50 research outputs found
Smart Monitoring and Control in the Future Internet of Things
The Internet of Things (IoT) and related technologies have the promise of realizing pervasive and smart applications which, in turn, have the potential of improving the quality of life of people living in a connected world. According to the IoT vision, all things can cooperate amongst themselves and be managed from anywhere via the Internet, allowing tight integration between the physical and cyber worlds and thus improving efficiency, promoting usability, and opening up new application opportunities. Nowadays, IoT technologies have successfully been exploited in several domains, providing both social and economic benefits. The realization of the full potential of the next generation of the Internet of Things still needs further research efforts concerning, for instance, the identification of new architectures, methodologies, and infrastructures dealing with distributed and decentralized IoT systems; the integration of IoT with cognitive and social capabilities; the enhancement of the sensing–analysis–control cycle; the integration of consciousness and awareness in IoT environments; and the design of new algorithms and techniques for managing IoT big data. This Special Issue is devoted to advancements in technologies, methodologies, and applications for IoT, together with emerging standards and research topics which would lead to realization of the future Internet of Things
Applications
Volume 3 describes how resource-aware machine learning methods and techniques are used to successfully solve real-world problems. The book provides numerous specific application examples: in health and medicine for risk modelling, diagnosis, and treatment selection for diseases in electronics, steel production and milling for quality control during manufacturing processes in traffic, logistics for smart cities and for mobile communications
Applications
Volume 3 describes how resource-aware machine learning methods and techniques are used to successfully solve real-world problems. The book provides numerous specific application examples: in health and medicine for risk modelling, diagnosis, and treatment selection for diseases in electronics, steel production and milling for quality control during manufacturing processes in traffic, logistics for smart cities and for mobile communications
AI and IoT Meet Mobile Machines
Infrastructure construction is society's cornerstone and economics' catalyst. Therefore, improving mobile machinery's efficiency and reducing their cost of use have enormous economic benefits in the vast and growing construction market. In this thesis, I envision a novel concept smart working site to increase productivity through fleet management from multiple aspects and with Artificial Intelligence (AI) and Internet of Things (IoT)
AI and IoT Meet Mobile Machines: Towards a Smart Working Site
Infrastructure construction is society's cornerstone and economics' catalyst. Therefore, improving mobile machinery's efficiency and reducing their cost of use have enormous economic benefits in the vast and growing construction market. In this thesis, I envision a novel concept smart working site to increase productivity through fleet management from multiple aspects and with Artificial Intelligence (AI) and Internet of Things (IoT)
Tecnologias IoT para pastoreio e controlo de postura animal
The unwanted and adverse weeds that are constantly growing in vineyards,
force wine producers to repeatedly remove them through the use of mechanical
and chemical methods. These methods include machinery such
as plows and brushcutters, and chemicals as herbicides to remove and
prevent the growth of weeds both in the inter-row and under-vine areas.
Nonetheless, such methods are considered very aggressive for vines, and, in
the second case, harmful for the public health, since chemicals may remain
in the environment and hence contaminate water lines. Moreover, such
processes have to be repeated over the year, making it extremely expensive
and toilsome. Using animals, usually ovines, is an ancient practice used
around the world. Animals, grazing in vineyards, feed from the unwanted
weeds and fertilize the soil, in an inexpensive, ecological and sustainable
way. However, sheep may be dangerous to vines since they tend to feed
on grapes and on the lower branches of the vines, which causes enormous
production losses. To overcome that issue, sheep were traditionally used to
weed vineyards only before the beginning of the growth cycle of grapevines,
thus still requiring the use of mechanical and/or chemical methods during the
remainder of the production cycle.
To mitigate the problems above, a new technological solution was investigated
under the scope of the SheepIT project and developed in the
scope of this thesis. The system monitors sheep during grazing periods on
vineyards and implements a posture control mechanism to instruct them to
feed only from the undesired weeds. This mechanism is based on an IoT
architecture, being designed to be compact and energy efficient, allowing it to
be carried by sheep while attaining an autonomy of weeks.
In this context, the thesis herein sustained states that it is possible to
design an IoT-based system capable of monitoring and conditioning sheep’s
posture, enabling a safe weeding process in vineyards. Moreover, we support
such thesis in three main pillars that match the main contributions of this
work and that are duly explored and validated, namely: the IoT architecture
design and required communications, a posture control mechanism and
the support for a low-cost and low-power localization mechanism. The
system architecture is validated mainly in simulation context while the posture
control mechanism is validated both in simulations and field experiments.
Furthermore, we demonstrate the feasibility of the system and the contribution
of this work towards the first commercial version of the system.O constante crescimento de ervas infestantes obriga os produtores a manter
um processo contĂnuo de remoção das mesmas com recurso a mecanismos
mecânicos e/ou quĂmicos. Entre os mais populares, destacam-se o uso de
arados e roçadores no primeiro grupo, e o uso de herbicidas no segundo
grupo. No entanto, estes mecanismos sĂŁo considerados agressivos para as
videiras, assim como no segundo caso perigosos para a saĂşde pĂşblica, visto
que os quĂmicos podem permanecer no ambiente, contaminando frutos e
linhas de água. Adicionalmente, estes processos são caros e exigem mão de
obra que escasseia nos dias de hoje, agravado pela necessidade destes processos
necessitarem de serem repetidos mais do que uma vez ao longo do
ano. O uso de animais, particularmente ovelhas, para controlar o crescimento
de infestantes é uma prática ancestral usada em todo o mundo. As ovelhas,
enquanto pastam, controlam o crescimento das ervas infestantes, ao mesmo
tempo que fertilizam o solo de forma gratuita, ecológica e sustentável. Não
obstante, este método foi sendo abandonado visto que os animais também
se alimentam da rama, rebentos e frutos da videira, provocando naturais
estragos e prejuĂzos produtivos.
Para mitigar este problema, uma nova solução baseada em tecnologias
de Internet das Coisas é proposta no âmbito do projeto SheepIT, cuja espinha
dorsal foi construĂda no âmbito desta tese. O sistema monitoriza as ovelhas
enquanto estas pastoreiam nas vinhas, e implementam um mecanismo de
controlo de postura que condiciona o seu comportamento de forma a que se
alimentem apenas das ervas infestantes. O sistema foi incorporado numa
infraestrutura de Internet das Coisas com comunicações sem fios de baixo
consumo para recolha de dados e que permite semanas de autonomia,
mantendo os dispositivos com um tamanho adequado aos animais.
Neste contexto, a tese suportada neste trabalho defende que Ă© possĂvel
projetar uma sistema baseado em tecnologias de Internet das Coisas,
capaz de monitorizar e condicionar a postura de ovelhas, permitindo que
estas pastem em vinhas sem comprometer as videiras e as uvas. A tese
Ă© suportada em trĂŞs pilares fundamentais que se refletem nos principais
contributos do trabalho, particularmente: a arquitetura do sistema e respetivo
sistema de comunicações; o mecanismo de controlo de postura; e o suporte
para implementação de um sistema de localização de baixo custo e baixo
consumo energético. A arquitetura é validada em contexto de simulação,
e o mecanismo de controlo de postura em contexto de simulação e de
experiências em campo. É também demonstrado o funcionamento do
sistema e o contributo deste trabalho para a conceção da primeira versão
comercial do sistema.Programa Doutoral em Informátic
iCity. Transformative Research for the Livable, Intelligent, and Sustainable City
This open access book presents the exciting research results of the BMBF funded project iCity carried out at University of Applied Science Stuttgart to help cities to become more liveable, intelligent and sustainable, to become a LIScity. The research has been pursued with industry partners and NGOs from 2017 to 2020. A LIScity is increasingly digitally networked, uses resources efficiently, and implements intelligent mobility concepts. It guarantees the supply of its grid-bound infrastructure with a high proportion of renewable energy. Intelligent cities are increasingly human-centered, integrative, and flexible, thus placing the well-being of the citizens at the center of developments to increase the quality of life. The articles in this book cover research aimed to meet these criteria. The book covers research in the fields of energy (i.e. algorithms for heating and energy storage systems, simulation programs for thermal local heating supply, runtime optimization of combined heat and power (CHP), natural ventilation), mobility (i.e. charging distribution and deep learning, innovative emission-friendly mobility, routing apps, zero-emission urban logistics, augmented reality, artificial intelligence for individual route planning, mobility behavior), information platforms (i.e. 3DCity models in city planning: sunny places visualization, augmented reality for windy cities, internet of things (IoT) monitoring to visualize device performance, storing and visualizing dynamic energy data of smart cities), and buildings and city planning (i.e. sound insulation of sustainable facades and balconies, multi-camera mobile systems for inspection of tunnels, building-integrated photovoltaics (BIPV) as active façade elements, common space, the building envelopes potential in smart sustainable cities)
iCity. Transformative Research for the Livable, Intelligent, and Sustainable City
This open access book presents the exciting research results of the BMBF funded project iCity carried out at University of Applied Science Stuttgart to help cities to become more liveable, intelligent and sustainable, to become a LIScity. The research has been pursued with industry partners and NGOs from 2017 to 2020. A LIScity is increasingly digitally networked, uses resources efficiently, and implements intelligent mobility concepts. It guarantees the supply of its grid-bound infrastructure with a high proportion of renewable energy. Intelligent cities are increasingly human-centered, integrative, and flexible, thus placing the well-being of the citizens at the center of developments to increase the quality of life. The articles in this book cover research aimed to meet these criteria. The book covers research in the fields of energy (i.e. algorithms for heating and energy storage systems, simulation programs for thermal local heating supply, runtime optimization of combined heat and power (CHP), natural ventilation), mobility (i.e. charging distribution and deep learning, innovative emission-friendly mobility, routing apps, zero-emission urban logistics, augmented reality, artificial intelligence for individual route planning, mobility behavior), information platforms (i.e. 3DCity models in city planning: sunny places visualization, augmented reality for windy cities, internet of things (IoT) monitoring to visualize device performance, storing and visualizing dynamic energy data of smart cities), and buildings and city planning (i.e. sound insulation of sustainable facades and balconies, multi-camera mobile systems for inspection of tunnels, building-integrated photovoltaics (BIPV) as active façade elements, common space, the building envelopes potential in smart sustainable cities)
Shortest Route at Dynamic Location with Node Combination-Dijkstra Algorithm
Abstract— Online transportation has become a basic
requirement of the general public in support of all activities to go
to work, school or vacation to the sights. Public transportation
services compete to provide the best service so that consumers
feel comfortable using the services offered, so that all activities
are noticed, one of them is the search for the shortest route in
picking the buyer or delivering to the destination. Node
Combination method can minimize memory usage and this
methode is more optimal when compared to A* and Ant Colony
in the shortest route search like Dijkstra algorithm, but can’t
store the history node that has been passed. Therefore, using
node combination algorithm is very good in searching the
shortest distance is not the shortest route. This paper is
structured to modify the node combination algorithm to solve the
problem of finding the shortest route at the dynamic location
obtained from the transport fleet by displaying the nodes that
have the shortest distance and will be implemented in the
geographic information system in the form of map to facilitate
the use of the system.
Keywords— Shortest Path, Algorithm Dijkstra, Node
Combination, Dynamic Location (key words