Robotics

Robotics Hardware Engineers design and develop the physical components that make robots work, translating requirements into hardware that performs reliably under real-world conditions. Testing and evaluation are central to this, putting hardware through its paces to understand how it actually performs before it's deployed. Reliability is a constant focus, since hardware that fails in the field can be far more costly to fix than hardware that's built right the first time. Throughout, they look for opportunities for innovation, developing new and forward-thinking robotic hardware solutions. Day to day, this means designing and developing robotic hardware, conducting hardware tests and evaluating performance, increasing the reliability and durability of hardware, and developing new robotic hardware solutions.

Robotics Systems Engineers bring together the different pieces of a robotic system, integrating hardware, software, and other components into something that works as a coherent whole. Performance monitoring is an ongoing responsibility, keeping an eye on how systems are running and optimising them as needed. Reliability matters a great deal here too, enhancing the continuity of robotic systems so they keep working when it counts. Throughout, they take on problem solving, identifying and resolving complex system issues that span multiple components. In practice, this means integrating robotic systems, monitoring and optimising system performance, enhancing the reliability and continuity of robotic systems, and identifying and solving complex system issues.

Robotics Research Engineers push the boundaries of what robotic technology can do, developing new technologies and solutions that go beyond incremental improvements. Research is at the heart of the role, investigating and applying new developments from across the robotics field to the work at hand. Performance improvement is a practical outcome of this research, enhancing how robotic systems perform based on what's been learned. Throughout, they contribute to the wider field through publications and patents, sharing findings and protecting new innovations. Day to day, this means developing new robotic technologies and solutions, investigating and applying new developments in robotics, enhancing the performance of robotic systems, and publishing research findings and obtaining patents.

Robotics Technicians handle the hands-on work of installing and maintaining robotic systems, making sure they're set up correctly and continue running smoothly over time. Fault detection is a key skill, identifying and resolving technical issues before they cause downtime. Operational efficiency is a constant focus, looking for ways to increase how efficiently robotic systems run day to day. Throughout, they provide training and support to teams, helping others work effectively with robotic systems. In practice, this means installing and maintaining robotic systems, identifying and resolving technical issues, increasing the operational efficiency of robotic systems, and providing technical training and support to teams.

Robotics Control Engineers design and implement the control systems that determine how robots move and respond, translating intended behaviours into precise, reliable control logic. Performance monitoring is ongoing, keeping track of how control systems perform and optimising them as conditions change. Reliability is a major focus, since control systems that fail can affect the safety and effectiveness of an entire robotic system. Throughout, they look for opportunities for innovation, developing new control algorithms and solutions. Day to day, this means designing and implementing robotic control systems, monitoring and optimising control system performance, increasing the reliability of control systems, and developing new control algorithms and solutions.

Robotics Automation Engineers develop automation systems that take robotic capabilities and apply them to streamline real-world processes, turning manual workflows into automated ones. Process improvement is a core part of this, analysing existing processes and figuring out how automation can make them better. Efficiency improvement is the natural outcome, increasing throughput and reducing waste through well-designed automation systems. Throughout, they look for opportunities for innovation, developing new automation technologies and solutions. In practice, this means developing robotic automation systems, analysing and improving automation processes, increasing efficiency through automation systems, and developing new automation technologies and solutions.