Course Structure Overview
The electrical engineering program at Institute of Engineering Jiwaji University Gwalior is structured over eight semesters, with a balanced mix of core subjects, departmental electives, science electives, and laboratory components. Each semester includes foundational courses followed by increasingly specialized topics that build upon previous knowledge.
| Semester | Course Code | Course Title | Credit Structure (L-T-P-C) | Pre-requisites |
|---|---|---|---|---|
| 1 | ENG101 | Engineering Mathematics I | 3-1-0-4 | - |
| 1 | ENG102 | Engineering Physics | 3-1-0-4 | - |
| 1 | ENG103 | Basic Electrical Engineering | 3-1-0-4 | - |
| 1 | ENG104 | Engineering Graphics | 2-0-0-2 | - |
| 1 | ENG105 | Computer Programming | 3-1-0-4 | - |
| 1 | ENG106 | English for Engineers | 2-0-0-2 | - |
| 1 | LAB101 | Basic Electrical Lab | 0-0-3-1 | - |
| 1 | LAB102 | Programming Lab | 0-0-3-1 | - |
| 2 | ENG201 | Engineering Mathematics II | 3-1-0-4 | ENG101 |
| 2 | ENG202 | Electronic Devices & Circuits | 3-1-0-4 | ENG102 |
| 2 | ENG203 | Signals & Systems | 3-1-0-4 | ENG101 |
| 2 | ENG204 | Electromagnetic Fields | 3-1-0-4 | ENG102 |
| 2 | ENG205 | Digital Logic Design | 3-1-0-4 | - |
| 2 | LAB201 | Electronic Circuits Lab | 0-0-3-1 | - |
| 2 | LAB202 | Digital Logic Design Lab | 0-0-3-1 | - |
| 3 | ENG301 | Control Systems | 3-1-0-4 | ENG203 |
| 3 | ENG302 | Power Electronics | 3-1-0-4 | ENG202 |
| 3 | ENG303 | Communication Systems | 3-1-0-4 | ENG203 |
| 3 | ENG304 | Microprocessor & Microcontroller | 3-1-0-4 | ENG205 |
| 3 | ENG305 | Electrical Machines | 3-1-0-4 | ENG202 |
| 3 | LAB301 | Control Systems Lab | 0-0-3-1 | - |
| 3 | LAB302 | Power Electronics Lab | 0-0-3-1 | - |
| 4 | ENG401 | Power System Analysis | 3-1-0-4 | ENG305 |
| 4 | ENG402 | Renewable Energy Systems | 3-1-0-4 | ENG301 |
| 4 | ENG403 | Embedded Systems | 3-1-0-4 | ENG304 |
| 4 | ENG404 | Advanced Signal Processing | 3-1-0-4 | ENG203 |
| 4 | ENG405 | Industrial Automation | 3-1-0-4 | ENG301 |
| 4 | LAB401 | Power Systems Lab | 0-0-3-1 | - |
| 4 | LAB402 | Embedded Systems Lab | 0-0-3-1 | - |
| 5 | ENG501 | Smart Grid Technologies | 3-1-0-4 | ENG401 |
| 5 | ENG502 | Artificial Intelligence in Electrical Engineering | 3-1-0-4 | ENG404 |
| 5 | ENG503 | Advanced Control Systems | 3-1-0-4 | ENG301 |
| 5 | ENG504 | Electromagnetic Compatibility | 3-1-0-4 | ENG204 |
| 5 | ENG505 | Energy Storage Systems | 3-1-0-4 | ENG402 |
| 6 | ENG601 | Advanced Power Electronics | 3-1-0-4 | ENG302 |
| 6 | ENG602 | Robotics & Automation | 3-1-0-4 | ENG503 |
| 6 | ENG603 | Power System Protection | 3-1-0-4 | ENG401 |
| 6 | ENG604 | IoT and Wireless Communications | 3-1-0-4 | ENG303 |
| 7 | ENG701 | Research Methodology | 2-0-0-2 | - |
| 7 | ENG702 | Capstone Project I | 3-0-0-3 | - |
| 8 | ENG801 | Capstone Project II | 6-0-0-6 | ENG702 |
Advanced Departmental Electives
Departmental electives are offered to help students specialize in areas of interest and gain deeper knowledge in specific domains:
- Smart Grid Technologies: This course explores the integration of renewable energy sources, advanced metering infrastructure, and demand response management systems. Students learn about grid stability analysis, voltage regulation strategies, and the role of smart inverters in distributed generation.
- Artificial Intelligence in Electrical Engineering: Designed to bridge AI and electrical engineering, this course covers machine learning algorithms applied to power systems, neural networks for signal processing, and deep learning techniques for fault detection and classification in industrial settings.
- Advanced Power Electronics: Covers advanced topics such as resonant converters, multi-level inverters, and wide bandgap semiconductor devices. Students gain expertise in designing efficient power conversion systems for electric vehicles, renewable energy applications, and high-power electronics.
- Robotics & Automation: Focuses on robot kinematics, dynamics, sensor integration, control algorithms, and industrial automation technologies. The course includes hands-on projects involving mobile robots, robotic arms, and automated manufacturing processes.
- Power System Protection: Introduces protective relaying systems, fault analysis methods, and protection coordination strategies in electrical power systems. Students learn to design and implement protection schemes for transformers, transmission lines, and distribution networks.
- IoT and Wireless Communications: Explores wireless sensor networks, IoT protocols, data transmission techniques, and embedded communication systems. Students build prototype networks using LoRaWAN, Zigbee, and WiFi technologies for smart city applications.
- Energy Storage Systems: Covers battery technologies, supercapacitors, fuel cells, and hybrid energy storage solutions. The course addresses system design, performance optimization, and integration challenges in renewable energy systems.
- Electromagnetic Compatibility: Addresses electromagnetic interference issues, shielding techniques, EMI testing procedures, and compliance standards for electronic devices. Students learn to analyze and mitigate EMI problems in various applications including automotive, aerospace, and consumer electronics.
- Advanced Control Systems: Builds upon control theory concepts by introducing advanced topics such as state-space representation, robust control, optimal control, and adaptive control systems. Applications include aerospace, robotics, and process control industries.
- Renewable Energy Integration: Focuses on integrating renewable energy sources into existing power grids, addressing intermittency issues, and optimizing energy management strategies. Students engage in case studies involving solar, wind, and hydroelectric systems.
Project-Based Learning Philosophy
The department emphasizes project-based learning as a core component of the curriculum. From the second year onward, students are encouraged to engage in both mini-projects and capstone projects that simulate real-world engineering challenges.
Mini-projects are conducted during the third and fourth semesters. These projects typically involve small teams of 3-5 students working on a specific problem under faculty supervision. The evaluation criteria include design documentation, implementation progress, presentation quality, and peer feedback.
The final-year thesis/capstone project is a significant undertaking that spans the entire eighth semester. Students select their projects in consultation with faculty mentors based on current industry trends or research interests. Projects are often inspired by real-world challenges posed by industry partners or national initiatives such as Smart Cities Mission, National Energy Policy, or Digital India.
The department provides dedicated project spaces equipped with prototyping tools, software licenses, and access to industry-standard equipment. Faculty mentors guide students through the entire process—from concept formulation to final implementation—ensuring that projects meet academic rigor while maintaining relevance to industry needs.