• Engineering Course


  • 2 Colleges

Electronics and Biomedical Engineering is a branch of engineering that explores engineering knowledge in biology and medicine.


Electronics and Biomedical Engineering is a branch of engineering that explores engineering knowledge in biology and medicine. Biomedical Electronics, in which electronic concepts are used in the construction of medical instrumentation, is one of the most relevant fields of this engineering field. Students will learn about fundamental components of electronic engineering such as digital systems, solid-state devices, and computer engineering while also studying biological sciences. Cell biology, the body's critical systems, and neuroscience are all covered in the life sciences modules. The two subjects are brought together through specialist biomedical electronic engineering curricula. This course will teach students how to design, manufacture, and test new health and wellness gadgets and systems. Wearable monitors and clever medical diagnostic instruments are examples of this. Biomedical engineering has been classified as one of the country's speciality engineering fields, focusing on studying engineering concepts. These concepts are then integrated with medical science principles to streamline the country's healthcare services. Healthcare spending is predicted to rise as a result of increasing knowledge and population expansion. Furthermore, as individuals become more aware of medical breakthroughs, the number of people seeking biomedical remedies for their health problems has increased. Biomedical engineers' employment will eventually rise as a result of this.


Students can combine electrical engineering training with biomedical studies as part of the electronics AND Biomedical engineering course. It is providing them with the ability to design sensors, apps, and digital systems. Students will study compulsory modules in mathematics, physics, electronics, and programming. They'll also learn about digital strategies and electrical materials and fields in both theory and experience. They will also have the opportunity to expand their expertise in crucial areas of the biological sciences. Examining the many types of macromolecules contained in cells is part of this. They'll also look into biomedical electronics systems. They will broaden and deepen my knowledge of biological and electronic engineering. Signal processing, computer engineering, and electronic system controls for biological applications are among the topics covered. They'll also be able to select from various electronics, computer science, and mathematics modules. Machine learning and robotics systems are among the alternatives, as are computational biology and operational research. They can also study a foreign language, take modules from other fields like biology, or choose from various new interdisciplinary programs.


Candidates interested in pursuing a career in electronics or biomedical engineering can enrol in four-year BTech programs or five-year integrated BTech-Mtech programs at the undergraduate level. Candidates can follow a two-year MTech program in Biomedical Engineering after graduation. There are also specific well-known engineering entrance tests that students can take to get admission to the most prominent colleges. The rapid growth of technology in electronics and biomedical engineering will continue to alter the employment profile of these professionals. It will also continue to develop new areas of work. As a result, there is a need to translate the growing range of activities available to electronics and biomedical engineers into excellent career opportunities. Biomedical engineers, instrument engineers, installation engineers, researchers, and maintenance engineers are typical job profiles.