Maximizing piezoelectricity by self-assembled highly porous perovskite–polymer composite films to enable the internet of things

<p>The fog computing is the emerging technology to compute, store, control and connecting smart devices with each other using cloud computing. The Internet of Things (IoT) is an architecture of uniquely identified interrelated physical things, these physical things are able to communicate with each other and can transmit and receive information. <a>This research presents a framework of the combination of the Internet of Things (IoT) and Fog computing. The blockchain is also the emerging technology that provides a hyper, distributed, public, authentic ledger to record the transactions. Blockchains technology is a secured technology that can be a boon for the next generation computing. The combination of fog, blockchains, and IoT creates a new opportunity in this area. In this research, the author presents a middleware framework based on the blockchain, fog, and IoT. The framework is implemented and tested. The results are found positive. </a></p>

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The Web of Smart Entities—Aspects of a Theory of the Next Generation of the Internet of Things

Artificial Intelligence for the Internet of Everything ◽

10.1016/b978-0-12-817636-8.00007-7 ◽

2019 ◽

pp. 117-137 ◽

Cited By ~ 2

Author(s):

Michael Wollowski ◽

John McDonald

Keyword(s):

Internet Of Things ◽

The Internet ◽

Next Generation ◽

The Internet Of Things ◽

The Web

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Challenges and prospects of 3D micro-supercapacitors for powering the internet of things

Energy & Environmental Science ◽

10.1039/c8ee02029a ◽

2019 ◽

Vol 12 (1) ◽

pp. 96-115 ◽

Cited By ~ 88

Author(s):

Christophe Lethien ◽

Jean Le Bideau ◽

Thierry Brousse

Keyword(s):

Energy Storage ◽

Solid State ◽

Internet Of Things ◽

High Performance ◽

Storage Systems ◽

Electronic Devices ◽

Electrochemical Energy Storage ◽

The Internet ◽

The Internet Of Things ◽

Internet Of Thing

The fabrication of miniaturized electrochemical energy storage systems is essential for the development of future electronic devices for Internet of Thing applications. This paper aims at reviewing the current micro-supercapacitor technologies and at defining the guidelines to produce high performance micro-devices with special focuses onto the 3D designs as well as the fabrication of solid state miniaturized devices to solve the packaging issue.

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Towards Using Cloud Elasticity on the Internet of Things Landscape

Big Data and Cloud Innovation ◽

10.18063/bdci.v3i1.835 ◽

2019 ◽

Vol 3 (1) ◽

Author(s):

Rodrigo Da Rosa Righi ◽

Márcio Miguel Gomes ◽

Cristiano Andrá Da Costa ◽

Helge Parzyjegla ◽

Hans-Ulrich Heiss

Keyword(s):

Internet Of Things ◽

Radio Frequency Identification ◽

High Performance ◽

Virtual Machines ◽

The Internet ◽

Data Volume ◽

Significant Performance ◽

Cloud Elasticity ◽

Performance Gains ◽

The Internet Of Things

The digital universe is growing at significant rates in recent years. One of the main responsible for this sentence is the Internet of Things, or IoT, which requires a middleware that should be capable to handle this increase of data volume at real-time. Particularly, data can arrive in the middleware in parallel as in terms of input data from Radio-Frequency Identification (RFID) readers as request-reply query operations from the users side. Solutions modeled at software, hardware and/or architecture levels present limitations to handle such load, facing the problem of scalability in the IoT scope. In this context, this arti- cle presents a model denoted Eliot - Elasticity-driven Internet of Things - which combines both cloud and high performance computing to address the IoT scal- ability problem in a novel EPCglobal-compliant architecture. Particularly, we keep the same API but offer an elastic EPCIS component in the cloud, which is designed as a collection of virtual machines (VMs) that are allocated and deallocated on-the-fly in accordance with the system load. Based on the Eliot model, we developed a prototype that could run over any black-box EPCglobal- compliant middleware. We selected the Fosstrak for this role, which is currently one of the most used IoT middlewares. Thus, the prototype acts as an upper layer over the Fosstrak to offer a better throughput and latency performances in an effortless way. The results are encouraging, presenting significant performance gains in terms of response time and request throughput when comparing both elastic (Eliot) and non-elastic (standard Fosstrak) executions.

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The Digital Universe

Australian Journal of Telecommunications and the Digital Economy ◽

10.18080/jtde.v2n3.285 ◽

2020 ◽

Vol 2 (3) ◽

pp. 9

Author(s):

Matt Zwolenski ◽

Lee Weatherill

Keyword(s):

Sensor Networks ◽

Information Security ◽

Internet Of Things ◽

Data Protection ◽

Business Models ◽

Unstructured Data ◽

The Internet ◽

Next Generation ◽

The Internet Of Things ◽

The Way

The Digital Universe, which consists of all the data created by PC, Sensor Networks, GPS/WiFi Location, Web Metadata, Web-Sourced Biographical Data, Mobile, Smart-Connected Devices and Next-Generation Applications (to name but a few) is altering the way we consume and measure IT and disrupting proven business models. Unprecedented and exponential data growth is presenting businesses with new and unique opportunities and challenges. As the ‘Internet of Things’ (IoT) and Third Platform continue to grow, the analysis of structured and unstructured data will drive insights that change the way businesses operate, create distinctive value, and deliver services and applications to the consumer and to each other. As enterprises and IT grapple to take advantage of these trends in order to gain share and drive revenue, they must be mindful of the Information Security and Data Protection pitfalls that lay in wait ─ hurdles that have already tripped up market leaders and minnows alike.

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Metaproduct Prototype on the basis of Runningpad

10.7287/peerj.preprints.354 ◽

2014 ◽

Author(s):

Martin Daumer ◽

Patrick Burger

Keyword(s):

Internet Of Things ◽

Transition Period ◽

The Internet ◽

Next Generation ◽

Current Transition ◽

The Internet Of Things

Imagine a world where everything from products to people, spaces and services is connected and together operates as a living network. ‘Meta Products’ is the next generation of ’living’ products, services and spaces referring to the potential of the Internet of Things to reach everywhere and to be embodied in everything. In the current transition period we are living in, we are building new aspirations that demand increasingly clever ways to use the potentially endless amounts of information we can track, sense, measure, share and produce via the constantly improving omnipresent technologies. So we are bringing information-fuelled products and services that will be around us as a network whenever we need them. The result of finding these increasingly clever ways to use information is what we call Meta-Products.

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A High-Performance Coniform Helmholtz Resonator-Based Triboelectric Nanogenerator for Acoustic Energy Harvesting

Nanomaterials ◽

10.3390/nano11123431 ◽

2021 ◽

Vol 11 (12) ◽

pp. 3431

Author(s):

Haichao Yuan ◽

Hongyong Yu ◽

Xiangyu Liu ◽

Hongfa Zhao ◽

Yiping Zhang ◽

...

Keyword(s):

Energy Harvesting ◽

Internet Of Things ◽

High Performance ◽

Helmholtz Resonator ◽

Acoustic Energy ◽

The Internet ◽

Triboelectric Nanogenerator ◽

Sensor Devices ◽

Acoustic Energy Harvesting ◽

The Internet Of Things

Harvesting acoustic energy in the environment and converting it into electricity can provide essential ideas for self-powering the widely distributed sensor devices in the age of the Internet of Things. In this study, we propose a low-cost, easily fabricated and high-performance coniform Helmholtz resonator-based Triboelectric Nanogenerator (CHR-TENG) with the purpose of acoustic energy harvesting. Output performances of the CHR-TENG with varied geometrical sizes were systematically investigated under different acoustic energy conditions. Remarkably, the CHR-TENG could achieve a 58.2% higher power density per unit of sound pressure of acoustic energy harvesting compared with the ever-reported best result. In addition, the reported CHR-TENG was demonstrated by charging a 1000 μF capacitor up to 3 V in 165 s, powering a sensor for continuous temperature and humidity monitoring and lighting up as many as five 0.5 W commercial LED bulbs for acoustic energy harvesting. With a collection features of high output performance, lightweight, wide frequency response band and environmental friendliness, the cleverly designed CHR-TENG represents a practicable acoustic energy harvesting approach for powering sensor devices in the age of the Internet of Things.

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