4 Facts About Mechatronics Engineering

Much is known about civil, mechanical, and electrical engineering but not in mechatronics engineering. In fact, this could be your first time to hear this term through this article. To shed light on this topic, below are four fast facts on mechatronics engineering.

History. For most people, mechatronics is not a daily word. Even in various fields of Sciences, mechatronics appear to be a novel discipline. The truth, however, is that the word ‘mechatronics’ first emerged during the 1980s when Japan started building their robots. Back then, mechatronics was devised to define the union of robotics and automation. This is because of the fact that Japanese engineers during that time felt that the great number of scientific areas available still fails to embody the concept of potential humanoid technology. At present, mechatronics engineering account for the 10% of engineering graduates in Australia and a lot of countries have also intended to produce more practitioners of this career.

Significance. Many critics believe that the traditional engineering disciplines have evolved far from from each other that they can no longer function in one room. This means that a company must employ a handful of engineers to address automated control and monitoring system. Fortunately, the emergence of diploma in mechatronic engineering has allowed the marriage of various engineering fields. For example, annual audit of a factory’s plant and manufacturing system has required the owner to install electronic and computer control systems to align with international standards. Sadly, in-house engineers don’t posses sufficient knowledge of computer working systems and software languages. In this event, a mechatronics engineer can lend a hand by developing real-time automatic systems which can check plant leakages and cracks and directly send evaluation report to the computer or hand-held devices of the plant manager. Through this, abrupt action can be done to improve plant functioning, thus, possible losses are minimized.

Areas of expertise. If most engineering fields appear to be encompassing, mechatronics engineering will make you think otherwise. This discipline can be applied to data networking, techniques in artificial engineering, avionics hardware and control systems, energy conversion of electromagnetic systems, power electronics, sensor development and installation, simulation of fabricated machine performance, signal processing, ‘smart’ technology development and improvement, thermo fluids and finally, robotics.

Accreditation. Despite the current applications of mechatronics engineering, only a few countries have recognized it as a formal branch of engineering. This is not because they doubt the integrity or the possibilities of this field but because they find it hard to establish the proper governing bodies that must facilitate the formulation of course modules and accreditation exams. At present, only Japan, Australia, France, the Netherlands and Germany have reported successfully creation and introduction of the mechatronics engineering in their educational systems. In the case of USA and Great Britain, professionals are still arguing on what specific party must preside over the execution and licensing procedures of mechatronics engineering.

The future is bright for mechatronics engineering. Students therefore must exploit this opportunity in order for them to be pioneers in their expertise. Moreover, the financial rewards that may come to these pioneers are likely to exceed current pay checks of other engineering practitioners.