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M-TECH in Embedded Systems at Symbiosis International University
Pune, Maharashtra
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About the Specialization
What is Embedded Systems at Symbiosis International University Pune?
This Embedded Systems program at Symbiosis International University, Pune, focuses on designing, developing, and optimizing hardware and software for specialized computing devices. It addresses the growing need for skilled professionals in India''''s rapidly expanding IoT, automotive, and industrial automation sectors, offering a blend of theoretical depth and practical application critical for cutting-edge product development.
Who Should Apply?
This program is ideal for engineering graduates, especially from Electronics, Telecommunication, Computer Science, and IT backgrounds, seeking to specialize in product-centric design. It also suits working professionals aiming to upskill in embedded technologies, IoT, or real-time systems, enabling career advancement in a high-demand industry.
Why Choose This Course?
Graduates of this program can expect to pursue roles as Embedded Software Engineers, IoT Developers, Hardware Design Engineers, or Firmware Developers in India. Entry-level salaries typically range from INR 6-10 LPA, with experienced professionals earning significantly more. The curriculum prepares students for global certifications and leadership roles in R&D.
Student Success Practices
Foundation Stage
Strengthen Core Engineering Fundamentals- (Semester 1-2)
Dedicate time to revisit and solidify foundational concepts in digital electronics, microcontrollers, and C/C++ programming. This strong base is crucial for advanced embedded systems topics. Utilize online courses, NPTEL lectures, and textbooks to ensure concept clarity.
Tools & Resources
NPTEL courses, Coursera/edX for C/C++, Textbooks on Digital Logic and Microcontrollers
Career Connection
A robust foundation prevents conceptual hurdles in later semesters and directly translates to better performance in technical interviews for embedded roles.
Master Programming & Debugging Skills- (Semester 1-2)
Regularly practice embedded C/C++ programming on development boards like Arduino/Raspberry Pi. Focus on writing efficient, low-level code and actively learn to use debugging tools like JTAG/SWD debuggers, oscilloscopes, and logic analyzers to troubleshoot hardware-software interactions effectively.
Tools & Resources
Arduino/Raspberry Pi kits, Embedded C/C++ compilers, JTAG/SWD debuggers, Logic analyzers (simulated or physical)
Career Connection
Proficiency in coding and debugging on embedded platforms is a core requirement for nearly all embedded engineering positions, making candidates highly desirable for product development roles.
Engage in Early Project Development- (Semester 1-2)
Start working on small, self-initiated projects early on, even before formal project courses. Begin with simple sensor interfacing, LED control, or basic IoT applications. Document your code and hardware designs thoroughly to build a portfolio.
Tools & Resources
GitHub for code versioning, KiCad/Eagle for basic schematics, Online tutorials and maker communities
Career Connection
Practical project experience demonstrates initiative and problem-solving abilities, which are highly valued by recruiters, especially in the competitive Indian embedded industry.
Intermediate Stage
Deep Dive into RTOS and Embedded Linux- (Semester 2-3)
Gain hands-on experience with Real-time Operating Systems (RTOS) like FreeRTOS/Zephyr and Embedded Linux. Understand task scheduling, inter-process communication, memory management, and device drivers by implementing small applications on suitable hardware platforms.
Tools & Resources
FreeRTOS/Zephyr documentation, Embedded Linux tutorials, ARM Cortex-M development boards, BeagleBone Black
Career Connection
Expertise in RTOS and Embedded Linux is critical for advanced embedded systems development, unlocking opportunities in roles requiring complex system design and high-performance embedded solutions.
Pursue Internships and Industry Mentorship- (Semester 2-3)
Actively seek internships or part-time projects in embedded systems companies, either locally in Pune or in major tech hubs. Network with industry professionals and secure mentorship to gain insights into real-world engineering practices and project cycles.
Tools & Resources
LinkedIn, College placement cell, Industry events and workshops
Career Connection
Internships provide invaluable practical exposure, build industry connections, and often lead to pre-placement offers, significantly enhancing career prospects post-graduation.
Participate in Technical Competitions & Hackathons- (Semester 2-3)
Join embedded systems specific hackathons or technical competitions focused on IoT, robotics, or smart devices. This fosters rapid prototyping, teamwork, and innovative problem-solving skills under time pressure, and exposes you to new technologies.
Tools & Resources
Major tech festival websites, Hackerearth/Devpost platforms, Relevant industry forums
Career Connection
Advanced Stage
Specialize in a Niche Embedded Area- (Semester 3-4)
Identify a specific area within embedded systems (e.g., Automotive, IoT Security, Edge AI, FPGA design) and develop deep expertise through advanced coursework, certifications, and dedicated projects. This specialization makes you a subject matter expert.
Tools & Resources
Specialized online courses (e.g., Udemy, edX), Vendor-specific certifications (e.g., ARM, NXP), Advanced research papers
Career Connection
Niche specialization provides a competitive edge, allowing you to target specific high-value roles and potentially command higher salaries in the specialized segment of the embedded industry.
Develop a Strong Dissertation/Thesis Project- (Semester 3-4)
Choose a challenging and industry-relevant dissertation topic. Focus on innovation, rigorous methodology, and a high-quality implementation. Document your work meticulously, emphasizing the problem, solution, and contributions.
Tools & Resources
Academic databases (IEEE Xplore), Research guidance from faculty, Advanced simulation tools
Career Connection
A robust dissertation showcases advanced research capabilities, deep technical knowledge, and the ability to undertake significant engineering challenges, highly attractive to R&D roles and further academic pursuits.
Prepare for Placements & Professional Growth- (Semester 3-4)
Regularly practice aptitude tests, technical interview questions (especially embedded C, data structures, RTOS), and soft skills. Prepare a compelling resume and LinkedIn profile highlighting projects and skills. Network proactively for job opportunities and career guidance.
Tools & Resources
Placement cell resources, Mock interview platforms, Networking events, Industry-focused job portals
Career Connection
Thorough preparation ensures you are interview-ready and can effectively articulate your skills and experience, maximizing your chances of securing desirable placements in top embedded companies.
Program Structure and Curriculum
Eligibility:
- B.E./B.Tech. in Electronics, Electronics & Telecommunication, Instrumentation, Computer Engineering, Information Technology, or Computer Science from any AICTE approved institute with minimum 50% marks (45% for SC/ST).
Duration: 2 years (4 semesters)
Credits: 65 Credits
Assessment: Internal: 50%, External: 50%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTP101 | Research Methodology & IPR | Core | 3 | Research problem identification, Literature review techniques, Research design and methods, Data collection and analysis, Intellectual Property Rights (IPR), Patent filing and ethics |
| MTP102 | Advanced Mathematics for Engineers | Core | 3 | Linear Algebra and Matrices, Vector Calculus and Transforms, Probability and Statistics, Optimization Techniques, Stochastic Processes, Numerical methods for engineering |
| MTPC01 | Advanced Digital Signal Processing | Elective (Common Pool for E&TC) | 3 | DSP fundamentals and applications, Multirate signal processing, Adaptive filters and estimation, Wavelet transforms, DSP processor architectures, Speech and image processing basics |
| MTPC02 | VLSI Design | Elective (Common Pool for E&TC) | 3 | MOS transistor theory, CMOS logic circuits, VLSI fabrication process, Design flow and tools (HDL), Low power VLSI design, FPGA architectures and applications |
| MTPL01 | Advanced Digital Signal Processing Lab | Lab (Based on Elective I) | 1 | MATLAB for DSP algorithms, Filter design and implementation, Spectral analysis techniques, Real-time DSP experiments |
| MTPL02 | VLSI Design Lab | Lab (Based on Elective II) | 1 | Verilog/VHDL programming, CMOS circuit simulation, FPGA based design implementation, ASIC design flow concepts |
| MTPS01 | Seminar | Core | 1 | Technical paper presentation, Literature survey, Public speaking skills, Research topic exploration |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTP201 | Advanced Computer Networks | Core | 3 | Network architectures and protocols, Wireless and mobile networks, Network security principles, Internet of Things (IoT) networking, Software Defined Networking (SDN), Cloud networking concepts |
| MTPC03 | Advanced Embedded Systems | Core (Specialization Foundation) | 3 | Embedded processor architectures, Real-time Operating Systems (RTOS), Device drivers and BSP, Embedded communication protocols, Embedded system design methodologies, Debugging and testing techniques |
| MTPC04 | Mobile Computing | Elective (Common Pool for E&TC) | 3 | Wireless communication technologies, Mobile IP and ad-hoc networks, Wireless sensor networks, Mobile operating systems, Location-based services, Context-aware computing |
| MTPL03 | Advanced Embedded Systems Lab | Lab | 1 | Microcontroller/Microprocessor interfacing, RTOS kernel porting and programming, Embedded Linux development, IoT device programming and connectivity |
| MTPF01 | Foundation Project | Project | 5 | Problem identification and definition, Literature survey and analysis, Project planning and design, Preliminary implementation and testing, Report writing and presentation |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTPE01 | Real-time Systems | Specialization Elective | 3 | Real-time scheduling algorithms, RTOS concepts and services, Concurrency control and synchronization, Real-time communication protocols, Fault tolerance in RT systems, Distributed real-time systems |
| MTPE02 | IoT Architectures & Protocols | Specialization Elective | 3 | IoT ecosystem and reference model, Sensor and actuator technologies, IoT communication protocols (MQTT, CoAP), Cloud platforms for IoT (AWS IoT, Azure IoT), Edge and Fog computing, IoT security and privacy |
| MTPL04 | Real-time Systems & IoT Lab | Lab (Based on Specialization Electives) | 1 | RTOS kernel experiments, Real-time task synchronization, Sensor integration with embedded platforms, IoT device to cloud connectivity, Data acquisition and processing for IoT |
| MTPD01 | Dissertation Part I | Project | 8 | Problem definition and scope, Comprehensive literature survey, Research methodology design, Preliminary system design and architecture, Tool selection and justification |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTPI01 | Internship / Industry Project | Project | 8 | Industry problem solving, Real-world project implementation, Professional communication and teamwork, Application of theoretical knowledge, Report writing and presentation |
| MTPD02 | Dissertation Part II | Project | 12 | Advanced system implementation, Experimentation and data analysis, Results interpretation and discussion, Thesis writing and documentation, Viva-voce and defense |
