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MSC in Digital Electronics at Sant Gadge Baba Amravati University
Amravati, Maharashtra
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About the Specialization
What is Digital Electronics at Sant Gadge Baba Amravati University Amravati?
This Digital Electronics program at Sant Gadge Baba Amravati University focuses on advanced concepts in digital system design, microcontrollers, embedded systems, and VLSI technology. It prepares students for the rapidly evolving Indian electronics and semiconductor industry, where demand for skilled professionals in areas like IoT, smart devices, and integrated circuit design is steadily growing. The curriculum emphasizes both theoretical foundations and practical applications crucial for innovation in India''''s tech landscape.
Who Should Apply?
This program is ideal for engineering graduates (B.E./B.Tech) in Electronics, Electrical, or Computer Science, and science graduates (B.Sc.) with a strong foundation in Physics or Electronics, seeking entry into core electronics R&D or design roles. It also suits working professionals eager to upskill in areas like embedded systems, ASIC, and VLSI design to advance their careers in India''''s expanding technology sector, particularly in semiconductor manufacturing and design houses.
Why Choose This Course?
Graduates of this program can expect promising career paths in India as Embedded Systems Engineers, VLSI Design Engineers, Digital Design Engineers, or R&D Scientists. Entry-level salaries typically range from INR 3.5-6 LPA, growing significantly with experience to INR 10-20+ LPA for experienced professionals in leading Indian and MNC firms. The program aligns with industry demands for skilled hardware-software integration and can lead to professional certifications in specific EDA tools or embedded platforms.
Student Success Practices
Foundation Stage
Master Digital & Microcontroller Fundamentals- (Semester 1-2)
Thoroughly grasp Boolean algebra, combinational/sequential logic, and 8051 microcontroller architecture and programming. Practice with logic gates, flip-flops, and simple 8051 programs on simulation software or hardware kits. Focus on understanding the low-level operation of digital systems.
Tools & Resources
Logicly (simulator), Proteus ISIS (for 8051 simulation), 8051 Development Boards, Textbooks like ''''Digital Logic and Computer Design'''' by M. Morris Mano
Career Connection
A strong foundation in these core areas is essential for all digital electronics roles, enabling you to build complex systems later and excelling in technical interviews for embedded and digital design positions.
Develop Strong C++ and Data Structures Skills- (Semester 1-2)
Dedicate time to consistent C++ programming practice, understanding OOP concepts, and implementing various data structures (arrays, linked lists, stacks, queues, trees, graphs) from scratch. Solve algorithmic problems regularly on coding platforms to enhance logical thinking.
Tools & Resources
HackerRank, LeetCode, GeeksforGeeks, VS Code, Dev-C++, Textbook ''''Data Structures and Algorithms in C++'''' by Goodrich, Tamassia, Mount
Career Connection
Proficiency in C++ and data structures is critical for embedded software development, firmware engineering, and any role involving efficient code implementation, which are highly sought after in the Indian tech industry.
Engage Actively in Lab Sessions & Projects- (Semester 1-2)
Beyond mandatory assignments, proactively explore additional experiments or small projects related to Digital System Design and Microcontrollers. Collaborate with peers, debug circuits and code, and document your findings meticulously. This hands-on experience is invaluable.
Tools & Resources
Breadboards, Logic ICs, Microcontroller Kits (e.g., Arduino, ESP32), Digital Multimeter, Oscilloscope
Career Connection
Practical skills are highly valued by employers in India. Active participation in labs builds confidence, problem-solving abilities, and creates a portfolio of projects that can be showcased during interviews.
Intermediate Stage
Explore HDL and FPGA Design- (Semester 3)
Delve deeper into Hardware Description Languages (VHDL/Verilog) and utilize FPGA development boards. Start designing and implementing moderately complex digital systems, focusing on optimizing for area and speed. Participate in online HDL design challenges.
Tools & Resources
Xilinx Vivado/ISE, Intel Quartus Prime, FPGA Development Boards (e.g., Basys 3, DE1-SoC), Verilog/VHDL reference books
Career Connection
FPGA and HDL skills are crucial for roles in ASIC/VLSI design, digital verification, and high-speed embedded systems, offering pathways to specialized jobs in India''''s growing semiconductor sector.
Build IoT and Embedded Systems Projects- (Semester 3)
Apply your knowledge of advanced microcontrollers and communication protocols to create real-world IoT projects. Focus on sensor integration, data transmission, and basic cloud connectivity. Consider projects addressing local community needs or industry problems.
Tools & Resources
Raspberry Pi, NodeMCU (ESP8266/ESP32), Various sensors (DHT11, PIR, LDR), MQTT/HTTP protocols, Firebase/ThingSpeak
Career Connection
IoT and embedded systems are booming fields in India. Hands-on projects demonstrate your ability to integrate hardware and software, making you an attractive candidate for roles in smart devices, automation, and industrial IoT.
Participate in Technical Competitions & Workshops- (Semester 3)
Actively seek out and participate in inter-college or national-level technical competitions, hackathons, and workshops focused on embedded systems, VLSI, or digital electronics. This provides exposure, networking opportunities, and a chance to apply learned concepts under pressure.
Tools & Resources
IEEE student chapters, IIT/NIT tech fests, Industry-led bootcamps
Career Connection
Such participation enriches your resume, helps in building a professional network, and showcases your problem-solving abilities and teamwork to potential employers, which is highly regarded in the competitive Indian job market.
Advanced Stage
Undertake an Industry-Relevant Capstone Project/Dissertation- (Semester 4)
Choose a project that addresses a current industry problem in SoC design, advanced computer architecture, or your chosen elective (e.g., DSP, VLSI, WSN). Aim for innovation, practical implementation, and thorough documentation. Seek mentorship from faculty or industry experts.
Tools & Resources
Advanced EDA tools (Cadence, Synopsys), High-performance microcontrollers, Simulation software, Research papers, IEEE Xplore
Career Connection
A strong capstone project is your most significant asset for placements in India, demonstrating your ability to execute complex design tasks, conduct research, and deliver impactful solutions relevant to the industry''''s needs.
Focus on Advanced Design & Verification Methodologies- (Semester 4)
Beyond basic design, learn about advanced verification techniques (e.g., UVM for VLSI), design for testability (DFT), and hardware security. Understanding these methodologies is critical for high-quality product development in the semiconductor industry.
Tools & Resources
Mentor Graphics QuestaSim, Synopsys VCS, Online courses on advanced verification
Career Connection
Specializing in design and verification methodologies opens doors to high-demand roles like Design Verification Engineer or DFT Engineer, which are crucial and well-paying positions in Indian semiconductor design houses.
Prepare for Placements and Professional Networking- (Semester 4)
Actively participate in campus placement drives, refine your resume and interview skills (technical and HR). Network with alumni and industry professionals through LinkedIn and career fairs. Attend mock interviews to gain confidence and receive feedback.
Tools & Resources
LinkedIn, Company career pages, Placement & Training Cell of the university, Mock interview platforms
Career Connection
Effective placement preparation and networking are key to securing desired job roles in leading Indian and multinational companies, providing access to internship-to-placement opportunities and ensuring a smooth transition into your professional career.
Program Structure and Curriculum
Eligibility:
- No eligibility criteria specified
Duration: 2 years (4 semesters)
Credits: 68 Credits
Assessment: Internal: 20%, External: 80%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| M.Sc. (DE) (Elec.) I-I (Sem-I) | Digital System Design | Core | 4 | Boolean Algebra & Logic Gates, Combinational Logic Circuits, Sequential Logic Circuits, Registers & Counters, Asynchronous Sequential Circuits, Introduction to VHDL |
| M.Sc. (DE) (Elec.) I-II (Sem-I) | Microcontrollers & Embedded Systems | Core | 4 | 8051 Microcontroller Architecture, 8051 Instruction Set & Programming, Interfacing (I/O, Memory), Timers & Counters, Interrupts & Serial Communication, Embedded System Design Concepts |
| M.Sc. (DE) (Elec.) I-III (Sem-I) | Computer Architecture & Organization | Core | 4 | Basic Computer Organization, CPU Design & Instruction Set, Memory System Organization, Input-Output Organization, Pipelining & Parallel Processing |
| M.Sc. (DE) (Elec.) I-P-I (Sem-I) | Practical I (Digital System Design & Microcontrollers) | Lab | 2 | Digital Logic Gates & Combinational Circuits, Sequential Circuits Implementation, 8051 Microcontroller Programming, Interfacing with 8051, VHDL Simulations |
| M.Sc. (DE) (Elec.) I-P-II (Sem-I) | Practical II (Computer Architecture & Organization) | Lab | 2 | Assembly Language Programming, Memory Addressing Modes, CPU Register Operations, I/O Device Simulation, Basic Processor Design Experiments |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| M.Sc. (DE) (Elec.) II-I (Sem-II) | C++ & Data Structures | Core | 4 | C++ Programming Fundamentals, Classes, Objects & OOP Concepts, Inheritance & Polymorphism, Data Structures (Arrays, Linked Lists), Stacks, Queues, Trees, Graphs, Sorting & Searching Algorithms |
| M.Sc. (DE) (Elec.) II-II (Sem-II) | Digital Communication | Core | 4 | Analog to Digital Conversion, Digital Modulation Techniques (ASK, FSK, PSK), Error Control Coding, Data Communication & Networking, OSI Model & Protocols, Spread Spectrum Communication |
| M.Sc. (DE) (Elec.) II-III (Sem-II) | Analog Integrated Circuits | Core | 4 | Operational Amplifiers Characteristics, Op-Amp Applications (Amplifiers, Filters), Active Filters Design, Voltage Regulators (LM317, 78XX), Timer IC (NE555) & PLL (LM565), Data Converters (ADC, DAC) |
| M.Sc. (DE) (Elec.) II-P-III (Sem-II) | Practical III (C++ & Data Structures, Digital Communication) | Lab | 2 | C++ OOPs Programming, Data Structure Implementation, Digital Modulation/Demodulation, Error Detection & Correction, Network Protocol Simulations |
| M.Sc. (DE) (Elec.) II-P-IV (Sem-II) | Practical IV (Analog Integrated Circuits) | Lab | 2 | Op-Amp Basic Circuits, Active Filter Realization, Voltage Regulator Testing, 555 Timer Applications, ADC/DAC Interfacing & Testing |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| M.Sc. (DE) (Elec.) III-I (Sem-III) | Advanced Digital System Design | Core | 4 | Logic Families & Interfacing, Hardware Description Languages (HDL), Combinational & Sequential Logic Design with HDL, FPGA & CPLD Architecture, Design Flow for Programmable Logic, Logic Synthesis & Optimization |
| M.Sc. (DE) (Elec.) III-II (Sem-III) | Advanced Microcontrollers & Embedded System Design | Core | 4 | Advanced Microcontroller Architectures (PIC, ARM), Real-Time Operating Systems (RTOS), Embedded Linux Concepts, Embedded Communication Protocols (I2C, SPI, CAN), Internet of Things (IoT) Fundamentals, Embedded System Debugging & Testing |
| M.Sc. (DE) (Elec.) III-III A (Sem-III) | Digital Signal Processing | Elective | 4 | Signals & Systems Fundamentals, Z-Transform & Inverse Z-Transform, Discrete Fourier Transform (DFT), Fast Fourier Transform (FFT), Digital Filter Design (FIR, IIR), DSP Processors Architecture |
| M.Sc. (DE) (Elec.) III-III B (Sem-III) | ASIC Design | Elective | 4 | ASIC Design Flow, Logic Synthesis & Optimization, Placement & Routing, Static Timing Analysis (STA), Design for Testability (DFT), Low Power ASIC Design |
| M.Sc. (DE) (Elec.) III-III C (Sem-III) | VLSI Design | Elective | 4 | MOS Transistor Theory, CMOS Logic Gates & Design, VLSI Design Styles, Layout Design Rules, Inverter & Combinational Circuit Design, Sequential Circuit Design in CMOS |
| M.Sc. (DE) (Elec.) III-P-V (Sem-III) | Practical V (Advanced Digital System Design & Microcontrollers) | Lab | 2 | FPGA/CPLD Programming with VHDL/Verilog, Advanced Microcontroller Interfacing, RTOS Task Management, IoT Device Communication, HDL-based System Design |
| M.Sc. (DE) (Elec.) III-P-VI (Sem-III) | Practical VI (Elective Paper I) | Lab | 2 | DSP Algorithm Implementation (MATLAB/Scilab), Digital Filter Design, VLSI/ASIC Design Tools (EDA), CMOS Layout Design, HDL Simulation for VLSI |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| M.Sc. (DE) (Elec.) IV-I (Sem-IV) | System On Chip (SOC) Design | Core | 4 | SoC Architecture & Components, IP Core Design & Integration, SoC Verification & Testing, Embedded Software for SoC, Low Power SoC Design Techniques, FPGA-based SoC Implementation |
| M.Sc. (DE) (Elec.) IV-II (Sem-IV) | Advanced Computer Architecture | Core | 4 | Pipelining & Instruction Level Parallelism, Superscalar & Vector Processors, Multiprocessors & Cache Coherence, Memory Hierarchy Design, Interconnection Networks, GPU Architecture |
| M.Sc. (DE) (Elec.) IV-III A (Sem-IV) | CMOS Analog & Mixed Signal Design | Elective | 4 | MOS Device Modeling, Single-Stage CMOS Amplifiers, Differential Amplifiers & Current Mirrors, Bandgap References, CMOS Comparators, Mixed-Signal Circuit Design |
| M.Sc. (DE) (Elec.) IV-III B (Sem-IV) | Wireless Sensor Networks | Elective | 4 | WSN Architecture & Design Principles, MAC Protocols for WSN, Routing Protocols for WSN, Localization & Time Synchronization, Security Challenges in WSN, WSN Applications |
| M.Sc. (DE) (Elec.) IV-III C (Sem-IV) | Biomedical Instrumentation | Elective | 4 | Bioelectric Signals & Electrodes, ECG, EEG, EMG Systems, Medical Imaging Systems (X-ray, CT, MRI), Therapeutic Equipment, Biosensors & Transducers, Patient Monitoring Systems |
| M.Sc. (DE) (Elec.) IV-P-VII (Sem-IV) | Practical VII (SOC Design & Advanced Computer Architecture) | Lab | 2 | SoC Design & Simulation using EDA tools, IP Core Integration, Advanced Processor Design Experiments, Cache Memory Simulation, Multiprocessor System Analysis |
| M.Sc. (DE) (Elec.) IV-P-VIII (Sem-IV) | Practical VIII (Elective Paper II) | Lab | 2 | CMOS Analog Circuit Design & Simulation, Mixed-Signal Design Experiments, Wireless Sensor Node Programming, Biomedical Sensor Interfacing, Data Acquisition from Bio-Signals |
| M.Sc. (DE) (Elec.) IV-PJ (Sem-IV) | Project / Dissertation | Project | 4 | Problem Identification & Literature Survey, System Design & Methodology, Hardware/Software Implementation, Testing & Validation, Report Writing & Presentation |
