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For future manufacturing systems with a high variety in products and a dynamic production environment, concepts for adapting production are becoming more important. Errors in processes need to be detected quickly and a fast reaction is necessary to prevent failures. Minimizing production stops and swiftly getting back to production is one main goal. Manufacturing systems have to become more intelligent...
Manufacturing paradigms are currently shifting from mass production towards mass customization and personalized products. Customers demand individual, high quality products that are tailored to their needs at a low cost and reasonable delivery times. The shoe and fashion industry is one example. Currently, mass customizing textile products is possible but comes with long delivery times due to fragmented...
Adaptability and changeability are becoming the key features of future manufacturing. With adaptability comes a need to dynamically and frequently change factory topologies throughout the life-cycle of manufacturing systems. These changes are necessary to respond to changes in markets that result in new products, production volumes, and product variants. In addition to flexibly switching between different...
Future manufacturing systems are required to be adaptable and react quickly on changes in markets and demands. Additionally, they should be able to support individualized products that are tailored to customer needs. Flexibility can be increased through decoupling product descriptions from manufacturing systems. Production processes are no longer described based on available resources. Instead, a...
Future manufacturing systems have to be more adaptable to be able to compete in fast changing markets and address specific customer demands. To increase adaptability of production systems, the software and communication infrastructures have to be adaptable as well. Current communication paradigms tightly couple manufacturing systems to communication infrastructures. Changes in the manufacturing system...
Manufacturing enterprises can only stay profitable if they manage to flexibly respond to changes in markets by adapting their products, product variants, and product volumes. To support such variety in products, we suggest a capability-based approach for production planning and scheduling. Production plans and machines are described in terms of required capabilities and provided capabilities respectively...
Life cycles of many products are becoming shorter. In addition, the number of variants of one product is growing. As a fact, volume of one specific product that is being manufactured is decreasing. This leads to more frequent modifications of production lines. To cope with these changes, adaptable manufacturing systems are required. Current manufacturing systems can only be adapted to certain (predefined)...
We present a demo for a modular software framework named Chromosome, serving as a middleware and execution platform for model-based software design of safety-critical embedded systems. Specifically in this work, we enable temporal isolation within the middleware and use an inverted pendulum case study to demonstrate our framework on an FPGA platform.
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