7 research outputs found
PAIRSE: A Privacy-Preserving Service-Oriented Data Integration System
Get PDFInternational audiencePrivacy is among the key challenges to data integration in many sectors, including healthcare, e-government, etc. The PAIRSE project aims at providing a flexible, looselycoupled and privacy-preserving data integration system in P2P environments. The project exploits recent Web standards and technologies such as Web services and ontologies to export data from autonomous data providers as reusable services, and proposes the use of service composition as a viable solution to answer data integration needs on the fly. The project proposed new composition algorithms and service/composition execution models that preserve privacy of data manipulated by services and compositions. The proposed integration system was demonstrated at EDBT 2013 and VLDB 2011
ModĂšle dâarchitecture personnalisable pour lâoptimisation de lâaccĂšs Ă des ressources et services pervasifs : Application Ă la tĂ©lĂ©mĂ©decine
No full textThe growing development and use of pervasive systems, equipped with increasingly sophisticated functionalities and communication means, offer fantastic potentialities of services, particularly in the eHealth and Telemedicine domains, for the benifit of each citizen, patient or healthcare professional. One of the current societal challenges is to enable a better exploitation of the available services for all actors involved in a given domain. Nevertheless, the multiplicity of the offered services, the systems functional variety, and the heterogeneity of the needs require the development of knowledge models of these services, systems functions, and needs. In addition, the distributed computing environments heterogeneity, the availability and potential capabilities of various human and material resources (devices, services, data sources, etc.) required by the different tasks and processes, the variety of services providing users with data, the interoperability conflicts between schemas and data sources are all issues that we have to consider in our research works. Our contribution aims to empower the intelligent exploitation of ubiquitous resources and to optimize the quality of service in ambient environment. For this, we propose a knowledge meta-model of the main concepts of a pervasive environment, such as Actor, Task, Resource, Object, Service, Location, Organization, etc. This knowledge meta-model is based on ontologies describing the different aforementioned entities from a given domain and their interrelationships. We have then formalized it by using a standard language for knowledge description. After that, we have designed an architectural framework called ONOF-PAS (ONtology Oriented Framework for Pervasive Applications and Services) mainly based on ontological models, a set of rules, an inference engine, and object oriented components for tasks management and resources processing. Being generic, extensible, and applicable in different domains, ONOF-PAS has the ability to perform rule-based reasoning to handle various contexts of use and enable decision making in dynamic and heterogeneous environments while taking into account the availability and capabilities of the human and material resources required by the multiples tasks and processes executed by pervasive systems. Finally, we have instantiated ONOF-PAS in the telemedicine domain to handle the scenario of the transfer of persons victim of health problems during their presence in hostile environments such as high mountains resorts or geographically isolated areas. A prototype implementing this scenario, called T-TROIE (Telemedicine Tasks and Resources Ontologies for Inimical Environments), has been developed to validate our approach and the proposed ONOF-PAS framework.Le dĂ©veloppement et lâusage croissants de systĂšmes pervasifs, dotĂ©s de fonctionnalitĂ©s et de moyens de communication de plus en plus sophistiquĂ©s, offrent de fantastiques potentialitĂ©s de services, en particulier pour lâe-SantĂ© et la tĂ©lĂ©mĂ©decine, au bĂ©nĂ©fice de tout citoyen, patient ou professionnel de santĂ©. Lâun des challenges sociĂ©taux actuels est de permettre une meilleure exploitation des services disponibles pour lâensemble des acteurs impliquĂ©s dans un domaine donnĂ©. Mais la multiplicitĂ© des services offerts, la diversitĂ© fonctionnelle des systĂšmes, et lâhĂ©tĂ©rogĂ©nĂ©itĂ© des besoins nĂ©cessitent lâĂ©laboration de modĂšles de connaissances de ces services, des fonctions de ces systĂšmes et des besoins. En outre, lâhĂ©tĂ©rogĂ©nĂ©itĂ© des environnements informatiques distribuĂ©s, la disponibilitĂ© et les capacitĂ©s potentielles des diverses ressources humaines et matĂ©rielles (instrumentation, services, sources de donnĂ©es, etc.) requises par les diffĂ©rentes tĂąches et processus, la variĂ©tĂ© des services qui fournissent des donnĂ©es aux utilisateurs, et les conflits dâinteropĂ©rabilitĂ© entre schĂ©mas et sources de donnĂ©es sont autant de problĂ©matiques que nous avons Ă considĂ©rer au cours de nos travaux de recherche. Notre contribution vise Ă optimiser la qualitĂ© de services en environnement ambiant et Ă rĂ©aliser une exploitation intelligente de ressources ubiquitaires. Pour cela, nous proposons un mĂ©ta-modĂšle de connaissances des principaux concepts Ă prendre en compte en environnement pervasif. Ce mĂ©ta-modĂšle est basĂ© sur des ontologies dĂ©crivant les diffĂ©rentes entitĂ©s prĂ©citĂ©es dans un domaine donnĂ© ainsi que leurs relations. Puis, nous lâavons formalisĂ© en utilisant un langage standard de description des connaissances. A partir de ce modĂšle, nous proposons alors une nouvelle mĂ©thodologie de construction dâun framework architectural, que nous avons appelĂ© ONOF-PAS. ONOF-PAS est basĂ© sur des modĂšles ontologiques, une base de rĂšgles, un moteur dâinfĂ©rence, et des composants orientĂ©s objet permettant la gestion des diffĂ©rentes tĂąches et le traitement des ressources. Il sâagit dâune architecture gĂ©nĂ©rique, applicable Ă diffĂ©rents domaines. ONOF-PAS a la capacitĂ© dâeffectuer un raisonnement Ă base de rĂšgles pour gĂ©rer les diffĂ©rents contextes dâutilisation et aider Ă la prise de dĂ©cision dans des environnements hĂ©tĂ©rogĂšnes dynamiques, tout en tenant compte de la disponibilitĂ© et de la capacitĂ© des ressources humaines et matĂ©rielles requises par les diverses tĂąches et processus exĂ©cutĂ©s par des systĂšmes dâinformation pervasifs. Enfin, nous avons instanciĂ© ONOF-PAS dans le domaine de la tĂ©lĂ©mĂ©decine pour traiter le scĂ©nario de lâorientation des patients ou de personnes victimes de problĂšmes de santĂ© en environnement hostile telles que la haute montagne ou des zones gĂ©ographiquement isolĂ©es. Un prototype dâimplĂ©mentation de ces scĂ©narios, appelĂ© T-TROIE a Ă©tĂ© dĂ©veloppĂ© afin de valider le framework ONOF-PAS
ModĂšle dâarchitecture personnalisable pour lâoptimisation de lâaccĂšs Ă des ressources et services pervasifs : Application Ă la tĂ©lĂ©mĂ©decine
No full textThe growing development and use of pervasive systems, equipped with increasingly sophisticated functionalities and communication means, offer fantastic potentialities of services, particularly in the eHealth and Telemedicine domains, for the benifit of each citizen, patient or healthcare professional. One of the current societal challenges is to enable a better exploitation of the available services for all actors involved in a given domain. Nevertheless, the multiplicity of the offered services, the systems functional variety, and the heterogeneity of the needs require the development of knowledge models of these services, systems functions, and needs. In addition, the distributed computing environments heterogeneity, the availability and potential capabilities of various human and material resources (devices, services, data sources, etc.) required by the different tasks and processes, the variety of services providing users with data, the interoperability conflicts between schemas and data sources are all issues that we have to consider in our research works. Our contribution aims to empower the intelligent exploitation of ubiquitous resources and to optimize the quality of service in ambient environment. For this, we propose a knowledge meta-model of the main concepts of a pervasive environment, such as Actor, Task, Resource, Object, Service, Location, Organization, etc. This knowledge meta-model is based on ontologies describing the different aforementioned entities from a given domain and their interrelationships. We have then formalized it by using a standard language for knowledge description. After that, we have designed an architectural framework called ONOF-PAS (ONtology Oriented Framework for Pervasive Applications and Services) mainly based on ontological models, a set of rules, an inference engine, and object oriented components for tasks management and resources processing. Being generic, extensible, and applicable in different domains, ONOF-PAS has the ability to perform rule-based reasoning to handle various contexts of use and enable decision making in dynamic and heterogeneous environments while taking into account the availability and capabilities of the human and material resources required by the multiples tasks and processes executed by pervasive systems. Finally, we have instantiated ONOF-PAS in the telemedicine domain to handle the scenario of the transfer of persons victim of health problems during their presence in hostile environments such as high mountains resorts or geographically isolated areas. A prototype implementing this scenario, called T-TROIE (Telemedicine Tasks and Resources Ontologies for Inimical Environments), has been developed to validate our approach and the proposed ONOF-PAS framework.Le dĂ©veloppement et lâusage croissants de systĂšmes pervasifs, dotĂ©s de fonctionnalitĂ©s et de moyens de communication de plus en plus sophistiquĂ©s, offrent de fantastiques potentialitĂ©s de services, en particulier pour lâe-SantĂ© et la tĂ©lĂ©mĂ©decine, au bĂ©nĂ©fice de tout citoyen, patient ou professionnel de santĂ©. Lâun des challenges sociĂ©taux actuels est de permettre une meilleure exploitation des services disponibles pour lâensemble des acteurs impliquĂ©s dans un domaine donnĂ©. Mais la multiplicitĂ© des services offerts, la diversitĂ© fonctionnelle des systĂšmes, et lâhĂ©tĂ©rogĂ©nĂ©itĂ© des besoins nĂ©cessitent lâĂ©laboration de modĂšles de connaissances de ces services, des fonctions de ces systĂšmes et des besoins. En outre, lâhĂ©tĂ©rogĂ©nĂ©itĂ© des environnements informatiques distribuĂ©s, la disponibilitĂ© et les capacitĂ©s potentielles des diverses ressources humaines et matĂ©rielles (instrumentation, services, sources de donnĂ©es, etc.) requises par les diffĂ©rentes tĂąches et processus, la variĂ©tĂ© des services qui fournissent des donnĂ©es aux utilisateurs, et les conflits dâinteropĂ©rabilitĂ© entre schĂ©mas et sources de donnĂ©es sont autant de problĂ©matiques que nous avons Ă considĂ©rer au cours de nos travaux de recherche. Notre contribution vise Ă optimiser la qualitĂ© de services en environnement ambiant et Ă rĂ©aliser une exploitation intelligente de ressources ubiquitaires. Pour cela, nous proposons un mĂ©ta-modĂšle de connaissances des principaux concepts Ă prendre en compte en environnement pervasif. Ce mĂ©ta-modĂšle est basĂ© sur des ontologies dĂ©crivant les diffĂ©rentes entitĂ©s prĂ©citĂ©es dans un domaine donnĂ© ainsi que leurs relations. Puis, nous lâavons formalisĂ© en utilisant un langage standard de description des connaissances. A partir de ce modĂšle, nous proposons alors une nouvelle mĂ©thodologie de construction dâun framework architectural, que nous avons appelĂ© ONOF-PAS. ONOF-PAS est basĂ© sur des modĂšles ontologiques, une base de rĂšgles, un moteur dâinfĂ©rence, et des composants orientĂ©s objet permettant la gestion des diffĂ©rentes tĂąches et le traitement des ressources. Il sâagit dâune architecture gĂ©nĂ©rique, applicable Ă diffĂ©rents domaines. ONOF-PAS a la capacitĂ© dâeffectuer un raisonnement Ă base de rĂšgles pour gĂ©rer les diffĂ©rents contextes dâutilisation et aider Ă la prise de dĂ©cision dans des environnements hĂ©tĂ©rogĂšnes dynamiques, tout en tenant compte de la disponibilitĂ© et de la capacitĂ© des ressources humaines et matĂ©rielles requises par les diverses tĂąches et processus exĂ©cutĂ©s par des systĂšmes dâinformation pervasifs. Enfin, nous avons instanciĂ© ONOF-PAS dans le domaine de la tĂ©lĂ©mĂ©decine pour traiter le scĂ©nario de lâorientation des patients ou de personnes victimes de problĂšmes de santĂ© en environnement hostile telles que la haute montagne ou des zones gĂ©ographiquement isolĂ©es. Un prototype dâimplĂ©mentation de ces scĂ©narios, appelĂ© T-TROIE a Ă©tĂ© dĂ©veloppĂ© afin de valider le framework ONOF-PAS
ModÚle d architecture personnalisable pour l optimisation de l accÚs à des ressources et services pervasifs (Application à la télémédecine)
No full textLe développement et l usage croissants de systÚmes pervasifs, dotés de fonctionnalités et de moyens de communication de plus en plus sophistiqués, offrent de fantastiques potentialités de services, en particulier pour l e-Santé et la télémédecine, au bénéfice de tout citoyen, patient ou professionnel de santé. L un des challenges sociétaux actuels est de permettre une meilleure exploitation des services disponibles pour l ensemble des acteurs impliqués dans un domaine donné. Mais la multiplicité des services offerts, la diversité fonctionnelle des systÚmes, et l hétérogénéité des besoins nécessitent l élaboration de modÚles de connaissances de ces services, des fonctions de ces systÚmes et des besoins. En outre, l hétérogénéité des environnements informatiques distribués, la disponibilité et les capacités potentielles des diverses ressources humaines et matérielles (instrumentation, services, sources de données, etc.) requises par les différentes tùches et processus, la variété des services qui fournissent des données aux utilisateurs, et les conflits d interopérabilité entre schémas et sources de données sont autant de problématiques que nous avons à considérer au cours de nos travaux de recherche. Notre contribution vise à optimiser la qualité de services en environnement ambiant et à réaliser une exploitation intelligente de ressources ubiquitaires. Pour cela, nous proposons un méta-modÚle de connaissances des principaux concepts à prendre en compte en environnement pervasif. Ce méta-modÚle est basé sur des ontologies décrivant les différentes entités précitées dans un domaine donné ainsi que leurs relations. Puis, nous l avons formalisé en utilisant un langage standard de description des connaissances. A partir de ce modÚle, nous proposons alors une nouvelle méthodologie de construction d un framework architectural, que nous avons appelé ONOF-PAS. ONOF-PAS est basé sur des modÚles ontologiques, une base de rÚgles, un moteur d inférence, et des composants orientés objet permettant la gestion des différentes tùches et le traitement des ressources. Il s agit d une architecture générique, applicable à différents domaines. ONOF-PAS a la capacité d effectuer un raisonnement à base de rÚgles pour gérer les différents contextes d utilisation et aider à la prise de décision dans des environnements hétérogÚnes dynamiques, tout en tenant compte de la disponibilité et de la capacité des ressources humaines et matérielles requises par les diverses tùches et processus exécutés par des systÚmes d information pervasifs. Enfin, nous avons instancié ONOF-PAS dans le domaine de la télémédecine pour traiter le scénario de l orientation des patients ou de personnes victimes de problÚmes de santé en environnement hostile telles que la haute montagne ou des zones géographiquement isolées. Un prototype d implémentation de ces scénarios, appelé T-TROIE a été développé afin de valider le framework ONOF-PAS.The growing development and use of pervasive systems, equipped with increasingly sophisticated functionalities and communication means, offer fantastic potentialities of services, particularly in the eHealth and Telemedicine domains, for the benifit of each citizen, patient or healthcare professional. One of the current societal challenges is to enable a better exploitation of the available services for all actors involved in a given domain. Nevertheless, the multiplicity of the offered services, the systems functional variety, and the heterogeneity of the needs require the development of knowledge models of these services, systems functions, and needs. In addition, the distributed computing environments heterogeneity, the availability and potential capabilities of various human and material resources (devices, services, data sources, etc.) required by the different tasks and processes, the variety of services providing users with data, the interoperability conflicts between schemas and data sources are all issues that we have to consider in our research works. Our contribution aims to empower the intelligent exploitation of ubiquitous resources and to optimize the quality of service in ambient environment. For this, we propose a knowledge meta-model of the main concepts of a pervasive environment, such as Actor, Task, Resource, Object, Service, Location, Organization, etc. This knowledge meta-model is based on ontologies describing the different aforementioned entities from a given domain and their interrelationships. We have then formalized it by using a standard language for knowledge description. After that, we have designed an architectural framework called ONOF-PAS (ONtology Oriented Framework for Pervasive Applications and Services) mainly based on ontological models, a set of rules, an inference engine, and object oriented components for tasks management and resources processing. Being generic, extensible, and applicable in different domains, ONOF-PAS has the ability to perform rule-based reasoning to handle various contexts of use and enable decision making in dynamic and heterogeneous environments while taking into account the availability and capabilities of the human and material resources required by the multiples tasks and processes executed by pervasive systems. Finally, we have instantiated ONOF-PAS in the telemedicine domain to handle the scenario of the transfer of persons victim of health problems during their presence in hostile environments such as high mountains resorts or geographically isolated areas. A prototype implementing this scenario, called T-TROIE (Telemedicine Tasks and Resources Ontologies for Inimical Environments), has been developed to validate our approach and the proposed ONOF-PAS framework.VILLEURBANNE-DOC'INSA LYON (692662301) / SudocVILLEURBANNE-DOC'INSA-Bib. elec. (692669901) / SudocSudocFranceF
Data Privacy Preservation in Telemedicine: The PAIRSE Project
No full textInternational audienceThe preservation of medical data privacy and confidentiality is a majorchallenge in eHealth systems and applications. A technological solution based onadvanced information and communication systems architectures is needed in orderto retrieve and exchange the patientâs data in a secure and reliable manner. In thispaper, we introduce the project PAIRSE, Preserving Privacy in Peer to Peer (P2P)environments, which proposes an original web service oriented frameworkpreserving the privacy and confidentiality of shared or exchanged medical data
Microservices-Based Architecture to Support the Adaptive RECORDS-Trial
No full textInformation systems used by platform trials should handle changes that are not predefined. Unfortunately, the technical architecture of most existing clinical data management systems (CDMS) do not support changes to be incorporated into an ongoing trial. Adaptive clinical trials need advanced architectural solutions setup to enable biomarker stratification and enrichment strategy necessary for the adaptive clinical trial operation. This short paper presents the microservices-based architecture solution that is used to run and support the adaptive RECORDS-Trial
