluable real-world experience, help in building a professional network, and often lead to pre-placement offers, significantly boosting career prospects.
Participate in Technical Competitions and Hackathons- (Semester 3-5)
Join national-level technical competitions (e.g., Smart India Hackathon, robotics challenges) or organize internal hackathons. This fosters innovative problem-solving, teamwork, and the application of theoretical knowledge to practical scenarios.
Tools & Resources
Online challenge platforms, Mentorship from faculty and seniors, Departmental technical clubs
Career Connection
Winning or even participating actively in competitions enhances your resume, demonstrates initiative, and provides unique talking points during interviews, making you stand out.
Advanced Stage
Specialize through Electives and Advanced Projects- (Semester 6-8)
Strategically choose EVE electives that align with your career aspirations (e.g., advanced VLSI, RF circuits, embedded AI). Engage in a significant B.Tech project that allows for deep specialization, potentially leading to publications or patented work.
Tools & Resources
Advanced EDA tools (Cadence, Synopsys), Research papers and journals (IEEE Xplore), Faculty research labs
Career Connection
Specialized knowledge and a strong final-year project are crucial for securing roles in R&D, pursuing Masters/PhD, or launching a startup in niche EVE domains.
Intensive Placement and Interview Preparation- (Semester 6-8)
Dedicate time to rigorous preparation for placement drives, focusing on technical aptitude, core EVE concepts, data structures and algorithms, and communication skills. Practice mock interviews with peers and career counselors.
Tools & Resources
Placement cell workshops, Company-specific previous year questions, Interview prep platforms (e.g., InterviewBit)
Career Connection
Thorough preparation ensures you are interview-ready for top companies visiting the campus, maximizing your chances of securing a high-quality job offer.
Cultivate a Professional Network- (Semester 6-8)
Maintain connections with alumni, industry professionals, and faculty. Attend conferences, webinars, and alumni meet-ups. This network can provide mentorship, career opportunities, and insights into industry trends.
Tools & Resources
LinkedIn, Professional organizations (e.g., IEEE Student Chapter), Alumni association events
Career Connection
A robust professional network opens doors to opportunities beyond campus placements, aids in career transitions, and provides lifelong learning and support.
Program Structure and Curriculum
Eligibility:
- Admission primarily through Joint Admission Counselling Delhi (JAC Delhi) based on JEE Main Rank, with specific Class 12th board performance requirements. Direct Admission of Students Abroad (DASA) and other specific categories also exist. Exact criteria are published annually for admission.
Duration: 8 semesters / 4 years
Credits: 160 Credits
Assessment: Internal: undefined, External: undefined
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE100 | Introduction to EVE | Core | 2 | Overview of Electronics and VLSI Engineering, Basic electronic components and circuits, Introduction to semiconductor devices, Applications of EVE in modern technology, Laboratory safety and fundamental measurement techniques |
| CSD101 | Introduction to Programming | Core | 4 | Programming language fundamentals (e.g., C/C++), Variables, data types, and operators, Control flow statements (conditional, loops), Functions, arrays, and pointers, Basic problem-solving and algorithm design |
| MTH101 | Linear Algebra | Science & Engineering | 4 | Vector spaces and subspaces, Matrices, determinants, and systems of linear equations, Eigenvalues, eigenvectors, and diagonalization, Linear transformations, Orthogonality and inner product spaces |
| PHY101 | Electromagnetism and Quantum Mechanics | Science & Engineering | 4 | Maxwell''''s equations and electromagnetic waves, Electric and magnetic fields in matter, Introduction to quantum mechanics, Schrodinger equation and its applications, Atomic structure and quantum phenomena |
| HSS101 | Professional Communication | Humanities & Social Sciences | 3 | Principles of effective technical communication, Technical report writing and documentation, Oral presentation skills and public speaking, Interpersonal communication and professional etiquette, Critical thinking and analytical writing |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE101 | Digital Logic & Design | Core | 4 | Boolean algebra and logic gates, Combinational logic circuit design, Sequential logic circuits (flip-flops, counters, registers), Finite state machines, Introduction to Hardware Description Languages (VHDL/Verilog) and FPGAs |
| EVE102 | Circuit Analysis | Core | 4 | Kirchhoff''''s laws and Ohm''''s law, Network theorems (Thevenin, Norton, Superposition), DC and AC circuit analysis, Transient response of RL, RC, RLC circuits, Frequency response and resonance |
| MTH102 | Probability and Statistics | Science & Engineering | 4 | Basic probability theory and axioms, Random variables and probability distributions, Joint and conditional probability, Hypothesis testing and confidence intervals, Regression and correlation analysis |
| PHY102 | Waves, Optics and Modern Physics | Science & Engineering | 4 | Wave phenomena (superposition, interference, diffraction), Geometrical and physical optics, Lasers and their applications, Introduction to special relativity, Nuclear physics and radioactivity |
| HSS Elective 1 | HSS Elective 1 | Humanities & Social Sciences | 3 | Topics vary based on chosen elective (e.g., Economics, Psychology, Philosophy), Social and ethical implications of technology, Human behavior and cognition, Cultural studies and diversity, Analytical reasoning and critical thinking |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE201 | Analog Electronics | Core | 4 | Diode characteristics and applications, Bipolar Junction Transistors (BJTs) and biasing, MOSFETs (Metal-Oxide-Semiconductor Field-Effect Transistors), Basic amplifier configurations, Operational amplifiers (Op-Amps) and their circuits |
| EVE202 | Signals & Systems | Core | 4 | Continuous-time and discrete-time signals, Linear Time-Invariant (LTI) systems, Fourier series and Fourier transform, Laplace transform and Z-transform, Convolution, correlation, and spectral analysis |
| CSD201 | Data Structures and Algorithms | Core | 4 | Arrays, linked lists, stacks, and queues, Trees (binary trees, BSTs, AVL trees), Graphs (representation, traversal algorithms), Sorting and searching algorithms, Algorithm analysis (time and space complexity) |
| MTH201 | Differential Equations | Science & Engineering | 4 | First-order ordinary differential equations (ODEs), Higher-order linear ODEs, Series solutions of ODEs, Laplace transforms and inverse Laplace transforms for ODEs, Introduction to partial differential equations (PDEs) |
| HSS Elective 2 | HSS Elective 2 | Humanities & Social Sciences | 3 | Topics vary based on chosen elective (e.g., Literature, Fine Arts, Public Policy), Creative expression and critical appreciation, Historical and contemporary societal issues, Impact of technology on society, Ethical considerations in professional practice |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE203 | Microprocessors & Microcontrollers | Core | 4 | Microprocessor (e.g., 8086) architecture and instruction set, Microcontroller (e.g., 8051) architecture and programming, Assembly language programming, Memory and I/O interfacing techniques, Interrupts, timers, and serial communication |
| EVE204 | Electromagnetic Fields & Waves | Core | 4 | Vector calculus and coordinate systems, Electrostatic and magnetostatic fields, Maxwell''''s equations in differential and integral forms, Time-varying fields and Poynting vector, Plane wave propagation and transmission lines |
| EVE205 | Digital Signal Processing | Core | 4 | Sampling theorem and quantization, Discrete Fourier Transform (DFT) and Fast Fourier Transform (FFT), Z-transform and its properties, Finite Impulse Response (FIR) filter design, Infinite Impulse Response (IIR) filter design |
| MTH202 | Discrete Mathematics | Science & Engineering | 4 | Set theory and propositional logic, Relations, functions, and recurrence relations, Counting principles (permutations, combinations), Graph theory (paths, cycles, trees), Boolean algebra and lattice theory |
| HSS Elective 3 | HSS Elective 3 | Humanities & Social Sciences | 3 | Topics vary based on chosen elective (e.g., Sociology, Environmental Studies, Indian Constitution), Governance and public policy in India, Environmental sustainability and engineering solutions, Diversity and inclusion in professional settings, Global challenges and technological responses |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE301 | VLSI Design | Core | 4 | CMOS device physics and manufacturing technology, CMOS inverter and logic gates characterization, Circuit design styles and scaling, Layout design and design rules, Static timing analysis and power estimation |
| EVE302 | Control Systems | Core | 4 | Open-loop and closed-loop control systems, Mathematical modeling of dynamic systems, Time-domain and frequency-domain analysis, Stability analysis (Routh-Hurwitz, Nyquist criteria, Root Locus), PID controllers and compensator design |
| EVE303 | Communication Systems | Core | 4 | Amplitude Modulation (AM) and demodulation techniques, Frequency Modulation (FM) and Phase Modulation (PM), Pulse Modulation (PAM, PWM, PPM) and PCM, Digital modulation schemes (ASK, FSK, PSK, QAM), Noise in communication systems and channel capacity |
| EVE Elective 1 | EVE Elective 1 | Elective | 4 | Advanced Digital System Design, Image and Video Processing, RF Circuits and Systems, Power Electronics, Biomedical Instrumentation |
| HSS Elective 4 | HSS Elective 4 | Humanities & Social Sciences | 3 | Topics vary based on chosen elective, Innovation and entrepreneurship, Principles of leadership and teamwork, Intellectual Property Rights (IPR), Global economy and technological trends |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE304 | Analog Integrated Circuits | Core | 4 | CMOS differential amplifiers and current mirrors, Operational amplifier design (gain, bandwidth, stability), Frequency response of analog circuits, Voltage references and current sources, Analog-to-Digital and Digital-to-Analog Converters (ADCs/DACs) |
| EVE305 | Embedded Systems | Core | 4 | Embedded processor architectures and programming, Real-Time Operating Systems (RTOS) concepts, Interfacing with sensors and actuators, Embedded communication protocols (I2C, SPI, UART), Introduction to Internet of Things (IoT) applications |
| EVE Elective 2 | EVE Elective 2 | Elective | 4 | VLSI Testing and Verification, Design for Testability (DFT), Low Power VLSI Design, Advanced Microcontroller Systems, Digital System Design using FPGAs |
| EVE Elective 3 | EVE Elective 3 | Elective | 4 | Semiconductor Device Physics and Modeling, MEMS and Nanotechnology, Optical Fiber Communication, Wireless Communication Systems, Robotics and Automation |
| HSS Elective 5 | HSS Elective 5 | Humanities & Social Sciences | 3 | Topics vary based on chosen elective, Professional ethics and values, Organizational behavior and management, Entrepreneurial ecosystem in India, Sustainable engineering practices |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE Elective 4 | EVE Elective 4 | Elective | 4 | Computer Architecture for VLSI, Hardware Security and Trust, Design Automation for VLSI (EDA), Embedded Machine Learning, Mixed-Signal IC Design |
| EVE Elective 5 | EVE Elective 5 | Elective | 4 | Advanced Digital Signal Processing, Speech and Audio Processing, Medical Imaging Systems, Quantum Computing Hardware, Cognitive Radio Systems |
| EVE Elective 6 | EVE Elective 6 | Elective | 4 | High-Speed Communication Circuits, Antenna Theory and Design, Microwave and Millimeter-wave Circuits, Satellite Communication Systems, Advanced Analog Circuit Design |
| EVE Elective 7 | EVE Elective 7 | Elective | 4 | VLSI Fabrication Technology, Advanced Semiconductor Devices, Reliability of Electronic Systems, Automotive Electronics, Wearable and Flexible Electronics |
| EVE Project 1 | B.Tech Project Part 1 | Project | 4 | Problem identification and literature review, Defining project objectives and scope, Methodology development and preliminary design, Initial simulations or prototype planning, Mid-term report and presentation |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| EVE Elective 8 | EVE Elective 8 | Elective | 4 | System-on-Chip (SoC) Design, Advanced VLSI Architectures, Hardware-Software Co-design, Memory Design and Architectures, Emerging Technologies in VLSI |
| EVE Elective 9 | EVE Elective 9 | Elective | 4 | Embedded Systems for IoT, Cyber-Physical Systems, Real-Time Embedded Systems, Hardware Accelerators for AI, Network-on-Chip (NoC) |
| EVE Elective 10 | EVE Elective 10 | Elective | 4 | Deep Learning Hardware, Bio-MEMS and Microsystems, Flexible and Stretchable Electronics, Quantum Sensors, Advanced Control Systems |
| EVE Project 2 | B.Tech Project Part 2 | Project | 4 | Detailed design and implementation, Prototyping and testing of the system, Performance evaluation and optimization, Comprehensive final report writing, Final presentation and demonstration |
