Extension of reconfigurability provisions in IEC 61499

Yan, Jeffrey; Vyatkin, Valeriy

doi:10.1109/etfa.2013.6648026

Cited by 15 publications

(5 citation statements)

References 10 publications

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“…Future works will include introducing built-in security features and support for hard real-time behaviours within the framework. We also plan to investigate the performance of the framework compared to other approaches, and how to map (translate) a standard IEC 61499 framework which has reconfiguration provisions such as those in [13] and enhanced with features proposed in this paper on SOSJ framework.…”

Section: Discussionmentioning

confidence: 99%

“…Similarly, SOA approaches like the DPWS [10] and OPC-UA [11] are not based on formal semantics and MoC, despite the increasing popularity of SOA paradigm in the industrial manufacturing context. There are also efforts in providing reconfiguration by utilizing the aforementioned software technologies within the IEC 61131 [12] and the IEC 61499 [13] [14], however only limited/partial reconfiguration is supported. On the other hand, a recent attempt to use a programming language with formal semantics and Globally Asynchronous Locally Synchronous (GALS) MoC, SystemJ [15], demonstrates the ability to easily specify correct-by-construction software behaviours for execution on distributed platforms.…”

Section: Introductionmentioning

confidence: 99%

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Dynamic Reconfiguration and Adaptation of Manufacturing Systems Using SOSJ Framework

Atmojo

Salčić

Wang

2018

IEEE Trans. Ind. Inf.

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One of the key challenges in modern manufacturing systems is how to dynamically reconfigure software behaviours that govern machines to reflect changes in physical manufacturing process without completely resetting the entire manufacturing operation. The existing software solutions used to describe software behaviours in manufacturing systems are typically not based on formal semantics and model of computation and have limited capabilities in handling dynamic adaptation/reconfiguration. This paper presents the Service Oriented SystemJ (SOSJ) framework that supports a new programming paradigm for designing dynamic distributed manufacturing systems. SOSJ combines the system-level language SystemJ and service oriented architecture (SOA) paradigm to take advantages of both SystemJ's correct-by-construction formal semantics and SOA's dynamic features, respectively. The paper describes the concepts and functionalities of SOSJ which enable dynamic reconfiguration of a typical manufacturing system. Performance benchmarks are run to compare the capabilities of SOSJ to a multi-agent system framework JADE.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dynamic Reconfiguration and Adaptation of Manufacturing Systems Using SOSJ Framework

Atmojo

Salčić

Wang

2018

IEEE Trans. Ind. Inf.

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“…One of the essential characteristics of IEC 61499 is the ability to reconfigure the system dynamically, i.e., during its execution. Thanks to a compliance profile, it is possible to send a set of controls to the device during its execution 1 [9]. The authors in [10] define specifications for a control architecture to support dynamic reconfiguration.…”

Section: Iec 61499 Reconfiguration Abilitiesmentioning

confidence: 99%

Model-Based Engineering for Designing Cyber-Physical Systems Control Architecture and Improving Adaptability from Requirements

Parant

Gellot

Alexandre

et al. 2022

Service Oriented, Holonic and Multi-Agent Manufacturing Systems for Industry of the Future

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Model-Based Engineering (MBE) is a method for reducing complexity in system design. This paper presents a methodology for designing Cyber-Physical System (CPS) and its control system using System Modeling Language (SysML) diagrams and IEC 61499 standard. The real-time control system is designed from high-level knowledge and tested software components on the plug and produce principle. This paper presents an application case to demonstrate the feasibility of our approach. In addition, a set of solutions is presented to reduce the time and improve the engineering and traceability of configuration changes during the system lifecycle.

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“…There have been efforts to introduce formal MoC into these standards such as [4], [5], but they lack mechanisms to handle dynamic changes. Attempts to introduce dynamic adaptations into IEC 61499 (such as [6] and [7]) and IEC 61131 (such as [8]) exist, however only partial/limited reconfiguration is enabled. Other programming technologies such as the multiagent systems (MAS) (e.g., JADE [9], JIAC [10]) and the service oriented architecture (SOA) (such as device profile for web services (DPWS) [11], Arrowhead [12]) are used in the context of dynamic systems.…”

Section: Introductionmentioning

confidence: 99%

A Service-Oriented Programming Approach for Dynamic Distributed Manufacturing Systems

Atmojo

Salčić

Wang

et al. 2020

IEEE Trans. Ind. Inf.

Self Cite

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Dynamic reconfigurability and adaptability are crucial features of the future manufacturing systems that must be supported by adequate software technologies. Currently, they are typically achieved as add-ons to existing software tools and run-time systems, which are not based on any formal foundation such as formal model of computation (MoC). This paper presents the new programming paradigm of service oriented SystemJ (SOSJ), which targets dynamic distributed software systems suited for future manufacturing applications. SOSJ is built on a merger and the synergies of two programming concepts of service oriented architecture, to support dynamic software system composition, and SystemJ programming language based on a formal MoC, which targets correct by construction design of static distributed software systems. The resulting programming paradigm allows the design and implementation of dynamic distributed software systems.

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Extension of reconfigurability provisions in IEC 61499

Cited by 15 publications

References 10 publications

Dynamic Reconfiguration and Adaptation of Manufacturing Systems Using SOSJ Framework

Dynamic Reconfiguration and Adaptation of Manufacturing Systems Using SOSJ Framework

Model-Based Engineering for Designing Cyber-Physical Systems Control Architecture and Improving Adaptability from Requirements

A Service-Oriented Programming Approach for Dynamic Distributed Manufacturing Systems

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