Changes for page Workpackages

From version 27.2
edited by Andrea Omicini
on 23/03/2023 00:27
Change comment: Updated the relative links.
To version 18.1
edited by Andrea Omicini
on 26/11/2021 19:34
Change comment: There is no comment for this version

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1 -= Workpackages =
1 += Background Papers in {{apice/}} =
2 2  
3 -* [[WP1>>SAPERE.1.WebHome]] – Project Management & Coordination
4 -* [[WP2>>SAPERE.2.WebHome]] – Requirement Collection & Integration
5 -* [[WP3>>SAPERE.3.WebHome]] – Diagnosis & Awareness Sub-component
6 -* [[WP4>>SAPERE.4.WebHome]] – Reparation & Mitigation Sub-component
7 -* [[WP5>>SAPERE.5.WebHome]] – Methodology Sub-component
8 -* [[WP6>>SAPERE.6.WebHome]] – Legal & Social Awareness
9 -* [[WP7>>SAPERE.7.WebHome]] – Synthetic & Real Data Validation
10 -* [[WP8>>SAPERE.8.WebHome]] – Dissemination, Outreach Activities, Training & Awareness
3 +{{velocity}}
4 +(% style="border-style:solid hidden hidden solid; border-color:$theme.borderColor" %)!!{{pub}}CollectivesortScp74{{/pub}}
5 +(% style="border-style:hidden solid solid hidden; border-color:$theme.borderColor" %)!!This article presents a comprehensive description of an ant-based, self-organizing algorithms for data aggregation in networks of distributed tuple spaces, showing that data can emergently achieve a cluster-based spatial organization depending on the shape of the carried information.
6 +(% style="border-style:solid hidden hidden solid; border-color:$theme.borderColor" %)!!{{pub}}SelforgcoordSac09{{/pub}}
7 +(% style="border-style:hidden solid solid hidden; border-color:$theme.borderColor" %)!!This paper provides a definition of self-organizing coordination, intended as the way of managing interactions in software system by relying on self-organizing metaphors. The key features of self-organizing coordination are also introduced and described and a series of examples of systems relying on self-organizing coordination approaches presented.
8 +(% style="border-style:solid hidden hidden solid; border-color:$theme.borderColor" %)!!{{pub}}EcoservicesIns180{{/pub}}
9 +(% style="border-style:hidden solid solid hidden; border-color:$theme.borderColor" %)!!We believe this paper is currently the one which most clearly states the requirements and objectives of pervasive service ecosystems. It also sketches a chemical-inspired approach to eco-laws construction, where chemical concentration is used to manage a service "activity value", promoting some ecological patterns of behaviour.
10 +----
11 +
12 +#pubATVblock("ChemcoordSoarbook")
13 +This paper motivates the use of a model of chemical tuple spaces for the coordination of situated, adaptive, and diversity-accommodating pervasive systems.
14 +Moreover it is outlined a incarnation of that model on the TuCSoN coordination infrastructure, which can be suitably enhanced with modules supporting
15 +semantic coordination and execution engine for chemical-inspired coordination laws.
16 +----
17 +
18 +#pubATVblock("BiochemicaltuplespaceSac10")
19 +This paper introduces a model of service self-composition based on the use of ecological laws, which are specified by relying on the biochemical tuple space model. The paper shows how service lifetime can be completely managed in a self-organizing way as regards both survival/extinction and composition with other services.
20 +----
21 +
22 +#pubATVblock("SemCoordSac2010")
23 +This paper show how to empower a tuple space model with semantic techniques by equipping tuple spaces with the ontological description of the coordination
24 +domain and by describing tuples as domain individuals described in terms of the ontology.
25 +In particular, the paper shows how such a model is very useful to address distributed and open scenarios.
26 +The model was implemented in the coordination infrastructure TuCSoN.
27 +----
28 +
29 +#pubATVblock("MorphoEngBook13")
30 +The paper presents a computational model for capturing scenarios of spatial self-organisation.
31 +In particular it deals with the spatial pattern of gene expression generated in multicellular organisms during morphogenesis.
32 +I believe it can be of interest in the description of a possible model able to reproduce such a complex phenomenon, in the results obtained with the model of a particular organism (Drosophila Melanogaster) and in the considerations proposed for the use of morphogenetic mechanisms in the generation of artificial systems with similar behaviour.
33 +----
34 +
35 +#pubATVblock("SelforgcoordKer25years")
36 +Here we discuss the potential of coordination models and languages as the sources for the abstractions and the technologies around which complex computational systems ~-- like intelligent, knowledge-intensive, pervasive, self-organising systems ~-- can be designed and built.
37 +----
38 +
39 +#pubATVblock("FuzzycoordSac11")
40 +The paper shows an extension of semantic tuple spaces with fuzzy techniques in order to also represent vague/fuzzy knowledge so often required by real-world application scenarios.
41 +In particular in this paper it is extended the model of Description Logic tuple spaces with fuzziness in order to support fuzzy semantic coordination.
42 +----
43 +
44 +#pubATVblock("SpatialTaas11")
45 +This paper motivates the use of a model of chemical tuple spaces for the coordination of pervasive service ecosystems. A case study of adaptive pervasive displays is used to show patterns of service competition, and of creation of computational fields based on chemical diffusion.
46 +{{/velocity}}