At the heart of modern life are electrical power and systems – and so are electrical and electronics engineers. To mention only a few examples, pioneers in these fields influenced the 21st century with inventions such as universal electric power systems, TV, the radio, and medical imaging. Among the most popular electronics and electrical engineers you may have heard of are Nikola Tesla (the founder of industrial electricity and electromagnetism), Thomas Edison (the light bulb maker and the record player inventor), Jack Kilby (the pocket calculator inventor and the integrated circuit), Marcian Hoff (the microprocessor inventor) and Martin Cooper (the handheld calculator inventor) Degrees in electrical engineering will provide students with knowledge of how the industry works and will also provide them with the technical expertise and practical experience required to design, test and develop electrical and electronic systems.
The distinction between electrical engineering and electronics engineering is often unclear. It is usually accurate to say that electrical engineers are primarily concerned with large-scale electrical power generation and distribution, while electronics engineers work on far smaller electronic circuits. You will be expected to gain professional knowledge of the courses used in computers and other modern technologies with a degree in electronics engineering. For this reason, electronics engineering is also taught alongside computer engineering. Even electrical or computer engineering degrees may intersect with mechanical and .
If you’re interested in how electrical systems operate, are inquisitive, and have a keen interest in maths and science. You already have some necessary engineering skills and may have an electrical or computer engineering degree. Even though technical knowledge is essential, electrical engineers are often involved within teams in designing and developing a range of devices. The bachelor’s level, a degree in electrical engineering, would offer students a background in electronic and electrical engineering’s underlying principles before enabling them to specialize in a field of interest later. Students may also be active in working in groups on projects.
As with most engineering topics, it’s best to believe you’ll be dedicated to your course each working week. Although you would almost definitely not be sitting eight hours a day in classes, your study schedule will be full. It will include several learning approaches, including laboratory work, tutorials, lectures, teamwork, group work, and individual research. You will also be expected to develop your knowledge outside of scheduled talks by navigating your course’s reading list. You may also be set engineering problems to solve, as
well as challenges to the coursework and hand-in laboratory reports.
Many hands-on sessions can also include manually dismantling electronic devices and reassembling them to see how they function. This helps students learn how to build and apply their engineering skills rather than just memorizing them from textbooks. If you’re interested in getting an engineering degree, visit .