Robotics Engineering  Responsibilities Growth and Future

One of the most important aspects of modern robotics is machine learning and artificial intelligence. Many functions are required to make a robot move about in an uncertain environment. It’s difficult enough to get the robot to recognize its own appendages. To deal with this, you’ll need a slew of libraries that can both describe and manage everything. 

Worldwide, 2.1 million industrial robots were in use in 2017, according to the International Association of Robotics (IFR). Many varieties of robotic systems exist, including articulating, collaborative and selective conformity robotic assembly robots as well as automated guided vehicles (AGV).

Advanced robotics are making an impact on manufacturing. Due to digitalization and the use of sophisticated computing technologies such as artificial intelligence (AI) to more aspects of product design, production, and supply chain, manufacturing processes are becoming increasingly complicated and extensive. 

You don’t want to build this system on your own, and it’s a lot more complicated than it appears at first. An apparently simple act, such as grasping an object, necessitates a whole library of code, and that’s after the robot has already discovered the thing via another set of sophisticated coding.

Understanding Artificial Intelligence and Its future

These humanoid robots are employed in fields like as caregiving and personal support, search and rescue, space exploration and research, entertainment and education, public relations and healthcare, and manufacturing, according to the American Society of Mechanical Engineers. As the number of use cases and apps grows, the Android market is expected to reach $13 billion by 2026.

Some human activities will be replaced by robots as their capabilities become more advanced, but not all. In unpredictable, human-dependent industries like construction and nursing, current robots technology can only automate 25% of jobs. Robots, on the other hand, rely on human programming and will continue to do so in the future.

According to the job description, this position has decent working conditions and job security, and requires at least 40 hours a week. Another aspect is the future of service robots for professional usage, according to the Robotic Industries Association

Robotics Engineering : Responsibilities Growth and Future

The typical starting salary for a robotics engineering employment is $30,000 per year. Robotics Engineer may earn upwards of $60,000 the longer they work and the more schooling they obtain. The location of the technician’s job has a significant impact on salary. With an annual salary of approximately $86,700, robotics technicians are really paid the most in Alaska. Robotics technicians may be eligible for perks including health insurance or 401k matching depending on the firm.

Robotics Engineering graduates may earn an average yearly income of $56,320, or $27 per hour, according to the most recent data on employment throughout the country. It is thus a Salary Above Average. When just starting out or depending on the state you live in, they may make as little as $41,600, or $20 per hour.

Robotics is a multidisciplinary area that combines a variety of engineering disciplines, including mechanical, electrical, computer, and systems engineering, to assist a wide range of industries. While the manufacturing business is essential, robots may be used in a variety of industries, including aerospace, transportation, automotive, medical, and everything in between.

How Robots are Built by Robotics Engineers

You should have a degree in an engineering subject to be considered for this position. You should be well-versed in flexible automation and computer systems, as well as cost and efficiency optimization.


  1. Investigate the parameters of a robotic application.

  2. Create robotic systems from beginning to end.

  3. Create and implement software to operate robots.

  4. Make prototypes and work on the required components (e.g. microprocessors)

  5. Create cost-effective and efficient manufacturing methods for the equipment.

  6. Carry out integration testing and quality control.

  7. Make use of machine learning methods

  8. Produce comprehensive documentation for robotic systems.

  9. Keep track of how robotic systems are being used and make improvements to their usefulness.

  10. Troubleshoot flaws in the robot’s design Stay up to date on robotics and related technical advances

Candidates can study for a certificate, a bachelor’s degree, or a master’s degree in this discipline. To become a Robotics Engineer, you must first complete a degree programme in this discipline. We’ve highlighted a few courses in this subject here:

Diploma Program (Four-Year Program):

Bachelor’s Degree Programs in Robotics (four years):

Robotics Engineering Bachelor of Technology (B.Tech)

Bachelor of Engineering (BE) in Robotics Master Courses (duration: two years):

Robotics Engineering Master of Technology (M.Tech)

Automation & Robotics Master of Technology (M.Tech)

Robotics Engineering Master of Engineering (ME)

M.Tech. in Remote Sensing & Wireless Sensor Networks

Specialized fields of Robotics engineering are given below:




Digital Electronics and Micro-Processors

Medical Robotics

Design and Control

Signal Processing

Robot Manipulators

Computer Integrated Manufacturing System

Robot Motion Planning

Computational Geometry

Computer Aided Manufacturing

Air Traffic Management System

Robotics Engineering : Responsibilities Growth and Future

To meet the obstacles of implementation, they must also guarantee that their organisation and system architecture are in place. Taking a wait-and-see attitude is no longer an option.

Robotics is one of the most promising future technologies. In industrial manufacturing, robots have become crucial. Robots are also becoming more common in private homes. Automation is becoming more popular across the world. Robotics in study and practice is the focus of our books and publications in this subject.