Electrical and electronic engineering explained.

Electrical and electronic engineers are at the lead of modern science, developing the tools and applications that we use. From solar-powered networks to smartphones, they are innovating to satisfy the connectivity, infrastructure and energy needs of society. Electricity is an integral part of our everyday life, including transportation, medicine, quantum technology, computation, artificial intelligence, cryptography, communications, the list is infinite. And what sets physical and mechanical apart? Simply put, electrical engineers are concerned with power supply and flow; electronic engineers are making the electronic devices we use every day.

Electrical engineering is about harnessing electricity:

  • The production, storage and transmission of it
  • Big volume delivery and power management systems
  • Circuits in which electricity circulates from one level to another
  • High voltage systems and high currents

Electronic engineering is about electrical circuits and components:

  • Build, design, and evaluate them
  • Incorporate them into hardware and operating programs
  • Circuits the process, and has capabilities for decision making
  • Applications of low voltage and low current
  • Robotics, AI, computation, networking

Both disciplines are oriented for implementations in the real world. If you’re passionate about mathematics and science, enjoy technology and its future social gains, this is the course for you.



Those are only a handful of the global developments and crucial issues faced by electrical and computer engineers:-

  • Rapid technical progress, the information and consumer technology transition, and new media.
  • Urgent need for alternative and renewable energy and transport solutions.
  • Developing integrated networks, including the Smart Grid.
  • The Shift in Automated Transport.
  • Computing and engineering systems are interweaving into ‘Industry 4.0’.
  • Advances in the scientific, engineering, electronics, and artificial intelligence industries.

All of this means competition for electrical and computer engineering is high and increasing. They will be the focus of future creativity. Starting wages are both high and reasonable. Reports forecast outstanding prospects for potential jobs with increased workplace stability and a rise in migration possibilities and diversification. Demand is worldwide, so chances of working overseas during your studies are high.

What qualifications do you need?

Specifications differ between universities and colleges, but in mathematics, most would ask for an A level (or equivalent) to qualify for a degree in electronic engineering. Physics, Chemistry and Electronics are other vital areas to be studied. You can also be selected according to GCSE scores. Always Verify the admission requirements for the specific university/course you are interested in.

How will you be assessed?

Evaluations consist of assessments, coursework, laboratory results, interviews, and project papers. Different courses assign distinct weights to each field. Electrical and Electronic Engineering can be taught over a three to five year course period. In such cases, different weights will be given out to different years. For additional details, check your specific course.

What are the postgraduate opportunities?

Those include environmental management, renewable energy, artificial intelligence, biomedical engineering, electrical and instrumentation technologies, and advanced electrical power engineering.

Interested in pursuing higher education engineering? Check the course offerings at Auston, a leading private university, with outstanding part-time engineering degrees in Singapore. You can visit their website at https://www.auston.edu.sg/part-time-degrees-in-singapore/.