Scientific Automation

Scientific Automation is the integration of automation software with findings from engineering science which go beyond the limits of conventional control. The basis for this is the continually increasing performance of PCs. The power of the PC Control philosophy offers sufficient capacity to integrate numerous advanced functions beyond standard control. Scientific Automation complements the conventional areas of control technology such as PLC, Motion Control and control technology, for instance, with precise and fast measurement technology and the associated engineering algorithms. The Beckhoff PC-based control technology provides the necessary basic foundation with powerful CPUs, fast I/O, the fast EtherCAT bus system and TwinCAT software.

Measurement technology, Condition Monitoring and Robotics become an integral part of PC-based control

The concept of Scientific Automation serves as the prerequisite to enable functions such as Condition Monitoring or robotics for a wide range of PLC programmers in a familiar format. The aim is to integrate the functions from the traditional “black box” into a standard PC-based software environment. This results in seamless integration into the overall control system and being able to dispense with additional robot CPUs. The PC-based controller from Beckhoff unites PLC, Motion Control and robotics all on one hardware and software platform. Further functionalities will follow, e.g. the integration of vision systems. Scientific Automation from Beckhoff is available in products in real terms and offers enough further potential for future developments and visions.

Scientific Automation offers enough further potential for future developments

Since machine concepts will undoubtedly change in coming years, Scientific Automation is reaching out even further to the future. Developing trends are moving towards increasingly complex PLC programs and ever shorter cycle times. The number of axes to be controlled synchronously will increase further, and the type of coupling between the axes will become more complex. Moreover, the number of electronic cam plates and electronic gearboxes will increase. In the future, many axes will be operated based on interpolation. However, in a few years` time, an advanced CPU will easily be able to cope with this. Integrated vision and robotics systems are implemented in software. With sufficient CPU power, advanced and familiar control algorithms – such as neural networks – may become suitable for industrial applications. However, more complex machines require more diagnostics and maintenance. More advanced systems with sophisticated diagnostics will make life easier for the end user. New input and output options such as voice input will simplify machine operation.
Another developing area is artificial intelligence. Until now, no intelligence to equal human intelligence has been replicated. It might certainly be possible to come closer to achieving this dream in the future with several cores and extreme computing power. In future computer generations, gestures, voice and image recognition procedures will be able to access terabytes of local data and at least provide support as highly sophisticated systems. In industry, this can be used for improving process operation, more human interaction, faster troubleshooting and ensuring product quality. Each system component or machine module could be allocated to a core, so that parallel processing with high clock frequencies might become possible.