PROGRAM EDUCATIONAL OBJECTIVES (PEOs)

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

1. Technical Competence: Graduates of the ECE program will possess a strong foundation in electrical and computer engineering principles, including analog and digital circuits, signal processing, communications, and computer systems, enabling them to analyse, design, and implement complex electronic systems and technologies.
2. Professional Development: Graduates will engage in continuous learning and professional development, acquiring advanced technical knowledge, practical skills, and interdisciplinary competencies to adapt to emerging technologies and industry trends in electrical and computer engineering throughout their careers.
3. Innovation and Entrepreneurship: Graduates will demonstrate creativity, critical thinking, and problem-solving skills, leveraging their technical expertise to develop innovative solutions, products, and technologies that address societal needs, drive economic growth, and contribute to technological advancements.
4. Ethics and Societal Impact: Graduates will exhibit ethical awareness, social responsibility, and environmental stewardship in their engineering practice, considering the ethical, economic, and societal implications of their work and striving to promote sustainability, safety, and equity in engineering solutions.
5. Effective Communication and Leadership: Graduates will possess strong communication, teamwork, and leadership skills, enabling them to effectively collaborate with diverse stakeholders, communicate technical concepts to non-technical audiences, and lead multidisciplinary teams in the design, implementation, and management of engineering projects.

PROGRAMME OUTCOME (PO’S)

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

1. **Foundational Knowledge**: Graduates will demonstrate a comprehensive understanding of fundamental principles and advanced concepts in electrical engineering, electronics, and computer engineering.

2. **Circuit Analysis and Design Skills**: Students will be proficient in analyzing, designing, and optimizing electrical circuits and systems, including analog and digital circuits, using both theoretical analysis and simulation tools.

3. **Electromagnetic Field Theory and Applications**: Graduates will understand the principles of electromagnetic field theory and their applications in various engineering domains, including transmission lines, antennas, and electromagnetic compatibility.

4. **Signal Processing Techniques**: Students will be able to apply signal processing techniques to analyze, manipulate, and interpret signals in both time and frequency domains, with applications in communication, control, and multimedia systems.

5. **Electronic Devices and Systems Design**: Graduates will have knowledge of electronic devices, such as transistors and integrated circuits, and be able to design and implement electronic systems for applications ranging from consumer electronics to industrial automation.

6. **Digital System Design and Embedded Systems**: Students will demonstrate proficiency in designing digital systems and embedded systems, including microcontrollers, FPGAs, and DSP processors, with applications in robotics, IoT, and real-time control.

7. **Communication Systems and Networking**: Graduates will understand the principles of communication systems, including modulation techniques, digital communication protocols, and wireless networking, and be able to design and analyze communication systems for various applications.

8. **Computer Architecture and Systems**: Students will be familiar with computer architecture principles, including processor design, memory systems, and input/output interfaces, and be able to design and optimize computer systems for performance, power efficiency, and reliability.

9. **Control Systems Analysis and Design**: Graduates will understand the principles of feedback control systems and be able to analyze, model, and design control systems for applications in robotics, automation, and mechatronics.

10. **Power Systems and Renewable Energy**: Students will comprehend the principles of power systems, including generation, transmission, and distribution, as well as renewable energy technologies, and be able to design and analyze sustainable energy systems.

11. **Software Engineering and Programming Skills**: Graduates will possess strong software engineering and programming skills, including proficiency in programming languages such as C/C++, Python, and MATLAB, and experience with software development tools and methodologies.

12. **Professionalism and Ethics**: Students will recognize the ethical and professional responsibilities of engineers, including issues related to safety, sustainability, and societal impact, and demonstrate integrity, accountability, and professionalism in their engineering practice.

PROGRAM SPECIFIC OUTCOMES (PSOs)

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

1. Wireless Network Optimization: PSO can be applied to optimize various parameters in wireless communication networks, such as resource allocation, power control, and routing. In wireless sensor networks (WSNs), PSO algorithms can optimize sensor placement, transmission power levels, and routing paths to minimize energy consumption, maximize network coverage, and ensure reliable communication. PSO-based optimization techniques enable engineers to design efficient and robust wireless networks for applications such as environmental monitoring, surveillance, and smart cities.
2. Antenna Array Design: PSO can be used to optimize the design and configuration of antenna arrays for communication systems, radar systems, and satellite communication. Antenna arrays consist of multiple antenna elements arranged in a specific pattern to achieve desired radiation characteristics such as beamforming, directionality, and polarization. PSO algorithms can optimize the positions, phases, and amplitudes of array elements to maximize antenna performance metrics such as gain, directivity, and sidelobe suppression. PSO-based optimization techniques enable engineers to design antenna arrays with enhanced performance and flexibility for diverse communication applications.
3. Digital Signal Processing (DSP): PSO can play a significant role in optimizing parameters and configurations in digital signal processing algorithms used in communication systems. For example, in adaptive filtering applications, PSO can optimize filter coefficients to achieve desired signal processing objectives such as noise reduction, interference cancellation, and channel equalization. PSO can also be applied to optimize parameters in modulation and coding schemes to improve spectral efficiency and error performance in communication systems. By employing PSO-based optimization techniques, engineers can enhance the efficiency, reliability, and performance of digital signal processing algorithms in communication applications.