Development of an Internet of Things Gateway Applied to a Multitask Industrial Plant

Tietz, Fabricio; Brandão, Dennis; Alves, Luiz Ferreira

doi:10.1109/induscon.2018.8627273

Cited by 10 publications

(3 citation statements)

References 7 publications

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“…We then connect and configure the Esp. 8266 Wi-Fi modules to the Micro-Controller Unit (MCU) in-order to establish connectivity between the thing speak cloud server and MCU [7,8]. The cloud server records all the real-time data variables from various sensors and can broadcast these values to all Wi-Fi enabled Electronic Gadgets.…”

Section: Introductionmentioning

confidence: 99%

Real Time Remote Monitoring, Control and Reporting Dashboard System to Avoid Industrial Disasters Using Industrial IOT

Lokku¹,

Reddy²,

Sai³

et al. 2021

Advances in Science and Technology

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In today’s global scenario, with the evolution of new technologies and robust ideas, the world gets more involved and embed the advancements of wireless communication with information technology. An ongoing Gartner report assesses that, by 2021, there will be 25.1 billion web associated gadgets, developing at a pace of 32% every year. Bounties of automation are minimizing the human assistance, intervention and reduced risk factor in industry. Here Industrial Automation is used to control systems or things such as computers or robots or machines or sensors with the help of Internet protocol and cloud computing. In this paper six parameters viz., vibration, temperature, humidity, air quality, sound rate and pressure are monitored and controlled remotely using cloud computing. The system performance automatically changes on the basis of sensor data being collected at regular intervals with a feedback mechanism, thereby allowing the system to control or monitor various devices using internet protocols. The threshold values for all the sensors are set as per the industrial standards. These automation techniques find extensive applications in various control mechanisms to operate the equipment under production processes like boilers and heat-treating ovens, steering and stabilization, pressure exerted by ideal gases in confined containers, vibrations by machinery, air pollution released from chemical composites etc.,

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Section: Introductionmentioning

confidence: 99%

Real Time Remote Monitoring, Control and Reporting Dashboard System to Avoid Industrial Disasters Using Industrial IOT

Lokku¹,

Reddy²,

Sai³

et al. 2021

Advances in Science and Technology

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“…La interconexión digital entre objetos de uso cotidiano es lo que se conoce como internet de las cosas (IoT), esta comunicación permite aprender e interactuar a partir de dispositivos conectados a internet (Esfahani 2017), donde la World Wide Web (www) ha provocado una revolución en la comunicación entre las personas y los objetos, concediendo la integración del mundo cibernético con el mundo físico (Ngu 2016). Minoly (2017), hace mención en la comunicación Máquina a Máquina, los vehículos autónomos (Cheng 2018), impresiones 3D, sensores más pequeños y eficientes (Muñiz 2019), (RFID) monitoreo por radiofrecuencia , sistemas de seguridad (Pancha 2019), ciudades inteligentes (Lau 2017), redes inteligentes, hogares inteligentes (Quispe y Maquera 2019), salud electrónica (Humayed 2017), gestión de activos y logística, agricultura (Ahmed 2018), control y monitoreo industrial (Tietz 2018) entre otros, son algunas aplicaciones mostradas en la figura 1 que corresponden al auge del internet de las cosas.…”

Section: Introductionunclassified

Diseño y construcción de un acoplamiento electrónico para realizar conexiones de IoT en un PLC convencional

Camacho-Altamirano

Martínez-Carrillo

Juárez-Toledo

2019

JCA

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The growth of the digital industrial technology (Industry 4.0) is a revolution that makes it possible to gather, control and analyze data about several technical procedures. The result of this manufacturing revolution is the higher-quality products being produced at a lower cost. It is becoming increasingly difficult to ignore the role that Internet of Things (IoT) has in the productive processes, however, this technology is expensive and requires an update of the Programmable Logic Controllers (PLCs). This paper will focus on the update of the design and construction of an electronic coupling device to make IoT connections in a conventional PLC. In this work a siemens S7-200 PLC is used, in the inputs and outputs of this device a nodemcu esp32 WIFI card is coupled to monitor and control the process. The electronic circuit and the flow diagram of the coupling between the PLC and WIFI card are included. The evidence from this study suggests that the upgrade of the industrial equipment towards the industry 4.0 is possible without the need to make significant changes.

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“…Each platform has a certain application domain, and it is associated with several sensors, gateways and computing platforms, which are built by different service providers. These devices and their communication infrastructure cause a lack of interoperability and several limitations when they are connected to the Internet because service providers need to fabricate the devices and configure the communication protocols for each application and manage redundant data generated from hundreds of sensors [97,98].…”

Section: The Gateways In Internet Of Things and Nano-thingsmentioning

confidence: 99%

Contribution to the system architecture design for electromagnetic nano-network communications

Galal Mahmoud Ibrahim

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(English) A nano-network is a communication network at the nano-scale between nano-devices. Nanodevices face certain challenges in functionalities, because of limitations in their processing capabilities and power management due to their nano-scale size. One of these challenges is the ability to perceive partial or full routing tables, which are the main decision makers for data routing in legacy communication networks. The reason is that creating and updating routing tables continuously require adequate processing power with sufficient memory and computing capabilities, which is not the case with nano- devices. Hence, these devices are expected to perform simple tasks, which equire different and novel approaches. In order to exploit the different functionalities of nano-machines, a set of nano-devices in a full nano-network needs to be managed and controlled using an appropriate architecture. This step will enable unrivaled applications in different fields. An Electromagnetic (EM) nano-network is a type of nano-communication that uses terahertz (THz) EM waves in communication. Nano-network has attracted increasing attention in recent years. Consequently, several developments have been achieved in the fabrication, communication and management of various EM nano network devices serving potential applications ranging from software- defined metamaterials, wireless robotic materials and body-centric communication. Such applications need uplink and downlink communication between the deployed nano-network and the external macro- world or the Internet through nano-interfaces. This causes heterogeneity and interoperability in different Internet of Nano-things (IoNT) applications, which become new challenges for nano-network communication. In this regard, dynamic, flexible and distributed micro/nano gateways can accommodate such sustainable issues and make the nano-network fully operational, regardless of the adopted application domain or the protocols used in communication. With the arrival of the Internet of Things (IoT), the use of the Internet has transformed, where various types of objects, sensors and devices can interact, making future networks connect nearly everything from traditional network devices to people. It is worth remarking that Software Defined Networking (SDN) and Network Function Virtualization (NFV) are two useful technologies for IoT. By outlining the way of combining SDN, NFV, IoT and fog computing technologies altogether, nano- network can overcome its challenges and limitations. The main objective of this thesis is to contribute to the system architectural design of EM nano- networks by developing an operational communication architecture to allow nano-machines to access the Internet. This communication architecture uses next-generation network technologies such as IoT and fog computing, besides well-known virtualization network technologies such as SDN and NFV to guarantee such accessibility. In addition, this communication architecture will provide added value to the data routing in the nano-network paradigm, whether inside the nano-domain or towards the macro- domain by providing virtualization and externalization of the complex routing decisions to be compiled externally on a powerful data center hosted on the cloud. The nano-machines will be able to access the cloud with the aid of smart hybrid devices called micro/nano-gateways, which provide two-way communication between nano-machines and the cloud. This two-way communication allows the end-user to easily control and manage a group of nanomachines expanding various applications in different fields. Moreover, it allows the nano-machines to store their measurements on the cloud, providing very large sets of data that are generated by a variety of nano-sensors/actuators forming big data, where Machine Learning (ML) approaches are used to perform complex analysis, intelligent judgments and creative problem solving on this big data extracting valuable information. (Español) Una nano-red es una red de comunicaciones a la escala nano, entre nano-dispositivos. Los nano-dispositivos afrontan determinados desafíos en funcionalidades, debido a las limitaciones de sui capacidad de procesado y la gestión de energía derivado de su nano-tamaño. Uno de estos desafíos es su capacidad de obtener una tabla de rutas parcial o completa, que es uno de los grandes puntos de decisión para el encaminamiento en redes de comunicaciones. La razón se encuentra en la dificultad y esfuerzo necesario para crear y actualizar continuamente las tablas, en términos de energía, memoria y capacidades de cómputo. En consecuencia, estos dispositivos únicamente efectuarán tareas sencillas, para las que se van a necesitar nuevas propuestas. Con el fin de aprovechar las funcionalidades de las nano-máquinas, un conjunto de nano-dispositivos en una nano-red completa necesita de mecanismos de gestión y control, a través de una arquitectura adecuada. Con ello, se podrán proporcionar nuevas aplicaciones en diversos campos. Una nano-red electromagnética (EM) es un tipo de nano-comunicación que emplea ondas en la banda de Teraherzios (THz). Las nano-redes han sido objeto de creciente atracción en los últimos años. En consecuencia, se han conseguido diversos desarrollos en la fabricación, comunicación y gestión con varios dispositivos en nano-redes EM, para aplicaciones desde metamateriales definidos por software, materiales robóticos wireless y comunicaciones en el cuerpo. Tales aplicaciones necesitan comunicaciones en sentido de subida y bajada, entre la nano-red desplegada y el macro-mundo externo, o Internet, a través de nano-interfaces. Ello causa heterogeneidad e inter-operabilidad en diversas aplicaciones de la Internet de las Nano-Things (IoNT), que constituyen nuevos desafíos para las comunicaciones en nano-redes. En este sentido, micro/nano gateways que sean dinámicos, flexibles y distribuidos, han de poder facilitar el acomodo de dichas aplicaciones y hacer que la red sea completamente operacional, independientemente del dominio de aplicaciones usadas o los protocolos de comunicaciones. Con la llegada de la Internet of Things (IoT), el uso de Internet se ha transformado, donde varios tipos de objetos, sensores y dispositivos pueden interactuar, haciendo que las futuras redes puedan conectar prácticamente cualquier cosa. Software Defined Networking (SDN) y Network Function Virtualization (NFV) son 2 tecnologías relevantes para IoT. Por medio de la combinación de SDN, NFV, IoT y fog computing, las nano-redes pueden solventar sus desafíos y limitaciones. El principal objetivo de esta tesis es contribuir al diseño de la arquitectura del sistema de las nano-redes EM por medio del desarrollo de una propuesta operacional que permita el acceso a Internet a las nano-máquinas Esta arquitectura de comunicaciones emplea las tecnologías de IoT y Fog Computing, además de las conocidas tecnologías de virtualización basadas en SDN y NFV. Además, la arquitectura de comunicaciones proporcionará un valor añadido al encaminamiento en el paradigma de la nano-red, ya sea dentro del nano-dominio o hacia el macro-dominio, por medio de virtualización y externalización de las decisiones complejas de encaminamiento, que serán compiladas externamente en un centro de datos situado en la nube. Las nano-máquinas serán capaces de acceder a la nube con la ayuda de dispositivos híbridos inteligentes denominados micro/nano gateways, que podrán proporcionar comunicaciones completas entre las nano-máquinas y la nube. De esta manera, el usuario final podrá controlar y gestionar un grupo de nano-máquinas y facilitar la creación de aplicaciones en diversos campos. Además, permite a las nano-máquinas almacenar su información en la nube, proporcionando grandes conjuntos de información, big-data, donde estrategías de Machine Learning (ML) se pueden usar para resolver diversos problemas complejos.

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Development of an Internet of Things Gateway Applied to a Multitask Industrial Plant

Cited by 10 publications

References 7 publications

Real Time Remote Monitoring, Control and Reporting Dashboard System to Avoid Industrial Disasters Using Industrial IOT

Real Time Remote Monitoring, Control and Reporting Dashboard System to Avoid Industrial Disasters Using Industrial IOT

Diseño y construcción de un acoplamiento electrónico para realizar conexiones de IoT en un PLC convencional

Contribution to the system architecture design for electromagnetic nano-network communications

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