Curriculum Overview for Electrical Engineering at Gyanodaya University Neemuch
The curriculum of the Electrical Engineering program at Gyanodaya University Neemuch is meticulously designed to ensure a balanced blend of theoretical knowledge and practical application, preparing students for both industry roles and further academic pursuits. The program spans eight semesters, each building upon previous learnings while introducing new concepts and skills essential for modern engineering practice.
Course Structure Across Eight Semesters
| Semester | Course Code | Course Title | Credit Structure (L-T-P-C) | Pre-requisites |
|---|---|---|---|---|
| 1 | EE101 | Mathematics I | 3-1-0-4 | - |
| 1 | EE102 | Physics for Electrical Engineering | 3-1-0-4 | - |
| 1 | EE103 | Introduction to Electrical Engineering | 2-0-0-2 | - |
| 1 | EE104 | Basic Electrical and Electronics Lab | 0-0-3-1 | - |
| 1 | EE105 | Computer Programming | 2-0-2-3 | - |
| 2 | EE201 | Mathematics II | 3-1-0-4 | EE101 |
| 2 | EE202 | Electrical Circuits and Networks | 3-1-0-4 | EE102 |
| 2 | EE203 | Digital Logic Design | 3-1-0-4 | - |
| 2 | EE204 | Basic Electronics Lab | 0-0-3-1 | - |
| 2 | EE205 | Engineering Drawing and Graphics | 2-0-0-2 | - |
| 3 | EE301 | Electromagnetic Fields | 3-1-0-4 | EE201 |
| 3 | EE302 | Signals and Systems | 3-1-0-4 | EE201 |
| 3 | EE303 | Electronics Devices and Circuits | 3-1-0-4 | EE202 |
| 3 | EE304 | Control Systems | 3-1-0-4 | EE302 |
| 3 | EE305 | Microprocessor and Assembly Language Programming | 2-0-2-3 | EE203 |
| 4 | EE401 | Power Systems Analysis | 3-1-0-4 | EE302 |
| 4 | EE402 | Communication Systems | 3-1-0-4 | EE302 |
| 4 | EE403 | Electrical Machines | 3-1-0-4 | EE303 |
| 4 | EE404 | Digital Signal Processing | 3-1-0-4 | EE302 |
| 4 | EE405 | Embedded Systems Lab | 0-0-3-1 | EE305 |
| 5 | EE501 | Power Electronics | 3-1-0-4 | EE403 |
| 5 | EE502 | Industrial Automation | 3-1-0-4 | EE404 |
| 5 | EE503 | Renewable Energy Systems | 3-1-0-4 | EE401 |
| 5 | EE504 | Advanced Control Systems | 3-1-0-4 | EE304 |
| 5 | EE505 | Wireless Communication | 3-1-0-4 | EE402 |
| 6 | EE601 | Advanced Embedded Systems | 3-1-0-4 | EE505 |
| 6 | EE602 | VLSI Design | 3-1-0-4 | EE303 |
| 6 | EE603 | Artificial Intelligence in Engineering | 3-1-0-4 | EE502 |
| 6 | EE604 | Project Management and Entrepreneurship | 2-0-0-2 | - |
| 6 | EE605 | Capstone Project Lab | 0-0-3-1 | EE601 |
| 7 | EE701 | Research Methodology | 2-0-0-2 | - |
| 7 | EE702 | Advanced Signal Processing | 3-1-0-4 | EE404 |
| 7 | EE703 | Smart Grid Technologies | 3-1-0-4 | EE501 |
| 7 | EE704 | Network Security | 3-1-0-4 | EE505 |
| 7 | EE705 | Final Year Project | 0-0-6-3 | EE701 |
| 8 | EE801 | Special Topics in Electrical Engineering | 2-0-0-2 | - |
| 8 | EE802 | Industrial Training | 0-0-6-3 | - |
| 8 | EE803 | Internship | 0-0-12-6 | - |
| 8 | EE804 | Elective Courses | 3-1-0-4 | - |
| 8 | EE805 | Capstone Project Presentation | 0-0-3-1 | EE705 |
Detailed Description of Departmental Elective Courses
Advanced departmental electives form a crucial part of the curriculum, offering specialized knowledge in niche areas that are increasingly relevant in today's engineering landscape. These courses are designed to deepen understanding and foster innovation among students.
Power Electronics
This course explores the design and analysis of power electronic converters used in industrial applications, renewable energy systems, and electric vehicle charging infrastructure. Students learn about DC-DC converters, AC-DC rectifiers, inverters, and their control strategies. Practical sessions involve building prototypes and testing performance under various load conditions.
Industrial Automation
Focused on modern automation technologies used in manufacturing environments, this course covers programmable logic controllers (PLCs), sensor integration, motor drives, and human-machine interfaces (HMIs). Students gain hands-on experience through lab exercises and simulations involving real-world industrial processes.
Renewable Energy Systems
This course examines the principles and applications of solar, wind, hydroelectric, and geothermal energy systems. It includes topics such as photovoltaic cell characteristics, wind turbine design, grid integration challenges, and energy storage solutions. Case studies from successful projects worldwide are analyzed to understand best practices.
Advanced Control Systems
Building upon foundational control theory, this course delves into modern control techniques including state-space methods, optimal control, robust control, and adaptive control. Students implement these concepts using MATLAB/Simulink and simulate complex dynamic systems.
Wireless Communication
This course covers wireless communication protocols, modulation schemes, channel coding, and multiple access techniques used in modern mobile networks. Students explore the architecture of 4G LTE and 5G NR systems, analyze network performance metrics, and design simple communication links using simulation tools.
Advanced Embedded Systems
Designed for students interested in embedded software development, this course covers real-time operating systems (RTOS), microcontroller architectures, device drivers, and embedded C programming. Projects involve developing embedded applications for IoT devices and automotive systems.
VLSI Design
This advanced course introduces the fundamentals of very large-scale integration (VLSI) design using CAD tools such as Cadence and Synopsys. Topics include logic synthesis, layout design, timing analysis, and verification techniques. Students complete a full VLSI design project from specification to implementation.
Artificial Intelligence in Engineering
This interdisciplinary course combines machine learning algorithms with electrical engineering applications. Students learn about neural networks, deep learning architectures, computer vision, and natural language processing as applied to engineering problems. Projects include image recognition systems and predictive maintenance models.
Smart Grid Technologies
This course explores the evolution of power grids into smart grids, focusing on advanced metering infrastructure (AMI), demand response management, energy storage integration, and grid stability issues. Students engage in case studies of smart grid implementations in different countries and evaluate their effectiveness.
Network Security
Addressing cybersecurity concerns in communication networks, this course covers encryption techniques, authentication protocols, intrusion detection systems, and secure network design principles. Practical sessions involve setting up firewalls, conducting vulnerability assessments, and implementing secure communication channels.
Project-Based Learning Approach
The department places significant emphasis on project-based learning to ensure students develop practical skills alongside theoretical knowledge. This approach encourages innovation, teamwork, and critical thinking while reinforcing academic concepts through hands-on experience.
Mini-projects are conducted in the second and third years, lasting 3-4 months each. These projects involve working in teams of 3-5 students on specific engineering challenges related to current industry trends. Students must demonstrate understanding of problem-solving methods, design processes, and technical documentation.
The final-year thesis or capstone project is undertaken under the supervision of faculty mentors and often aligns with ongoing research initiatives or industry collaboration projects. Students select their topics based on personal interest, academic guidance, and available resources. The evaluation criteria include technical depth, innovation, presentation quality, peer review feedback, and project completion timeline.
Thesis and Capstone Project Guidelines
The final-year project is a capstone experience that integrates all the knowledge and skills acquired throughout the program. Students are expected to identify a relevant research problem, design an appropriate solution, implement it using available tools and resources, and document their findings in a comprehensive report.
Project selection involves consultation with faculty advisors who help students refine their ideas and ensure feasibility within the allocated time frame. The department provides access to specialized software, laboratory equipment, and technical support throughout the project lifecycle.
Mentorship and Supervision
Each student is assigned a faculty mentor during the project phase. Mentors provide guidance on research methodology, technical challenges, and academic writing standards. Regular meetings are scheduled to review progress, address concerns, and offer constructive feedback.
The department also hosts weekly project workshops where students present their work in progress, receive peer feedback, and engage in collaborative discussions. These sessions foster a supportive learning environment that encourages innovation and continuous improvement.