968 research outputs found
Internet of Things Applications - From Research and Innovation to Market Deployment
The book aims to provide a broad overview of various topics of Internet of Things from the research, innovation and development priorities to enabling technologies, nanoelectronics, cyber physical systems, architecture, interoperability and industrial applications. It is intended to be a standalone book in a series that covers the Internet of Things activities of the IERC – Internet of Things European Research Cluster from technology to international cooperation and the global "state of play".The book builds on the ideas put forward by the European research Cluster on the Internet of Things Strategic Research Agenda and presents global views and state of the art results on the challenges facing the research, development and deployment of IoT at the global level. Internet of Things is creating a revolutionary new paradigm, with opportunities in every industry from Health Care, Pharmaceuticals, Food and Beverage, Agriculture, Computer, Electronics Telecommunications, Automotive, Aeronautics, Transportation Energy and Retail to apply the massive potential of the IoT to achieving real-world solutions. The beneficiaries will include as well semiconductor companies, device and product companies, infrastructure software companies, application software companies, consulting companies, telecommunication and cloud service providers. IoT will create new revenues annually for these stakeholders, and potentially create substantial market share shakeups due to increased technology competition. The IoT will fuel technology innovation by creating the means for machines to communicate many different types of information with one another while contributing in the increased value of information created by the number of interconnections among things and the transformation of the processed information into knowledge shared into the Internet of Everything. The success of IoT depends strongly on enabling technology development, market acceptance and standardization, which provides interoperability, compatibility, reliability, and effective operations on a global scale. The connected devices are part of ecosystems connecting people, processes, data, and things which are communicating in the cloud using the increased storage and computing power and pushing for standardization of communication and metadata. In this context security, privacy, safety, trust have to be address by the product manufacturers through the life cycle of their products from design to the support processes. The IoT developments address the whole IoT spectrum - from devices at the edge to cloud and datacentres on the backend and everything in between, through ecosystems are created by industry, research and application stakeholders that enable real-world use cases to accelerate the Internet of Things and establish open interoperability standards and common architectures for IoT solutions. Enabling technologies such as nanoelectronics, sensors/actuators, cyber-physical systems, intelligent device management, smart gateways, telematics, smart network infrastructure, cloud computing and software technologies will create new products, new services, new interfaces by creating smart environments and smart spaces with applications ranging from Smart Cities, smart transport, buildings, energy, grid, to smart health and life. Technical topics discussed in the book include: • Introduction• Internet of Things Strategic Research and Innovation Agenda• Internet of Things in the industrial context: Time for deployment.• Integration of heterogeneous smart objects, applications and services• Evolution from device to semantic and business interoperability• Software define and virtualization of network resources• Innovation through interoperability and standardisation when everything is connected anytime at anyplace• Dynamic context-aware scalable and trust-based IoT Security, Privacy framework• Federated Cloud service management and the Internet of Things• Internet of Things Application
EAGLE—A Scalable Query Processing Engine for Linked Sensor Data
Recently, many approaches have been proposed to manage sensor data using semantic web technologies for effective heterogeneous data integration. However, our empirical observations revealed that these solutions primarily focused on semantic relationships and unfortunately paid less attention to spatio–temporal correlations. Most semantic approaches do not have spatio–temporal support. Some of them have attempted to provide full spatio–temporal support, but have poor performance for complex spatio–temporal aggregate queries. In addition, while the volume of sensor data is rapidly growing, the challenge of querying and managing the massive volumes of data generated by sensing devices still remains unsolved. In this article, we introduce EAGLE, a spatio–temporal query engine for querying sensor data based on the linked data model. The ultimate goal of EAGLE is to provide an elastic and scalable system which allows fast searching and analysis with respect to the relationships of space, time and semantics in sensor data. We also extend SPARQL with a set of new query operators in order to support spatio–temporal computing in the linked sensor data context.EC/H2020/732679/EU/ACTivating InnoVative IoT smart living environments for AGEing well/ACTIVAGEEC/H2020/661180/EU/A Scalable and Elastic Platform for Near-Realtime Analytics for The Graph of Everything/SMARTE
Federated Sensor Network architectural design for the Internet of Things (IoT)
An information technology that can combine the physical world and virtual world is desired. The Internet of Things (IoT) is a concept system that uses Radio Frequency Identification (RFID), WSN and barcode scanners to sense and to detect physical objects and events. This information is shared with people on the Internet. With the announcement of the Smarter Planet concept by IBM, the problem of how to share this data was raised. However, the original design of WSN aims to provide environment monitoring and control within a small scale local network. It cannot meet the demands of the IoT because there is a lack of multi-connection functionality with other WSNs and upper level applications. As various standards of WSNs provide information for different purposes, a hybrid system that gives a complete answer by combining all of them could be promising for future IoT applications.
This thesis is on the subject of `Federated Sensor Network' design and architectural development for the Internet of Things. A Federated Sensor Network (FSN) is a system that integrates WSNs and the Internet. Currently, methods of integrating WSNs and the Internet can follow one of three main directions: a Front-End Proxy solution, a Gateway solution or a TCP/IP Overlay solution. Architectures based on the ideas from all three directions are presented in this thesis; this forms a comprehensive body of research on possible Federated Sensor Network architecture designs. In addition, a fully compatible technology for the sensor network application, namely the Sensor Model Language (SensorML), has been reviewed and embedded into our FSN systems. The IoT as a new concept is also comprehensively described and the major technical issues discussed. Finally, a case study of the IoT in logistic management for emergency response is given. Proposed FSN architectures based on the Gateway solution are demonstrated through hardware implementation and lab tests. A demonstration of the 6LoWPAN enabled federated sensor network based on the TCP/IP Overlay solution presents a good result for the iNET localization and tracking project. All the tests of the designs have verified feasibility and achieve the target of the IoT concept
A domain-independent methodology to analyze IoT data streams in real-time. A proof of concept implementation for anomaly detection from environmental data
Pushed by the Internet of Things (IoT) paradigm modern sensor networks monitor a wide range of phenomena, in areas such as environmental monitoring, health care, industrial processes, and smart cities. These networks provide a continuous pulse of the almost infinite activities that are happening in the physical space and are thus, key enablers for a Digital Earth Nervous System. Nevertheless, the rapid processing of these sensor data streams still continues to challenge traditional data-handling solutions and new approaches are being requested. We propose a generic answer to this challenge, which has the potential to support any form of distributed real-time analysis. This neutral methodology follows a brokering approach to work with different kinds of data sources and uses web-based standards to achieve interoperability. As a proof of concept, we implemented the methodology to detect anomalies in real-time and applied it to the area of environmental monitoring. The developed system is capable of detecting anomalies, generating notifications, and displaying the recent situation to the user
SMART-ITEM: IoT-Enabled Smart Living
The main goal of this proposed project is to harness the emerging IoT technology to empower elderly population to self-manage their own health, stay active, healthy, and independent as long as possible within a smart and secured living environment. An integrated open-sourced IoT ecosystem will be developed. It will encompass the entire data lifecycle which involves the following processes: data acquisition, data transportation; data integration, processing, manipulation and computation; visualisation; data intelligence and exploitation; data sharing; data storage. This innovative cloud-based IoT ecosystem will provide a one-stop shop for integrated smart IoT-enabled services to support older people (greater or equal to 65 years old) who live alone at home (or care homes). Another innovation of this system is the design and implementation of an integrated IoT gateway for wellbeing wearable and home automation system sensors with varying communication protocols. The SMART-ITEM system and services will appropriately address the following (i) smart health and care; (ii) smart quality of life; (iii) SMART-ITEM social community. The development of the system will be based on the User Centred Design methodology so as to ensure active user engagement throughout the entire project lifecycle and necessary standards as well as compliances will be adhered to (e.g. security, trust and privacy) in order to enhance user acceptance
A Semantic Interoperability Model Based on the IEEE 1451 Family of Standards Applied to the Industry 4.0
The Internet of Things (IoT) has been growing recently. It is a concept for connecting
billions of smart devices through the Internet in different scenarios. One area being
developed inside the IoT in industrial automation, which covers Machine-to-Machine (M2M) and industrial communications with an automatic process, emerging the
Industrial Internet of Things (IIoT) concept. Inside the IIoT is developing the concept of
Industry 4.0 (I4.0). That represents the fourth industrial revolution and addresses the
use of Internet technologies to improve the production efficiency of intelligent services
in smart factories. I4.0 is composed of a combination of objects from the physical world and the digital world that offers dedicated functionality and flexibility inside and outside of an I4.0 network.
The I4.0 is composed mainly of Cyber-Physical Systems (CPS). The CPS is the integration
of the physical world and its digital world, i.e., the Digital Twin (DT). It is responsible for realising the intelligent cross-link application, which operates in a self-organised and
decentralised manner, used by smart factories for value creation. An area where the CPS
can be implemented in manufacturing production is developing the Cyber-Physical Production System (CPPS) concept. CPPS is the implementation of Industry 4.0 and CPS in manufacturing and production, crossing all levels of production between the
autonomous and cooperative elements and sub-systems. It is responsible for connecting
the virtual space with the physical world, allowing the smart factories to be more intelligent, resulting in better and smart production conditions, increasing productivity,
production efficiency, and product quality. The big issue is connecting smart devices with
different standards and protocols. About 40% of the benefits of the IoT cannot be
achieved without interoperability. This thesis is focused on promoting the
interoperability of smart devices (sensors and actuators) inside the IIoT under the I4.0 context.
The IEEE 1451 is a family of standards developed to manage transducers. This standard reaches the syntactic level of interoperability inside Industry 4.0. However, Industry 4.0
requires a semantic level of communication not to exchange data ambiguously. A new
semantic layer is proposed in this thesis allowing the IEEE 1451 standard to be a complete framework for communication inside the Industry 4.0 to provide an interoperable network interface with users and applications to collect and share the data from the industry field.A Internet das Coisas tem vindo a crescer recentemente. É um conceito que permite
conectar bilhões de dispositivos inteligentes através da Internet em diferentes cenários.
Uma área que está sendo desenvolvida dentro da Internet das Coisas é a automação
industrial, que abrange a comunicação máquina com máquina no processo industrial de
forma automática. Essa interligação, representa o conceito da Internet das Coisas
Industrial. Dentro da Internet das Coisas Industrial está a desenvolver o conceito de
Indústria 4.0 (I4.0). Isso representa a quarta revolução industrial que aborda o uso de
tecnologias utilizadas na Internet para melhorar a eficiência da produção de serviços em
fábricas inteligentes. A Indústria 4.0 é composta por uma combinação de objetos do
mundo fÃsico e do mundo da digital que oferece funcionalidade dedicada e flexibilidade
dentro e fora de uma rede da Indústria 4.0.
O I4.0 é composto principalmente por Sistemas CiberfÃsicos. Os Sistemas CiberfÃsicos
permitem a integração do mundo fÃsico com seu representante no mundo digital, por
meio do Gémeo Digital. Sistemas CiberfÃsicos são responsáveis por realizar a aplicação
inteligente da ligação cruzada, que opera de forma auto-organizada e descentralizada,
utilizada por fábricas inteligentes para criação de valor. Uma área em que o Sistema
CiberfÃsicos pode ser implementado na produção manufatureira, isso representa o
desenvolvimento do conceito Sistemas de Produção CiberfÃsicos. Esse sistema é a
implementação da Indústria 4.0 e Sistema CiberfÃsicos na fabricação e produção. A
cruzar todos os nÃveis desde a produção entre os elementos e subsistemas autónomos e
cooperativos. Ele é responsável por conectar o espaço virtual com o mundo fÃsico,
permitindo que as fábricas inteligentes sejam mais inteligentes, resultando em condições
de produção melhores e inteligentes, aumentando a produtividade, a eficiência da
produção e a qualidade do produto. A grande questão é como conectar dispositivos
inteligentes com diferentes normas e protocolos. Cerca de 40% dos benefÃcios da Internet
das Coisas não podem ser alcançados sem interoperabilidade. Esta tese está focada em
promover a interoperabilidade de dispositivos inteligentes (sensores e atuadores) dentro
da Internet das Coisas Industrial no contexto da Indústria 4.0.
O IEEE 1451 é uma famÃlia de normas desenvolvidos para gerenciar transdutores. Esta
norma alcança o nÃvel sintático de interoperabilidade dentro de uma indústria 4.0. No
entanto, a Indústria 4.0 requer um nÃvel semântico de comunicação para não haver a
trocar dados de forma ambÃgua. Uma nova camada semântica é proposta nesta tese
permitindo que a famÃlia de normas IEEE 1451 seja um framework completo para
comunicação dentro da Indústria 4.0. Permitindo fornecer uma interface de rede
interoperável com utilizadores e aplicações para recolher e compartilhar os dados dentro
de um ambiente industrial.This thesis was developed at the Measurement and Instrumentation Laboratory (IML)
in the University of Beira Interior and supported by the portuguese project INDTECH
4.0 – Novas tecnologias para fabricação, que tem como objetivo geral a conceção e
desenvolvimento de tecnologias inovadoras no contexto da Indústria 4.0/Factories of the Future (FoF), under the number POCI-01-0247-FEDER-026653
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