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M-TECH in Electronics Design And Technology at GITAM, Gandhi Institute of Technology and Management
Visakhapatnam, Andhra Pradesh
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About the Specialization
What is Electronics Design and Technology at GITAM, Gandhi Institute of Technology and Management Visakhapatnam?
This M.Tech in Electronics Design and Technology program at GITAM focuses on advanced concepts in VLSI design, embedded systems, and signal processing. It is highly relevant for India''''s burgeoning semiconductor industry, driving innovation in areas like IoT, AI hardware, and consumer electronics. The program aims to create highly skilled engineers for complex electronic system development.
Who Should Apply?
This program is ideal for engineering graduates with a B.E./B.Tech in ECE, EEE, Instrumentation, or related fields, seeking to specialize in cutting-edge electronics. It also caters to working professionals aiming to upskill in VLSI, embedded systems, or DSP, preparing them for advanced design and R&D roles within the Indian technology sector.
Why Choose This Course?
Graduates of this program can expect promising career paths in VLSI design, embedded software development, hardware verification, and R&D roles in companies like Intel, Qualcomm, Texas Instruments, and Indian startups. Entry-level salaries typically range from INR 6-10 LPA, growing significantly with experience. It prepares students for roles contributing to India''''s ''''Make in India'''' and ''''Digital India'''' initiatives.
Student Success Practices
Foundation Stage
Master Core Concepts and Analog Design- (Semester 1-2)
Focus intensely on fundamental subjects like Digital System Design, Analog & Mixed-Signal VLSI, and Embedded System Design. Dedicate time to understanding analog circuit behavior and design principles, which are critical for advanced electronics.
Tools & Resources
Cadence Virtuoso, Synopsys Design Compiler, Verilog/VHDL simulators, NPTEL courses on VLSI/Embedded Systems
Career Connection
A strong foundation in these areas is essential for entry-level design, verification, and embedded software engineering roles in the semiconductor industry.
Develop Hands-on Lab Skills- (Semester 1-2)
Actively participate in labs like Advanced Digital System Design Lab and Analog & Mixed-Signal VLSI Design Lab. Master the use of EDA tools for simulation, synthesis, and layout. Experiment beyond prescribed exercises to build a portfolio of practical designs.
Tools & Resources
Xilinx Vivado, Intel Quartus Prime, Raspberry Pi/Arduino kits, Online tutorials
Career Connection
Practical skills are highly valued by employers. Proficiency in EDA tools and hardware development accelerates placement in core engineering positions.
Engage in Early Project Work and Elective Exploration- (Semester 2)
Utilize the Mini Project opportunity in Semester 2 to apply learned concepts. Explore program electives like VLSI Testing or IoT to identify areas of deeper interest and potential specialization early on, helping to shape future career goals.
Tools & Resources
IEEE Xplore, ResearchGate, Academic journals, Department faculty advisors
Career Connection
Early project experience and focused elective choices showcase initiative and direction, making students more attractive to recruiters seeking specialized talent.
Intermediate Stage
Intensify Project-Based Learning- (Semester 3)
Dedicate significant effort to Project Work - I. Choose a project topic aligned with your specialization interests, aiming for novel solutions or significant improvements to existing systems. Collaborate with faculty and peers for effective problem-solving.
Tools & Resources
Jupyter Notebooks, MATLAB/Simulink, GitHub for version control, Research papers
Career Connection
A well-executed project demonstrates independent research capability, problem-solving skills, and a deeper understanding of the chosen domain, critical for R&D and design roles.
Deepen Specialization through Electives- (Semester 3)
Strategically select Electives IV and V (e.g., ASIC Design, SoC Verification) to build expertise in a niche area. Go beyond lectures by reading research papers and attempting mini-projects related to these advanced topics to gain a competitive edge.
Tools & Resources
Industry whitepapers, Specialized EDA tools, Online certification platforms (e.g., Coursera, Udemy for advanced topics)
Career Connection
Demonstrable expertise in specialized areas like ASIC or SoC verification directly addresses specific industry demands, opening doors to highly specialized job roles and higher compensation.
Seek Internships and Industry Exposure- (After Semester 2 / During Semester 3)
Proactively look for internships in core electronics companies during the summer after Semester 2 or integrate it into Project Work - I if possible. This provides invaluable real-world experience and helps build industry connections.
Tools & Resources
LinkedIn, Company career pages, Department placement cell, Networking events
Career Connection
Internships often lead to pre-placement offers (PPOs) and significantly enhance your resume, making you a preferred candidate for full-time positions in your chosen field.
Advanced Stage
Execute and Refine Capstone Project- (Semester 4)
The Project Work - II is your capstone. Aim for a high-quality, impactful outcome. Focus on thorough testing, performance optimization, and professional documentation. Prepare for a strong thesis defense and potential publication.
Tools & Resources
Advanced simulation tools, Hardware prototypes, Technical writing guides, Presentation skills workshops
Career Connection
A successful capstone project is the strongest evidence of your engineering capabilities, directly showcasing your readiness for R&D, design, or lead engineering roles.
Prepare for Placements and Technical Interviews- (Semester 4)
Intensively practice technical interview questions related to VLSI, embedded systems, and DSP. Brush up on core concepts, algorithms, and design problems. Develop strong communication skills for group discussions and HR rounds.
Tools & Resources
GeeksforGeeks, LeetCode, Cracking the Coding Interview, Mock interviews
Career Connection
Thorough preparation directly translates to successful interview performance, securing placements in top-tier companies within the electronics design and technology sector.
Network and Professional Development- (Throughout the program, intensifying in Semester 4)
Attend industry conferences, workshops, and technical talks. Engage with professionals on platforms like LinkedIn. Consider joining professional bodies like IEEE. Continuously update skills with emerging technologies beyond the curriculum.
Tools & Resources
IEEE membership, Technical webinars, Professional networking events
Career Connection
Networking expands your career opportunities, provides insights into industry trends, and can lead to mentorship, fostering long-term professional growth and leadership potential.
Program Structure and Curriculum
Eligibility:
- A pass in B.E./B.Tech./AMIE in Electrical & Electronics Engineering/ Electronics & Communication Engineering/ Instrumentation Technology / Telecommunications / Biomedical Engineering / Computer Science and Engineering / Information Technology / M.Sc. (Electronics / Applied Electronics / Instrumentation) or equivalent with at least 50% aggregate marks.
Duration: 4 semesters / 2 years
Credits: 71 Credits
Assessment: Internal: 40%, External: 60%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| GRMTE101 | Research Methodology and IPR | Mandatory Non-Credit Course | 0 | Research problem formulation, Research design, Data collection and analysis, Report writing and presentation, Intellectual property rights, Patents and copyrights |
| GPCPE101 | Digital System Design Using HDL | Core | 3 | VHDL/Verilog language constructs, Combinational circuit design, Sequential circuit design, Design of finite state machines, FPGA-based design, Synthesis and simulation |
| GPCPE102 | Analog and Mixed-Signal VLSI Design | Core | 3 | CMOS technology and device modeling, Single-stage amplifiers, Differential amplifiers, Current mirrors, Operational amplifiers, Mixed-signal concepts |
| GPCPE103 | Advanced Digital Signal Processing | Core | 3 | Discrete-time signals and systems, DFT and FFT algorithms, IIR and FIR filter design, Multirate signal processing, Adaptive filters, Wavelet transforms |
| GPCPE104 | Embedded System Design | Core | 3 | Embedded system architecture, Microcontrollers and DSPs, Memory organization, Input/Output interfacing, Real-time operating systems (RTOS), Embedded software development |
| GPCPE105 | Advanced Digital System Design Lab | Lab | 1.5 | HDL programming for digital circuits, FPGA synthesis and implementation, Design of complex digital systems, Verification and testing, Timing analysis |
| GPCPE106 | Analog and Mixed-Signal VLSI Design Lab | Lab | 1.5 | SPICE simulations of CMOS circuits, Design of current mirrors and amplifiers, Op-amp design and characterization, Layout design of analog circuits, Mixed-signal circuit simulation |
| GEMPE101 | Program Elective-I (Example: Data Converters) | Elective | 3 | Sampling and quantization, Digital to Analog Converters (DAC), Analog to Digital Converters (ADC), Nyquist rate converters, Oversampling converters, Performance metrics of data converters |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| GPEPE201 | Program Elective-II (Example: VLSI Testing) | Elective | 3 | Fault modeling, Test generation for combinational circuits, Test generation for sequential circuits, Design for Testability (DFT), Built-in Self-Test (BIST), Boundary scan techniques |
| GPEPE202 | Program Elective-III (Example: Physical Design Automation) | Elective | 3 | VLSI design flow, Partitioning algorithms, Placement algorithms, Routing algorithms, Clock tree synthesis, Design rule checking |
| GPCPE201 | Design of Analog and Mixed Signal Circuits | Core | 3 | Feedback and stability, Voltage references and regulators, Phase-locked loops (PLLs), Bandgap references, Oscillators and mixers, Switched-capacitor circuits |
| GPCPE202 | VLSI Technology and Fabrication | Core | 3 | Crystal growth and wafer preparation, Oxidation and diffusion, Ion implantation, Lithography and etching, Thin film deposition, CMOS fabrication process |
| GPCPE203 | Advanced Embedded System Lab | Lab | 1.5 | ARM processor architecture, RTOS implementation, Device driver development, Network protocols on embedded systems, Embedded system project development |
| GPCPE204 | Mini Project with Seminar | Project | 2 | Project proposal formulation, Literature survey, Design and implementation, Testing and validation, Report writing, Technical seminar presentation |
| GEMOE201 | Open Elective (Example: Business Analytics) | Elective | 3 | Introduction to Business Analytics, Descriptive Analytics, Predictive Analytics, Prescriptive Analytics, Data visualization, Decision making tools |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| GPCPE391 | Project Work - I | Project | 10 | Problem identification and literature review, Project planning and scope definition, Preliminary design and methodology, Simulation and initial results, Mid-term presentation, Project documentation |
| GPEPE301 | Program Elective-IV (Example: ASIC Design) | Elective | 3 | ASIC design flow, Standard cell library, Gate arrays, Full custom design, Static timing analysis, Power analysis |
| GPEPE302 | Program Elective-V (Example: System on Chip Verification) | Elective | 3 | Verification methodologies, Coverage driven verification, UVM (Universal Verification Methodology), Assertions and formal verification, Testbench architecture, Verification planning |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| GPCPE491 | Project Work - II | Project | 16 | Advanced design and implementation, Extensive testing and validation, Performance optimization, Final results and analysis, Thesis writing, Project defense and presentation |
