The course deals with the study of strength of materials where the understanding of how bodies and materials respond to applied loads is the main emphasis. The course covers the fundamental concepts of stresses and strains experienced and/or developed by different materials in their loaded state and subjected to different conditions of constraint that includes axial stress, shearing stress, bearing stress, torsion, flexural stress, and stress-strain relationships
SDG 4: Quality Education - By strengthening foundational engineering knowledge and analytical skills, the course contributes to SDG 4. Through problem-solving and design-based learning, students develop critical thinking and technical competencies aligned with high-quality engineering education.
SGD 9: Industry, Innovation, and Infrastructure - By equipping students with the knowledge and skills to analyze and design structural members, the course contributes to SDG 9. The course supports the analysis and design of resilient infrastructure and innovative engineering solutions by providing methods/tools to predict material behavior and structural performance under load.
This course develops students’ foundational competence in electronic circuits through the systematic study of diodes, transistors, and integrated circuits used in modern electrical and electronics engineering applications. It emphasizes the analysis of circuits employing discrete components and extends to the practical understanding of commonly used integrated circuits. The course further introduces fundamental electronic circuit design concepts for basic applications such as filters, power supplies, and operational amplifier signal processing, with attention to sustainable and responsible engineering practices.
Aligned with the Sustainable Development Goals (SDGs), this course supports:
- SDG7: (Affordable and Clean Energy) The course develops students’ ability to analyze and design efficient electronic circuits such as power supplies and regulators, which are fundamental components of energy conversion and management systems. Through the study of semiconductor devices and power electronics principles, students gain technical competence in creating circuits that contribute to energy efficiency and sustainable power usage.
- SDG9: (Industry, Innovation & Infrastructure) By introducing integrated circuits, transistor amplifiers, and operational amplifier applications, the course strengthens students’ engineering foundation in electronics system design. These competencies directly support technological innovation and the development of modern industrial and communication infrastructures.
This course develops students’ foundational competence in electronic circuits through the systematic study of diodes, transistors, and integrated circuits used in modern electrical and electronics engineering applications. It emphasizes the analysis of circuits employing discrete components and extends to the practical understanding of commonly used integrated circuits. The course further introduces fundamental electronic circuit design concepts for basic applications such as filters, power supplies, and operational amplifier signal processing, with attention to sustainable and responsible engineering practices
Aligned with the Sustainable Development Goals (SDGs), this course supports
- SDG7: (Affordable and Clean Energy) The course develops students’ ability to analyze and design efficient electronic circuits such as power supplies and regulators, which are fundamental components of energy conversion and management systems. Through the study of semiconductor devices and power electronics principles, students gain technical competence in creating circuits that contribute to energy efficiency and sustainable power usage.
- SDG9: (Industry, Innovation & Infrastructure) By introducing integrated circuits, transistor amplifiers, and operational amplifier applications, the course strengthens students’ engineering foundation in electronics system design. These competencies directly support technological innovation and the development of modern industrial and communication infrastructures.
The course deals with the study of electric and magnetic fields; resistive, dielectric and magnetic materials, coupled circuits, magnetic circuits and fields, and time-varying electromagnetic fields. It involves a review of vector analysis and types of coordinate system (Cartesian, cylindrical and spherical coordinate systems). Topics covered are dot and cross products of vector, Coulomb’s law and electric field intensity of different charge configuration (volume, point, line sheet charge), electric flux density, Gauss’s Law, divergence, Maxwell’s equations and energy and potential.