PROGRAM EDUCATIONAL OBJECTIVES (PEOs)

Graduates of B.Tech in Electrical & Electronics Engineering Programme shall be able to

1. Technical Proficiency: Graduates of the EEE program will demonstrate proficiency in fundamental principles, theories, and practices of electrical and electronics engineering, enabling them to analyse, design, and implement solutions for complex engineering problems.
2. Professional Development: Graduates will engage in continuous professional development, acquiring advanced technical knowledge, skills, and competencies to adapt to emerging technologies and industry trends in electrical and electronics engineering throughout their careers.
3. Leadership and Innovation: Graduates will demonstrate leadership, creativity, and innovation in addressing societal needs and industry challenges, contributing to advancements in technology, sustainable practices, and the development of new products and systems.
4. Ethical and Social Responsibility: Graduates will adhere to ethical principles, professional integrity, and social responsibility in their engineering practice, considering the impact of their work on public safety, environmental sustainability, and the well-being of society.
5. Global Perspective: Graduates will have a global perspective, understanding the cultural, economic, and environmental factors that influence electrical and electronics engineering solutions, and will collaborate effectively in diverse, multicultural teams to address global challenges and opportunities in the field.

Programme Outcome (PO’S)

Graduates of B.Tech in Electrical & Electronics Engineering Programme shall be able to

1. **Fundamental Knowledge**: Graduates will demonstrate a solid understanding of fundamental principles and advanced concepts in electrical and electronic engineering, including circuit theory, electromagnetics, power systems, control systems, and electronics.

2. **Problem Solving Skills**: Students will be able to apply engineering knowledge and analytical skills to identify, formulate, and solve complex problems in electrical and electronic systems, considering technical, economic, and societal constraints.

3. **Design and Analysis Proficiency**: Graduates will be proficient in designing electrical and electronic systems, components, and devices, applying engineering principles, standards, and software tools, and conducting analysis and simulation as necessary.

4. **Experimental Techniques**: Students will be competent in using experimental techniques to design, conduct, and analyze experiments relevant to electrical and electronic engineering, including laboratory experiments, measurements, and data analysis.

5. **Professional Ethics and Responsibility**: Graduates will recognize the ethical and professional responsibilities of electrical engineers, including considerations of public safety, health, and welfare, and demonstrate integrity, honesty, and accountability in their professional practice.

6. **Teamwork and Collaboration**: Students will be able to work effectively as part of multidisciplinary teams, demonstrating leadership, interpersonal skills, and the ability to contribute positively to team dynamics in electrical engineering projects.

7. **Communication Skills**: Graduates will possess effective communication skills, including the ability to communicate technical information clearly and concisely through written reports, oral presentations, and graphical representations, and to collaborate with diverse stakeholders.

8. **Project Management Skills**: Students will understand the principles of project management and be able to apply project management techniques to plan, organize, execute, and control electrical engineering projects, considering scope, schedule, budget, and quality constraints.

9. **Continuous Learning and Professional Development**: Graduates will recognize the importance of life-long learning and continuous professional development in the field of electrical engineering and engage in activities to enhance their knowledge, skills, and competencies throughout their careers.

10. **Electrical Safety and Regulatory Compliance**: Students will be familiar with relevant regulations, codes, and safety standards governing electrical engineering practices and be able to design and operate electrical systems in compliance with these standards.

11. **Environmental and Energy Considerations**: Graduates will understand the environmental and energy-related implications of electrical engineering projects and be able to incorporate sustainability principles into the design, operation, and management of electrical systems.

12. **Innovation and Entrepreneurship**: Students will develop innovative thinking and entrepreneurial skills, including the ability to identify opportunities, generate novel ideas, and translate them into practical solutions, products, or services in the field of electrical engineering.

PROGRAM SPECIFIC OUTCOMES (PSOs)

Graduates of B.Tech in Electrical & Electronics Engineering Programme shall be able to

1. Power System Optimization: PSO can be used to optimize various aspects of power systems, including economic dispatch, optimal power flow, and voltage regulation. In economic dispatch, PSO algorithms can efficiently allocate generation resources to minimize the overall cost of electricity production while satisfying demand and operational constraints. Similarly, PSO can optimize power flow within the network to minimize transmission losses and ensure reliable operation. Additionally, PSO can be applied to voltage control problems, adjusting reactive power resources to maintain voltage levels within acceptable limits across the system.
2. Signal Processing: PSO can be utilized for optimizing parameters in signal processing algorithms, such as filter design, spectral analysis, and pattern recognition. For example, in digital filter design, PSO can search for the coefficients that minimize distortion or noise while preserving signal characteristics. In spectral analysis, PSO can optimize parameters for signal decomposition techniques like wavelet transforms or Fourier analysis. Furthermore, PSO can aid in feature selection and parameter tuning for pattern recognition tasks, improving the accuracy and efficiency of classification algorithms.
3. Antenna Design: PSO can play a significant role in optimizing the design of antennas for various applications, including communication systems, radar systems, and wireless sensor networks. PSO algorithms can optimize antenna geometries, such as element positions, lengths, and orientations, to achieve desired radiation patterns, gain, and impedance matching characteristics. By exploring the design space efficiently, PSO can find optimal solutions for multi-objective antenna design problems, considering conflicting objectives such as directivity, bandwidth, and size constraints.