The Bachelor of Science in Electrical Engineering (Honours) equiped me with the knowledge, skills, and abilities needed to excel in the design, planning, and operation of electric power systems, devices, and related industries. Course Duties Mastering Theoretical Foundations: Gaining a deep understanding of electrical engineering principles, such as circuit theory, electromagnetism, and power systems, to solve real-world problems. Practical Application: Developing hands-on skills through laboratory work, projects, and simulations to design, test, and implement electrical systems and components. Problem-Solving: Applying mathematical and scientific concepts to analyze and address challenges in power generation, transmission, distribution, and control systems. Professional Competence: Preparing to work competently in industries by designing and managing electrical energy systems, ensuring safety, efficiency, and sustainability. Research and Innovation: Engaging in projects that encourage innovation, such as improving energy systems or developing new technologies, often culminating in a final-year capstone project. Ethical and Sustainable Practice: Learning to consider environmental and societal impacts in engineering solutions, aligning with modern demands for sustainable energy practices. Major Subjects Foundational Subjects (First Year Completed and Pre-Engineering) Mathematics: Calculus, linear algebra, and differential equations to build analytical skills (Engineering Mathematics I and II). Physics: Mechanics, electricity, and magnetism to establish a scientific base (Physics I and II ). Chemistry: Basic chemical principles relevant to materials and energy systems (Chemistry I and II). Introduction to Engineering: Overview of engineering principles, design processes, and professional practice. Core Electrical Engineering Subjects (Second and Third Year Completeds) Electric Circuits: Analysis and design of electrical circuits, including DC and AC systems. Electronics: Fundamentals of electronic devices and circuits, such as diodes, transistors, and amplifiers. Electromagnetics: Study of electromagnetic fields and waves, critical for power and communication systems. Power Systems: Principles of power generation, transmission, and distribution. Control Systems: Techniques for designing and analyzing systems to regulate electrical processes. Electrical Machines: Study of motors, generators, and transformers, focusing on energy conversion. Advanced and Specialized Subjects (Third and Fourth Year Completeds) Power Electronics: Design and application of electronic circuits for power conversion and control. Renewable Energy Systems: Technologies like solar and wind power, reflecting modern energy trends. Digital Systems: Basics of digital electronics and microprocessors for control and automation. Signals and Systems: Analysis of signals for communication and control applications. Engineering Design and Project Management: Practical application of skills in designing systems and managing projects.