Accelerating the
Industrial Internet of Things
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3 case studies
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Siemens Wind Power
Siemens Wind Power
Siemens Wind Power
RTI
Wind provides clean, renewable energy. The core concept is simple: wind turbines spin blades to generate power. However, today's systems are anything but simple. Modern wind turbines have blades that sweep a 120 meter circle, cost more than 1 million dollars and generate multiple megawatts of power. Each turbine may include up to 1,000 sensors and actuators – integrating strain gages, bearing monitors and power conditioning technology. The turbine can control blade speed and power generation by altering the blade pitch and power extraction. Controlling the turbine is a sophisticated job requiring many cooperating processors closing high-speed loops and implementing intelligent monitoring and optimization algorithms. But the real challenge is integrating these turbines so that they work together. A wind farm may include hundreds of turbines. They are often installed in difficult-to-access locations at sea. The farm must implement a fundamentally and truly distributed control system. Like all power systems, the goal of the farm is to match generation to load. A farm with hundreds of turbines must optimize that load by balancing the loading and generation across a wide geography. Wind, of course, is dynamic. Almost every picture of a wind farm shows a calm sea and a setting sun. But things get challenging when a storm goes through the wind farm. In a storm, the control system must decide how to take energy out of gusts to generate constant power. It must intelligently balance load across many turbines. And a critical consideration is the loading and potential damage to a half-billion-dollar installed asset. This is no environment for a slow or undependable control system. Reliability and performance are crucial.


Industries: Energy
Functions: Maintenance
Capabilities: Asset Tracking & MonitoringData Acquisition & ManagementRemote Access & Control
Hardware:
Software:
Services:
Distributed Systems for Medical Ultrasound
Distributed Systems for Medical Ultrasound
Distributed Systems for Medical Ultrasound
RTI
As a large distributed system scales, the ability to simultaneously maintain or enhance performance and reliability creates its own set of unique challenges. How do you address the distributed future, ensure you learn from your past experiences and build on the investments customers have already made? The challenges are real, and in the process of overcoming them BK Medical is building healthcare systems that are more cost effective, and provide greater integration into the patient care systems to facilitate improved decision making for doctors.


Industries: Equipment & Machinery
Functions: Maintenance
Capabilities: Data Acquisition & ManagementData Visualization
Hardware:
Unmanned Aircraft Systems (UAS) Ground Control Station (GCS)
Unmanned Aircraft Systems (UAS) Ground Control Station (GCS)
Unmanned Aircraft Systems (UAS) Ground Control Station (GCS)
RTI
General Atomics had to meet strict requirements for data bandwidth and availability. They could have designed and implemented a custom solution for data integration on their own, but that would have significantly delayed the project. Plus the lifecycle cost of developing and maintaining a custom software solution for a specific project can be enormous.


Industries: Transportation
Functions: Maintenance
Capabilities: Asset Tracking & MonitoringData Acquisition & ManagementRemote Access & Control
Software:
Services: