Ambient intelligence in self-organising assembly systems using the chemical reaction model

Frei, Regina; Serugendo, Giovanna Di Marzo; Şerbănuţă, Traian Florin

doi:10.1007/s12652-010-0016-0

Cited by 15 publications

(11 citation statements)

References 47 publications

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“…Beside having been conceived as general computational model, chemically-inspired computing can be an effective starting point to realize schemes of dynamic service composition [61] or knowledge aggregation [62]. Network protocols for data distribution and aggregation according to chemical models have also been explored, as in the Fraglets approach [63,64].…”

Section: Chemical Coordinationmentioning

confidence: 99%

Developing pervasive multi-agent systems with nature-inspired coordination

Zambonelli

Omicini

Anzengruber³

et al. 2015

Pervasive and Mobile Computing

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Pervasive computing systems can be modeled effectively as populations of interacting autonomous components. The key challenge to realizing such models is in getting separately-specified and -developed sub-systems to discover and interoperate with each other in an open and extensible way, supported by appropriate middleware services. In this paper, we argue that nature-inspired coordination models offer a promising way of addressing this challenge. We first frame the various dimensions along which nature-inspired coordination models can be defined, and survey the most relevant proposals in the area. We describe the nature-inspired coordination model developed within the SAPERE project as a synthesis of existing approaches, and show how it can effectively support the multifold requirements of modern and emerging pervasive services. We conclude by identifying what we think are the open research challenges in this area, and identify some research directions that we believe are promising.

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Section: Chemical Coordinationmentioning

confidence: 99%

Developing pervasive multi-agent systems with nature-inspired coordination

Zambonelli

Omicini

Anzengruber³

et al. 2015

Pervasive and Mobile Computing

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“…The focus of [28], however is not on adaptive systems, but rather on well-formedness scheduling criteria to ensure correctness of statistical model checking techniques (discussed later in Section 7.3). Self-organizing assembly systems, instead, are addressed in [32] using Maude as specification language and the Chemical Abstract Machine (CHAM) [33] as architecture and programming paradigm. CHAM shares some similarities with RRDs in general and our approach in particular, including the use of (reactive) rule-based specifications and nested architectures.…”

Section: Hierarchical Architectures and Models For Adaptive Systemsmentioning

confidence: 99%

“…CHAM shares some similarities with RRDs in general and our approach in particular, including the use of (reactive) rule-based specifications and nested architectures. The approach described in [32], however, does not rely on reflection nor on quantitative analysis.…”

Section: Hierarchical Architectures and Models For Adaptive Systemsmentioning

confidence: 99%

Modelling and analyzing adaptive self-assembly strategies with Maude

Bruni

Corradini

Gadducci

et al. 2015

Science of Computer Programming

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Building adaptive systems with predictable emergent behavior is a difficult task and it is becoming a critical need. The research community has accepted the challenge by introducing approaches of various nature: from software architectures to programming paradigms and analysis techniques. Our white-box conceptual approach to adaptive systems based on the notion of control data promotes a clear distinction between the application and the adaptation logic. In this paper we propose a concrete instance of our approach based on (i) a neat identification of control data; (ii) a hierarchical architecture that provides the basic structure to separate the adaptation and application logics; (iii) computational reflection as the main mechanism to realize the adaptation logic; (iv) probabilistic rule-based specifications and quantitative verification techniques to specify and analyze the adaptation logic. We show that our solution can be naturally realized in Maude, a Rewriting Logic based framework, and illustrate our approach by specifying, validating and analyzing a prominent example of adaptive systems: robot swarms equipped with self-assembly strategies

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“…A brief summary is in (Di Marzo Serugendo and Frei 2012). In (Frei et al 2010a) we explained the various relevant concepts, which are briefly reviewed in this article, clarified the relation between Ambient Intelligence and SOAS, and presented the first part of the formal specifications. This work has now been completed and serves as a proof of concept.…”

Section: Introductionmentioning

confidence: 99%

“…Evolvable and self-organising assembly systems revisit this way of building systems and demonstrate Ambient Intelligence features and responsiveness to people along the following three lines (Frei et al 2010a):…”

Section: Introductionmentioning

confidence: 99%

Self-organising assembly systems formally specified in Maude

Frei

Şerbănuţă

Serugendo

2012

J Ambient Intell Human Comput

Self Cite

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This article recapitulates on the research done in Self-Organising Assembly Systems (SOAS) and presents the completed formal specifications and their simulation in Maude. SOAS are assembly systems that (1) participate in their own design by spontaneously organising themselves in the shop floor layout in response to the arrival of a product order and (2) manage themselves during production. The self-organising process for SOAS to design themselves follows the Chemical Abstract Machine (CHAM) paradigm: industrial robots self-select and self-arrange according to specific chemical rules in response to a product order with generic assembly instructions (GAP). This article presents an additional set of rules describing how the GAP is transformed into Layout-Specific Assembly Instructions (LSAI), which is a kind of recipe for how the self-organising robots assemble the product.

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Ambient intelligence in self-organising assembly systems using the chemical reaction model

Cited by 15 publications

References 47 publications

Developing pervasive multi-agent systems with nature-inspired coordination

Developing pervasive multi-agent systems with nature-inspired coordination

Modelling and analyzing adaptive self-assembly strategies with Maude

Self-organising assembly systems formally specified in Maude

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