Resultado final
VICINITY core components software upgrades packages with release notes will be continuously provided integrated validated and deployed in the cloud Software packages will include necessary functional and security bug fixes functional updates and changes Upgrades will be provided at the end of VICINITY Framework Integration Lab Testing and at the end of Validation of VICINITY system
Open Interoperability Gateway API, first versionOpen Interoperability Gateway API packages and API integration support materials will be publicly published on internet and accessible for VICINITY users and wide public. Open Interoperability Gateway API packages will consists of libraries and adapter examples. The functionality provided by Open Interoperability Gateway API will be summarized in Release Note.
VICINITY core components continuous upgrades, final versionVICINITY core components software upgrades packages with release notes will be continuously provided, integrated, validated and deployed in the cloud. Software packages will include necessary functional and security bug fixes, functional updates and changes. Upgrades will be provided at the end of VICINITY Framework Integration & Lab Testing and at the end of Validation of VICINITY system.
VICINITY client components continuous upgrades, final versionDeliverable 4.4 contains the integrated client platform conformed from D4.1, D4.2 and D4.3, as well as the software upgrades and bug fixes until deliverable's due date.
VICINITY test-bed deployment, including Validation, Parameterization and TestingThis deliverable will provide the data of the implementation and experimental results obtained in labscale facilities regarding control design energy management systems implementation and ICT integration Conclusions recommendations and guidelines for largescale implementation will be provided as well
Web-based VICINITY neighbourhood managerThe VICINITY Neighbourhood manager software packages will be provided configured and integrated with other components of VICINITY Software packages will be deployed on cloudbased virtual server infrastructure according to the VICINITY architectural design The VICINITY Neighbourhood manager will be publicly available on internet via standard webbrowser The functionality provided by webbased VICINITY neighbourhood manager will be summarised in a release note
Set of open sample VICINITY gateway adaptersIn the deliverable D41 a framework for designing VICINITY Gateway Adapters will be presented On its basis several VICINITY aware gateway adapters for appliances and other objects will be created Gateway adapters will contain support for Open VICINITY gateway API D33 which will provide a communication channel and suitable methods to communicate with the VICINITY communication server D11 Thus the main purpose of VICINITY gateway adapters will be to unify a communication flow that become manageable by using VICINITY Neighbourhood Manager D32
Open Interoperability Gateway API, final versionOpen Interoperability Gateway API packages and API integration support materials will be publicly published on internet and accessible for VICINITY users and wide public Open Interoperability Gateway API packages will consists of libraries and adapter examples The functionality provided by Open Interoperability Gateway API will be summarised in a release note
VICINITY value-added services deployment, validation, upgrade and evaluationReport on the deployment and realisation of the implemented value-added services per each pilot Use Case, including validation against their requirements, possible upgrades and final evaluation of both technical aspects and user experience.
VICINITY client components continuous upgrades, first versionDeliverable 44 contains the integrated client platform conformed from D41 D42 and D43 as well as the software upgrades and bug fixes until deliverables due date
VICINITY Agent and Auto-Discovery platformThe deliverable will contain the software components for VICINITY Agent and AutoDiscovery platform implemented within T42 Namely the semantically enhanced discovery of existing IoT devices on the client side will be handled by semantic query mechanisms supported by dynamic agentbased retrieval of IoT device parameters from existing IoT device repositories A written description of the platform architecture functionality and implementation details will be provided as well
VICINITY Security ServicesVICINITY security services will include endtoend gateway to gateway and data encryption service based on stateoftheart COTS tools and libraries and authorization services software packages integrated with VICINITY Neighbourhood database The functionality of VICINITY security services will be summarised in a release note
VICINITY integrated prototypeThe deliverable will provide the integrated prototype serving as a base of VICINITY prototype based on the requirements set in WP1and can be demonstrate the Use Cases for the envisioned scenarios Adapters from the laboratory environments will be developed by partners CERTH will integrate available testbest facilities of smart house and intelligent building multisensorial infrastructure available AAU will integrate ICT solutions and energy systems together with control and energy management systems Lab tests will be done in the microgrid research labs of AAU TINYM will integrate its own proprietary generic IoT solution and the monitor solutions for online wireless measurement of indoor air quality usage patterns and energy consumption in buildings Finally ATOS will integrate with its Internet of Everything Lab IoE Lab
Semantic discovery and dynamic configuration servicesThe deliverable will provide the software components serving as a base of VICINITY semantic discovery and dynamic configuration service platform accompanied by a written description of design architecture and implementation details The produced software components will include the unified VICINITY semantic repository of IoT drivers that will enable a connection with external repositories by means of API for standardized adaptors and endpoints management including the services of semantic discovery and mapping of IoT driver descriptors to the Generic IoT ontology
VICINITY value-added services implementation frameworkDetailed definition of valueadded services including requirements and architectural design specification to be implemented and demonstrated per each pilot Use Case
High-available VICINITY server deploymentThe highavailable virtual server infrastructure including VICINITY Communication Service software packages will be provided configured integrated and deployed in the cloud according to the VICINITY architectural design The functionality provided by highavailable VICINITY server will be summarised in a release note
One of the core activities of VICINITY project will be to evaluate its results against the use cases and requirements specified in D81 so as to validate the actual performance and impact of the project framework and identify any gaps and further work required The deliverable will identify the business scenarios and use cases that the project will test against based on D14 and specify the evaluation framework within which these will be tested The use cases must be capable of operating from the common VICINITY platform and use as much common software as possible to avoid unnecessary repetition of design Performance indices should be provided autonomously within each use case so that data may be recorded in real time and be remotely read by the network management system using a real time dashboard All use cases should appear on the dashboard The technical feasibility and effectiveness of each use case will be assessed via questionnaires so that individual users can provide ratings of the system performance and these will be specified here It is important that the evaluation framework allows for iterative testing and assessment of the framework so that test procedures can be changed based on actual experience and the dashboard continuously updated
Analysis of Standardisation Context and Recommendations for Standards InvolvementThe deliverable will map out the standards landscape and the ecosystem relevant to IoT and specifically the place of VICINITY within it. It will analyse the existing standards and on-going work items relevant to IoT and VICINITY, and recommend the standards involvement that VICINITY partners will undertake over the life of the project. It is very important that VICINITY participates in the recent EC AIOTI standards landscaping initiative and downstreams its results into standards groups such as ETSI SmartM2M, ITS and EE, the oneM2M Partnership Project, ITU-T SG20 and Q20/5, CEN TC278 and ISO TC22 and TC204 so that the European and global community can adopt common systems and interfaces to realise the application benefits, reduce cost and risks. However, there will be insufficient resources to engage with all relevant standards bodies and the project must select the most important working groups and target these for contributions.
Report on business drivers and barriers of IoT interoperability and value added servicesStakeholders will be approached to provide information related to vendor locks in the IoT systems currently used, IoT related motivations, IoT related expectations and IoT interoperability inhibitors. The established VICINITY advisory board shall be involved at identification of current and future IoT nteroperability challenges and barriers (security, privacy, legal, commercial, cultural etc.).
VICINITY requirement capture frameworkThe report will state the requirement capture process to get from the stakeholders communities’ workshops and the VICINITY Advisory Board members technical information related to sensors, smart objects, data sets, information management tools and other information systems and non-technical information related to commercial, security and legal aspects.
Pilot results of Smart Energy MicroGrid Neighbourhood use-caseThis comparative benchmarking report will include ENERC’s Smart Energy MicroGrid Neighborhood (microgrid community) use-case evaluation based on the detailed framework defined in T8.1. The compliance evaluation will take into account user and business requirements defined in both WP1 and WP2. Included performance indicators and metrics will be specific to the use case and developed by ENERC. According to the Pilot Evaluation Framework, the report will document contributions from stakeholders, pilot managers, users/citizens during piloting activities, through interviews towards the evaluation of technical feasibility, effectiveness, usability, economic rationale, and environmental impact, so to rate the performance in each category. The report will include evaluation-benchmarking criteria related to efficiency, appropriateness and usability of solutions. The matrix report will include the results of stakeholder engagement; Vicinity concept applicability to microgrid driven community, interoperability results and document potential additional value added services that can result form the implementation.
Report on Dissemination Activities, Public Participation and Awareness, year 3Every year two conference papers will be intended to publish in relevant international conferences specially focus on IEEE conferences Some of the conferences will be submitted to be published in prestigious journal from IEEE transactions and magazines The preprints of the papers will be also uploaded in the website of the project with free access The results of the projects will be presented in Keynotes Seminars and PhD courses of the University
Data Management Plan, first versionThe deliverable will issue the first version of the procedures and delivery of a comprehensive data management plan for the tasks addressed during the whole lifecycle of VICINITY. The plan will detail what data the project will generate in the demonstrators and take into account the exploitation potential and how it will be curated and preserved. Data management plan is related to defined ontologies in D1.4. Activities related to verification and re-use of the results will also be described and matched with VICINITY target stakeholders and consortium.
Report on Dissemination Activities, Public Participation and Awareness, year 4Every year two conference papers will be intended to publish in relevant international conferences (specially focus on IEEE conferences). Some of the conferences will be submitted to be published in prestigious journal from IEEE (transactions and magazines). The preprints of the papers will be also uploaded in the website of the project with free access. The results of the projects will be presented in Keynotes, Seminars and PhD courses of the University.
Report on pilot sites and operational requirementsThis report is the outcome of consolidation of four survey reports conducted by ENERC in cooperation with each pilot responsible (TINYM, HITS, MPC). The pilots’ surveying general report will feature a standard template for all the sites in order to document stakeholder interviews, operational requirements of each site, the analysis of contingencies and expected results, and to list specifications of the installed systems and equipment, as well as provide a technical description of functionalities with corresponding devices and/or microgrid equipment to be adopted to IoT. The report might incorporate additional operation requirements after discussion within the consortium; in case information gaps or additional needs are identified gap analysis document would be prepared. A comparative requirements’ matrix for future replicable package creation of optimized sites surveys for operational requirements will be created. Create knowledge management exchange between the pilot’s sites, including stakeholder’s engagement processes. Create a comparative requirements matrix for future replicable package creation of optimized sites surveys for operational requirements.
Evaluation of the semantic model in real world scenariosThis deliverable will describe the validation of the VICINITY ontology. It will include an overview of the process followed to validate the ontology, the description of the specifications and scenarios against which the ontology will be validated, and the results of such validation.
Report on Dissemination Activities, Public Participation and Awareness, year 2Every year two conference papers will be intended to publish in relevant international conferences (specially focus on IEEE conferences). Some of the conferences will be submitted to be published in prestigious journal from IEEE (transactions and magazines). The preprints of the papers will be also uploaded in the website of the project with free access. The results of the projects will be presented in Keynotes, Seminars and PhD courses of the University.
Pilot results of Buildings for Assisted Living Neighbourhood use-caseThe deliveris will contain the pilot result of the Building in a Neighbourhood use case through an interface for IoT platform that incorporates static building data with dynamic user-driven data requesting movement assistance, indoor climat monitoring. Challenge is to evaluate how semantics from technical building environment, abnormalities can be correctly understood by energy and parking &EV charging domain. And impotant criteria for the pilot will be how services in on domain can read semantically correct information from services ore sensordevices in other domains. This cross interoperability will be donw with information from facility management system, parking and mobility and energy. It will be conducted surveys formulas midway in the trial of use case. The results of these will form the basis for an iteration with improvements. At the end of the project there will be a similar survey and result of that will be incorporated into the project's final report. Evaluation criteria will be defined with T2.3 on standardization and conformity assessment.
Report on VICINITY business requirementsThe deliverable will provide the definition of high level user requirements for IoT interoperability, ubiquitous applications, services and other smart objects based on tasks 1.1 and 1.2. Partners will contribute with requirements related to domains of their expertise. The outcome will be consolidated in order to translate the existing business establishment from use-cases as well as the user requirements of task 1.1 into the feature required in the VICINITY platform. The deliverable will also include proposals for new ontologies comprising new fields i.e. medical home sensors, human interaction, neighbourhood power usage, storage and generation, traffic and parking.
VICINITY technical requirements specificationVICINITY technical requirements specification document consists of functional and non-functional requirements describing detailed behaviour of VICINITY. VICINITY requirements will be based on business requirements, business drivers and barriers, IoT interoperability and value added services requirements, pilot sites and operational requirements.
Pilot area installation methodology & planningThis deliverables will be a description of a common installation methodology for all demo sites and a specific detailed plan for every demo sites Every pilot site address some particular aspects and focus Based on this methodology it will be develop a specific plan for all demo sites The sites in Norway will put focus on Assistive Living Building Monitoring Energy Flexibility Smart Neighbourhood and Intelligent TransportationParking In Portugal focus will be on Smart Buildings and Smart Energy and eHealth in Greece The plan will identify Adapters for real infrastructures provided by the appropriate partners eg ENERC for renewable infrastructures GNOMON CERTH and TINYM for health and buildings HITS for transport OTE will develop adapters toward mobile services and ATOS will manage the development of adapters toward third party IoT assets integrated as result of Open call
Dissemination and Communication Plan, year 4D95D97 Dissemination and Communication Plan year 4 will be based on creating and following strategies for internal and external communication Internal communication will of course be a central part in order to keep the project on track and allow cooperation between participants to flow as effortlessly as possible Information about the project background and ongoing activities will have to be conveyed through pressreleases conferences and workshops Presentations at relevant forums will also be central to the communication plan Update the CRM system and coworking webspaces project transparency for common utilisation and sectioned for each project participant In order to streamline the information flow a profile handbook will be developed briefs will be created brochures and a project video will be created This will all be included in a presskitThe project website D91 will function both as a hub for communication within the workgroups and the general public It shall also represent a necessary point of information for the consortium other partners as well as stakeholders Social media will be an another important media outlet and a channel will be created for the different partners of VICINITY to inform about progress products and resultsD95D97 will collect all this activities into a report for the corresponding years of project activity
Report on eHealth at Home InstallationsReport on the deployment and installation of required equipment and overall VICINITY framework for the realisation of the eHealth at Home pilot use at selected end-users in the Greek selected pilot areas.
Auto-Discovery space deployment validation reportThe deliverable will provide a written report on the validation of deployed VICINITY AutoDiscovery platform The validation will be based on a defined set of quality and performance measures The adopted testing environment build as a single installation of deployed platform for all pilot cases will be described with respect to the suitability to verify and evaluate platform capabilities such as the integration of Agent with existing services and the dynamic addition of new device types into a mockup version of a device repository The prototype tests will be described in detail the achieved results will be analyzed and summarized into output recommendations for further refinements and requirements on the VICINITY platform functionality and architecture
Report on Buildings for Assisted Living Neighbourhood InstallationsThe deliverable will contain a report on Buildings in Neighbourhood Installations. Pilot site installation will be implemented in close cooperation with Oslo Science Park. The report will describe technical part of the site installation and the practical use case that has been implemented in to the Pilot. Aspects that will be described in the Pilot report is about the experience of support for building monitoring and controll, EV charging and energy in a smart neigthbourhood. Architecture plan based on individual needs and privacy. Building instrumentation with extensive use of sensors, IEQ, energy consumption, exsisting instrumentationsystems. This will be carefully coordinated together with the tenant in neighbourhood community in Oslo Science Park.This will be fully compliant to legislation on privacy and handling of sensitive information.
VICINITY architectural designVICINITY architectural design document includes description of VICINITY components and concepts from static and behaviour point of view. Architecture design will encompasses specifications of VICINITY usability, reliability, security, efficiency, maintenance, components functions and interactions, implementation, deployment.
Report on Standard Involvement over life of project and conformance assessmentDeliverable 2.4 will collect practical and quantitative feedback obtained during VICINITY project to create recommendations, amendments and/or extensions to the related standardisation, selected in D2.1.
Report on Dissemination Activities, Public Participation and Awareness, year 1Every year two conference papers will be intended to publish in relevant international conferences (specially focus on IEEE conferences). Some of the conferences will be submitted to be published in prestigious journal from IEEE (transactions and magazines). The preprints of the papers will be also uploaded in the website of the project with free access. The results of the projects will be presented in Keynotes, Seminars and PhD courses of the University.
Dissemination and Communication Plan, year 3D9.5-D9.7 Dissemination and Communication Plan year 3 will be based on creating and following strategies for internal and external communication. Internal communication will of course be a central part in order to keep the project on track and allow cooperation between participants to flow as effortlessly as possible. Information about the project, background and on-going activities will have to be conveyed through press-releases, conferences and workshops. Update the CRM system and co-working web-spaces, project transparency for common utilisation, and sectioned for each project participant. Presentations at relevant forums will also be central to the communication plan. In order to streamline the information flow, a profile handbook will be developed, briefs will be created, brochures and a project video will be created. This will all be included in a presskit. The project website (D9.1) will function both as a hub for communication within the workgroups and the general public. It shall also represent a necessary point of information for the consortium, other partners as well as stakeholders. Social media will be an another important media outlet, and a channel will be created for the different partners of VICINITY to inform about progress, products and results. D9.5-D9.7 will collect all this activities into a report, for the corresponding years of project activity.
Report on Intelligent Transport & Parking InstallationsThe deliverable will contain a report on Intelligent Transport & Parking Installation as implemented in cooperation with Norwegian Helsehus and the neighborhood district. The report will address experiences gained from applying Security and biometric protocols to handle security and access control policies, as well as describe how Assistive Living will be supported for health personnel and visitors.Lastly it will contain information on how DATEX-II communication have been tested for IoT technology using standardized traffic protocols for Traffic and travel information.
VICINITY value-added services definition, requirements and architectural designDetailed definition of value-added services, including requirements and architectural design specification, to be implemented and demonstrated per each pilot Use Case.
Final ReportFinal project report.
Dissemination and Communication Plan, year 2D9.5-D9.7 Dissemination and Communication Plan year 2 will be based on creating and following strategies for internal and external communication. Internal communication will of course be a central part in order to keep the project on track and allow cooperation between participants to flow as effortlessly as possible. Information about the project, background and on-going activities will have to be conveyed through press-releases, conferences and workshops. Establishment of a CRM system and co-working web-spaces, project transparency for common utilisation, and sectioned for each project participant. Presentations at relevant forums will also be central to the communication plan. In order to streamline the information flow, a profile handbook will be developed, briefs will be created, brochures and a project video will be created. This will all be included in a presskit. The project website (D9.1) will function both as a hub for communication within the workgroups and the general public. It shall also represent a necessary point of information for the consortium, other partners as well as stakeholders. Social media will be an another important media outlet, and a channel will be created for the different partners of VICINITY to inform about progress, products and results. D9.5-D9.7 will collect all this activities into a report, for the corresponding years of project activity.
Risk Assessment, Ethical monitoring and Contingency PlansRisks to the project may include issues such as vendor lock-in on protocols which might prevent full interoperability of interconnected smart objects, and difficulties in getting standards contributions accepted in some standards bodies. The project must also take account of security and privacy issues (such as cyber attacks) and develop techniques for protection against these. D10.2 will provide an assessment of the risks to the success of the VICINITY project based initially on the risks identified in Section 3.2.3 of the proposal. A risk register will be set up and these and other risks categorised according to severity and impact on the project. Possible mitigating actions will also be identified so that the project plan can be adapted to include any necessary actions. Based on this, a Risk Management and Contingency Plan will be drafted and agreed that will be taken into account by each WP. The ToRs of an Ethics Advisory Board also will be specified and agreed which will address any legal and ethical issues for the technologies developed by the consortium. This will also address privacy issues related to data collection and handling, providing guidance to the development and realisation of the trials and to end-user participants. Finally the principles of Quality Assurance must be established within the project to ensure that deliverables are fit for purpose and meet required standards such as ISO 9000. A project Quality Plan will be established and its principles agreed.
Pilot results of eHealth at Home use-caseReport on the overall assessment and evaluation of the achieved results during the realisation of the eHealth at Home Use Case at selected pilot areas in Greece, comprising of both User Experience and the improvements brought by the overall VICINITY framework in terms of integration, interoperability, compliance with requirements etc.
Evaluation of user experience and performance of VICINITY Framework & value-added servicesThe deliverable will provide a report on the results of the evaluation of the user experience and assess how well the VICINITY Framework performed against the expectations set up in D8.1. It will describe the way the pilot system was evaluated, the evaluation criteria and the performance of each use case and application. This will include autonomously gathered data, results of questionnaires and evaluations of the economic and environmental performances. A rating system will be included to show the relative maturity of the use case and the applications within it. The usefulness of the dashboard will also be assessed and reported including how performance indices may be updated over time so that year-on-year improvements can be measured and tracked.
Detailed Specification of the Semantic ModelThis deliverable will describe the VICINITY ontology. It will include an overview of the ontology development process followed to develop the ontology, will present the relevant parts of the existing ontologies and standards reused during the development, and will describe in detail the different modules of the VICINITY ontology. Apart from being described in the deliverable, the ontology will be implemented using the OWL language and will be published online following existing recommendations and best practices.
Pilot results of Intelligent Transport & Parking use-caseThe deliverable will contain the pilot results of the use-case for Intelligent Transport & Parking based on an open IoT platform that incorporates sensor data with intelligent agents and smart buildings. A report will describe the results from the validation performed by partners and test installation, as well as lab tests and real life test data. The report will also lay out lessons learned from sharing data from traffic management and end-to-end communication with road side equipment and other IoT objects. The deliverable should offer a way to develop an understanding of how to improve time gain and reduce strain on infrastructure and emission through use of logistics and predictive analysis.
Report on Smart Energy MicroGrid Neighbourhood InstallationsThe report will be composed of a set of documents containing visuals and schematics on the VICINITY solution installations within the MicroGrid Neighborhood pilot and standardized microgrid community. These contents will be created and maintained by ENERC during systems installation. Knowledge management process would facilitate synchronization of the report format and areas to be analyzed with the other pilot installation responsible partners, in order to obtain cross-knowledge leverage and consistency in results reporting as well as in the methodology under which the analysis is performed. Thus, the report will include an assessment report and analysis of the obtained results vs. expected results of pilot installations. Create and maintain during systems and the related business process installations a set of documents containing visuals and schematics on the VICINITY solution installations within Micro Neighborhood pilots.
Data Management Plan, second versionThe deliverable will issue the second version of the procedures and delivery of a comprehensive data management plan for the tasks addressed during the whole lifecycle of VICINITY. The plan will detail what data the project will generate in the demonstrators and take into account the exploitation potential and how it will be curated and preserved. Data management plan is related to defined ontologies in D1.4. Activities related to verification and re-use of the results will also be described and matched with VICINITY target stakeholders and consortium.
The deliverable will issue the final version of the procedures and delivery of a comprehensive data management plan for the tasks addressed during the whole lifecycle of VICINITY. The plan will detail what data the project will generate in the demonstrators and take into account the exploitation potential and how it will be curated and preserved. Data management plan is related to defined ontologies in D1.4. Activities related to verification and re-use of the results will also be described and matched with VICINITY target stakeholders and consortium.
The consortium will organise the final review meeting for the projects of the call in M37. The partners will share the costs as described in the Consortium Agreement.
Description of the project website available online.
Publicaciones
Autores:
Carlos Gamarra, Josep M. Guerrero, Eduardo Montero
Publicado en:
Renewable and Sustainable Energy Reviews, Edición 60, 2016, Página(s) 615-630, ISSN 1364-0321
Editor:
Elsevier BV
DOI:
10.1016/j.rser.2016.01.091
Autores:
Amjad Anvari-Moghaddam, Josep M. Guerrero, Juan C. Vasquez, Hassan Monsef, Ashkan Rahimi-Kian
Publicado en:
IET Generation, Transmission & Distribution, Edición 11/11, 2017, Página(s) 2752-2761, ISSN 1751-8687
Editor:
Institution of Engineering and Technology
DOI:
10.1049/iet-gtd.2016.1129
Autores:
Johannes Kölsch, Christopher Heinz, Axel Ratzke, Christoph Grimm
Publicado en:
Future Internet, Edición 11/10, 2019, Página(s) 218, ISSN 1999-5903
Editor:
MDPI
DOI:
10.3390/fi11100218
Autores:
Andrea Cimmino, María Poveda-Villalón, Raúl García-Castro
Publicado en:
Sensors, Edición 20/3, 2020, Página(s) 822, ISSN 1424-8220
Editor:
Multidisciplinary Digital Publishing Institute (MDPI)
DOI:
10.3390/s20030822
Autores:
Enrique Rodriguez-Diaz, Juan C. Vasquez, Josep M. Guerrero
Publicado en:
IEEE Consumer Electronics Magazine, Edición 5/1, 2016, Página(s) 74-80, ISSN 2162-2256
Editor:
Institute of Electrical and Electronics Engineers Inc.
DOI:
10.1109/MCE.2015.2484699
Autores:
Fernando Serena, María Poveda-Villalón, Raúl García-Castro
Publicado en:
Current Trends in Web Engineering. ICWE 2017. LNCS 10544, 2017, Página(s) 19-31
Editor:
Springer International Publishing
DOI:
10.1007/978-3-319-74433-9_2
Autores:
Alba Fernández-Izquierdo, Raúl García-Castro
Publicado en:
Proceedings of the 21st International Conference on Knowledge Engineering and Knowledge Management (EKAW 2018), LNAI 11313, 2018, Página(s) 114-130, ISBN 978-3-030-03667-6
Editor:
Springer International Publishing
DOI:
10.1007/978-3-030-03667-6_8
Autores:
Raúl García-Castro
Publicado en:
Actes IC 2017 28es Journées francophones d’Ingénierie des Connaissances, 2017, Página(s) 1
Editor:
IC 2017
Autores:
Johannes Kolsch, Christopher Heinz, Sebastian Schumb, Christoph Grimm
Publicado en:
2018 Workshop on Modeling and Simulation of Cyber-Physical Energy Systems (MSCPES), 2018, Página(s) 1-6, ISBN 978-1-5386-4105-7
Editor:
IEEE
DOI:
10.1109/mscpes.2018.8405399
Autores:
Yajuan Guan, Wei Feng, Jinghang Lu, Josep M. Guerrero, Juan C. Vasquez
Publicado en:
2018 IEEE Energy Conversion Congress and Exposition (ECCE), 2018, Página(s) 5899-5904, ISBN 978-1-4799-7312-5
Editor:
IEEE
DOI:
10.1109/ecce.2018.8557795
Autores:
Emilio J. Palacios-Garcia, Enrique Rodriguez-Diaz, Amjad Anvari-Moghaddam, Mehdi Savaghebi, Juan C. Vasquez, Josep M. Guerrero, Antonio Moreno-Munoz
Publicado en:
2017 IEEE 26th International Symposium on Industrial Electronics (ISIE), 2017, Página(s) 1725-1731, ISBN 978-1-5090-1412-5
Editor:
IEEE
DOI:
10.1109/isie.2017.8001508
Autores:
Enrique Rodriguez-Diaz, Emilio J. Palacios-Garcia, Amjad Anvari-Moghaddam, Juan C. Vasquez, Josep M. Guerrero
Publicado en:
2017 IEEE Second International Conference on DC Microgrids (ICDCM), 2017, Página(s) 256-261, ISBN 978-1-5090-4479-5
Editor:
IEEE
DOI:
10.1109/icdcm.2017.8001053
Autores:
Alexander Berler, Anastassios Tagarisb and Catherine Chronaki
Publicado en:
2016
Editor:
-
Autores:
Johannes Kolsch, Axel Ratzke, Christoph Grimm
Publicado en:
2019 7th Workshop on Modeling and Simulation of Cyber-Physical Energy Systems (MSCPES), 2019, Página(s) 1-6, ISBN 978-1-7281-0637-3
Editor:
IEEE
DOI:
10.1109/mscpes.2019.8738795
Autores:
Maria Belesioti, Evangelos Sfakianakis, Viktor Oravec, Athanasios Tryferidis, Kostis Kaggelides, Ioannis P. Chochliouros, Maria Koutli, Dimitrios Tzovaras
Publicado en:
2019 15th International Conference on Distributed Computing in Sensor Systems (DCOSS), 2019, Página(s) 219-223, ISBN 978-1-7281-0570-3
Editor:
IEEE
DOI:
10.1109/dcoss.2019.00057
Autores:
Maria Koutli, Natalia Theologou, Athanasios Tryferidis, Dimitrios Tzovaras, Aimilia Kagkini, Dimitrios Zandes, Konstantinos Karkaletsis, Konstantinos Kaggelides, Jorge Almela Miralles, Viktor Oravec, Stefan Vanya
Publicado en:
2019 15th International Conference on Distributed Computing in Sensor Systems (DCOSS), 2019, Página(s) 263-270, ISBN 978-1-7281-0570-3
Editor:
IEEE
DOI:
10.1109/dcoss.2019.00064
Autores:
Johannes Kolsch, Axel Ratzke, Christoph Grimm, Christopher Heinz, Gomathi Nandagopal
Publicado en:
2019 15th International Conference on Distributed Computing in Sensor Systems (DCOSS), 2019, Página(s) 255-262, ISBN 978-1-7281-0570-3
Editor:
IEEE
DOI:
10.1109/dcoss.2019.00063
Autores:
Alba Fernández-Izquierdo, Raúl García-Castro
Publicado en:
Proceedings of the 31st International Conference on Software Engineering and Knowledge Engineering, 2019, Página(s) 573-578, ISBN 1-891706-48-9
Editor:
KSI Research Inc. and Knowledge Systems Institute Graduate School
DOI:
10.18293/seke2019-117
Autores:
Andrea Cimmino, Maria Poveda-Villalon, and Raul Garcia-Castro
Publicado en:
2019
Editor:
X
Autores:
Andrea Cimmino, Viktor Oravec, Fernando Serena, Peter Kostelnik, Maria Poveda-Villalon, Athanasios Tryferidis, Raul Garcia-Castro, Stefan Vanya, Dimitrios Tzovaras, Christoph Grimm
Publicado en:
2019 15th International Conference on Distributed Computing in Sensor Systems (DCOSS), 2019, Página(s) 241-247, ISBN 978-1-7281-0570-3
Editor:
IEEE
DOI:
10.1109/dcoss.2019.00061
Autores:
Yajuan Guan, Wei Feng, Emilio J. Palacios-Garcia, Juan C. Vasquez, Josep M. Guerrero
Publicado en:
2019 15th International Conference on Distributed Computing in Sensor Systems (DCOSS), 2019, Página(s) 248-254, ISBN 978-1-7281-0570-3
Editor:
IEEE
DOI:
10.1109/dcoss.2019.00062
Autores:
Maria Koutli, Natalia Theologou, Athanasios Tryferidis, Dimitrios Tzovaras
Publicado en:
2019 IEEE 19th International Conference on Bioinformatics and Bioengineering (BIBE), 2019, Página(s) 922-926
Editor:
IEEE
DOI:
10.1109/bibe.2019.00173
Autores:
Amir Ghasemkhani, Amjad Anvari-Moghaddam, Josep M. Guerrero, Birgitte Bak-Jensen
Publicado en:
2016 IEEE PES Innovative Smart Grid Technologies Conference Europe (ISGT-Europe), 2016, Página(s) 1-6, ISBN 978-1-5090-3358-4
Editor:
IEEE
DOI:
10.1109/ISGTEurope.2016.7856286
Autores:
Yajuan Guan, Juan C. Vasquez, Josep M. Guerrero,
Publicado en:
IEEE International Symposium on Industrial Electronics (ISIE 2017), 2017
Editor:
IEEE
Autores:
Enrique Rodriguez-Diaz, Emilio J. Palacios-Garcia, Mehdi Savaghebi, Juan C Vasquez, Josep M. Guerrero
Publicado en:
2016 IEEE International Conference on Consumer Electronics (ICCE), 2016, Página(s) 544-545, ISBN 978-1-4673-8364-6
Editor:
IEEE
DOI:
10.1109/ICCE.2016.7430724
Autores:
Carna Radojicic, Aida Mynzhasova, Christopher Heinz, Christoph Grimm, Juan Rico, Keith Dickerson
Publicado en:
IEEE Technically Sponsored Intelligent Systems Conference (IntelliSys), 2017, ISBN 978-1-5090-6435-9
Editor:
IEEE
Autores:
Amjad Anvari-Moghaddam, Josep M. Guerrero, Ashkan Rahimi-Kian, Maryam S. Mirian
Publicado en:
2016 IEEE 7th International Symposium on Power Electronics for Distributed Generation Systems (PEDG), 2016, Página(s) 1-7, ISBN 978-1-4673-8617-3
Editor:
IEEE
DOI:
10.1109/PEDG.2016.7526997
Autores:
Yajuan Guan, Juan C. Vasquez, Josep M. Guerrero, Natalie Samovich, Stefan Vanya, Viktor Oravec, Raúl García-Castro, Fernando Serena, María Poveda-Villalón, Carna Radojicic, Christopher Heinz, Christoph Grimm, Athanasios Tryferidis, Dimitrios Tzovaras, Keith Dickerson, Marek Paralic, Marek Skokan, Tomas Sabol
Publicado en:
Global IoT Summit (GIoTS-2017), 2017, Página(s) 134-139, ISBN 978-1-5090-5873-0
Editor:
IEEE
Autores:
Ovidiu Vermesan
Publicado en:
Advancing IoT Platforms Interoperability, 2018, Página(s) 1-92, ISBN 978-87-7022-006-4
Editor:
River Publisher
DOI:
10.13052/rp-9788770220057
Autores:
Maria Belesioti, Ioannis P. Chochliouros, Stefan Vanya, Viktor Oravec, Natalia Theologou, Maria Koutli, Athanasios Tryferidis, Dimitrios Tzovaras
Publicado en:
Artificial Intelligence Applications and Innovations, Edición 520, 2018, Página(s) 62-69, ISBN 978-3-319-92015-3
Editor:
Springer International Publishing
DOI:
10.1007/978-3-319-92016-0_6
Autores:
Alba Fernández-Izquierdo, Raúl García-Castro
Publicado en:
The Semantic Web: ESWC 2019 Satellite Events - ESWC 2019 Satellite Events, Portorož, Slovenia, June 2–6, 2019, Revised Selected Papers, Edición 11762, 2019, Página(s) 52-57, ISBN 978-3-030-32326-4
Editor:
Springer International Publishing
DOI:
10.1007/978-3-030-32327-1_11
Autores:
Alba Fernández-Izquierdo, María Poveda-Villalón, Raúl García-Castro
Publicado en:
The Semantic Web - 16th International Conference, ESWC 2019, Portorož, Slovenia, June 2–6, 2019, Proceedings, Edición 11503, 2019, Página(s) 443-458, ISBN 978-3-030-21347-3
Editor:
Springer International Publishing
DOI:
10.1007/978-3-030-21348-0_29
Autores:
Editor: Martin Bauer, NEC Laboratories Europe
Publicado en:
2019
Editor:
/
Autores:
Editor: Martin Bauer, NEC Laboratories Europe
Publicado en:
2019
Editor:
/
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