Platforms for industrial cyber-physical systems integration: contradicting requirements as drivers for innovation

Peter Palensky; Stefan Vielguth; Florian Nadler; Michael Heiss; Andreas Oertl; Monika Sturm

Platforms for industrial cyber-physical systems integration: contradicting requirements as drivers for innovation

Peter Palensky, Stefan Vielguth, Florian Nadler, Michael Heiss, Andreas Oertl, Monika Sturm

Digital Resilient Cities

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Publikation: Beitrag in Buch oder Tagungsband › Beitrag in Tagungsband ohne Präsentation

Abstract

A variety of businesses are experiencing a boost in innovation due to cyber-physical systems. Consumer electronics, the health sector, the energy sector, or the automotive industry are examples of domains where the design and operations of highly integrated embedded systems are closer to physical processes than ever. New methods for describing, verifying, designing, and operating such integrated and often autonomously acting systems are required [1]. However, the biggest challenge likely lies in between these domains: the integration of distributed, multi-domain cyberphysical systems [2]. The combination and integration of diverse CPSs lead to an entirely new magnitude of applications and design challenges regarding the resulting CPS. An autonomous, electric vehicle may serve as an illustrative example: In order to perform a smooth, safe, comfortable, and efficient shopping tour, various CPSs that were previously operated independently need to interoperate: · The steering and navigation controls, · The charging electronics, · Vehicle-to-infrastructure, vehicle-to-vehicle, and vehicle-to-pedestrian communications, · The charging station directory,

Originalsprache	Englisch
Titel	2015 Workshop on Modeling and Simulation of Cyber-Physical Energy Systems (MSCPES), CPS Week, IEEE, At Seattle
Seiten	9-16
Seitenumfang	8
Publikationsstatus	Veröffentlicht - 2015

Research Field

Ehemaliges Research Field - Energy

Schlagwörter

cyber-physical systems
IT platforms
software integration
distributed systems
complexity management

UN SDGs

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abstract = "A variety of businesses are experiencing a boost in innovation due to cyber-physical systems. Consumer electronics, the health sector, the energy sector, or the automotive industry are examples of domains where the design and operations of highly integrated embedded systems are closer to physical processes than ever. New methods for describing, verifying, designing, and operating such integrated and often autonomously acting systems are required [1]. However, the biggest challenge likely lies in between these domains: the integration of distributed, multi-domain cyberphysical systems [2]. The combination and integration of diverse CPSs lead to an entirely new magnitude of applications and design challenges regarding the resulting CPS. An autonomous, electric vehicle may serve as an illustrative example: In order to perform a smooth, safe, comfortable, and efficient shopping tour, various CPSs that were previously operated independently need to interoperate: · The steering and navigation controls, · The charging electronics, · Vehicle-to-infrastructure, vehicle-to-vehicle, and vehicle-to-pedestrian communications, · The charging station directory,",

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year = "2015",

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Platforms for industrial cyber-physical systems integration: contradicting requirements as drivers for innovation. / Palensky, Peter; Vielguth, Stefan; Nadler, Florian et al.
2015 Workshop on Modeling and Simulation of Cyber-Physical Energy Systems (MSCPES), CPS Week, IEEE, At Seattle. 2015. S. 9-16.

Publikation: Beitrag in Buch oder Tagungsband › Beitrag in Tagungsband ohne Präsentation

TY - CHAP

T1 - Platforms for industrial cyber-physical systems integration: contradicting requirements as drivers for innovation

AU - Palensky, Peter

AU - Vielguth, Stefan

AU - Nadler, Florian

AU - Heiss, Michael

AU - Oertl, Andreas

AU - Sturm, Monika

PY - 2015

Y1 - 2015

N2 - A variety of businesses are experiencing a boost in innovation due to cyber-physical systems. Consumer electronics, the health sector, the energy sector, or the automotive industry are examples of domains where the design and operations of highly integrated embedded systems are closer to physical processes than ever. New methods for describing, verifying, designing, and operating such integrated and often autonomously acting systems are required [1]. However, the biggest challenge likely lies in between these domains: the integration of distributed, multi-domain cyberphysical systems [2]. The combination and integration of diverse CPSs lead to an entirely new magnitude of applications and design challenges regarding the resulting CPS. An autonomous, electric vehicle may serve as an illustrative example: In order to perform a smooth, safe, comfortable, and efficient shopping tour, various CPSs that were previously operated independently need to interoperate: · The steering and navigation controls, · The charging electronics, · Vehicle-to-infrastructure, vehicle-to-vehicle, and vehicle-to-pedestrian communications, · The charging station directory,

AB - A variety of businesses are experiencing a boost in innovation due to cyber-physical systems. Consumer electronics, the health sector, the energy sector, or the automotive industry are examples of domains where the design and operations of highly integrated embedded systems are closer to physical processes than ever. New methods for describing, verifying, designing, and operating such integrated and often autonomously acting systems are required [1]. However, the biggest challenge likely lies in between these domains: the integration of distributed, multi-domain cyberphysical systems [2]. The combination and integration of diverse CPSs lead to an entirely new magnitude of applications and design challenges regarding the resulting CPS. An autonomous, electric vehicle may serve as an illustrative example: In order to perform a smooth, safe, comfortable, and efficient shopping tour, various CPSs that were previously operated independently need to interoperate: · The steering and navigation controls, · The charging electronics, · Vehicle-to-infrastructure, vehicle-to-vehicle, and vehicle-to-pedestrian communications, · The charging station directory,

KW - cyber-physical systems

KW - IT platforms

KW - software integration

KW - distributed systems

KW - complexity management

KW - cyber-physical systems

KW - IT platforms

KW - software integration

KW - distributed systems

KW - complexity management

M3 - Conference Proceedings without Presentation

SN - 978-1-4799-7357-6

SP - 9

EP - 16

BT - 2015 Workshop on Modeling and Simulation of Cyber-Physical Energy Systems (MSCPES), CPS Week, IEEE, At Seattle

ER -

Platforms for industrial cyber-physical systems integration: contradicting requirements as drivers for innovation

Abstract

Research Field

Schlagwörter

UN SDGs

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