The document discusses smart industry applications of advanced sensors. It describes Industry 4.0 and the goals of smart industry such as more efficient, customized, and environmentally friendly production. It then discusses predictive maintenance applications using sensors for vibration analysis, sound emission, environment monitoring and analytics. The document presents ST's SensorTile Wireless Industrial Node kit for industrial IoT applications with various integrated sensors and wireless connectivity. Finally, it discusses ST's intelligent power switches and industrial connectivity devices that can be used for factory automation, process instrumentation, motor drives and other industrial equipment.
Remote temperature and humidity monitoring system using wireless sensor networkseSAT Journals
Abstract Today’s world has become very advanced with smart appliances and devices like laptops, tablets, televisions. smart phones with different features and their usage has been enormously increasing in our day-to-day life. The technology advancement in Digital Electronics and Micro Electro Mechanical Systems. In this scenario the most important role is played by Wireless Sensor Networks and its development and usage in heterogeneous fields and several contexts. the home automation field and process control systems and health control systems widely uses wireless sensor networks. Moreover with WSN we can monitor environments and its conditions also. We are designing a protocol to monitor the environmental temperature and humidity at different conditions. The architecture is simple to construct and ease to implement and also has an advantage of low power consumption. The aim of our paper to describe and show how to create a simple protocol for environment monitoring using a wireless development kit. we are using advanced technology of crossbow motes and NESC Language Programming. Keywords: Motes, WSN, sensor, TinyOS, Nesc.
Remote temperature and humidity monitoring system using wireless sensor networkseSAT Journals
Abstract Today’s world has become very advanced with smart appliances and devices like laptops, tablets, televisions. smart phones with different features and their usage has been enormously increasing in our day-to-day life. The technology advancement in Digital Electronics and Micro Electro Mechanical Systems. In this scenario the most important role is played by Wireless Sensor Networks and its development and usage in heterogeneous fields and several contexts. the home automation field and process control systems and health control systems widely uses wireless sensor networks. Moreover with WSN we can monitor environments and its conditions also. We are designing a protocol to monitor the environmental temperature and humidity at different conditions. The architecture is simple to construct and ease to implement and also has an advantage of low power consumption. The aim of our paper to describe and show how to create a simple protocol for environment monitoring using a wireless development kit. we are using advanced technology of crossbow motes and NESC Language Programming. Keywords: Motes, WSN, sensor, TinyOS, Nesc.
Intelligent fire detection and alert system using labVIEWIJECEIAES
Fire detection systems are designed to discover fires and allow the safe evacuation of occupants as well as protecting the safety of emergency response personnel. This paper describes the design and development of a fire detection and alert system. Temperature and flame sensors are used to indicate the occurrence of fire. This work consists of two parts, which are transmitter and receiver, both using ZigBee wireless technology. Arduino Uno is used as the microcontroller at the transmitter part to control the sensor nodes and give alert when over temperature and flame are detected. At the transmitter, the collected data from the sensors are transmitted by an XBee module operated as router node. At the receiver side, an XBee coordinator module which is attached to a computer using USB to serial communication captured the data for further processing. In addition, an interactive and user-friendly Graphical User Interface (GUI) is developed. LabVIEW software is used to design the GUI which displays and analyze the possibility of fire happening. The system can display the fire location and provides early warning to allow occupants to escape the building safely.
An electronic switch sensor with a point to-point intrusive monitoring systemZac Darcy
Sophistications in theft and other criminal damages necessitates for the symbiotic blending of technology with security needs. In this research, electronic switches in the form of sensors were used to implement a point-to point intrusive monitoring system for the detection of an unauthorized access to commercial and residential buildings. The system is a simple and reliable security system and uses switch sensor technology to revolutionize the standards of living. The system is also simple, adaptable and cost-effective. It is designed in six major units which include; the power supply, the input/sensor micro-switches, the monitoring and indicator, the timing, the tone generation and output units. To ensure steady power supply in the circuit, the power unit constitutes both the mains and DC supplies. The alarm unit are being activated by the normally closed sensor micro-switches unit which is connected in an electronic/door mat at both the entrance and exit of buildings. In order to facilitate easy location of the intruder, the exact point of intrusion is being determined by the monitoring and indicator unit which constitutes the quad R/S flip-flop IC and LED’s. The timing/tone generation unit is built on the 555 timer IC, in the Astable mode, which output keeps changing as far as there is a breakage of the sensors. The output of the system is mainly the LEDs and buzzer, which gives electrical light and audio signal to notify the owner of an intruder in the building. Major design issues considered include; efficiency, portability, cost-effectiveness, durability, compatibility as well as the availability of required materials. This system works on the principle of the micro-switch sensor and dependent on the condition that an intruder entered through the door and stepped in any one of the switches under the mat. Verification and validation of the system indicate compliances to design specification hence the output requirements were met.
My solution for this involves IoT device fixed on the safety jacket which is called Smart safety jacket.The Smart Safety Jacket enables complete safety of the employees working in mining and construction industries by installing a different type of sensors like Temperature sensor, Humidity sensor, Ultrasonic sensor, Motion sensor, Gas sensor, Sound sensor, RFID, Emergency Panel, and Notification Panel. These sensors connected to the network through Wi-Fi makes more relevant and valuable ever than before. In case of emergency, immediate notification will be sent to an admin who is monitoring entire miners in the mining industry and immediate action will be taken to rescue miner from the hazard.
The whole process can be stated in two points.
1. The miner has to wear the smart safety jacket (connected with the sensors) which is connected to the control room via a network.
2. A Monitor in the control room who is continuously monitoring the miners and the mining site should check the hazard status and alert and rescue the miners in case of any critical situation.
Thus the mining environment and miners will be protected from the hazard.
Study and Development of Temperature & Humidity monitoring system through Wir...IJERA Editor
Wireless sensor networks have become an integral part of any developing country as it is being used nowadays as the primary monitoring system in various applications. The wireless sensor networks eliminate the hazards associated with the wiring systems and make data measurement and monitoring process much easier and cost effective. The decentralized architecture of the wireless sensor network and its flexibility of deployment make wireless networks most suitable for various process plants, industries and remote & rural communication. In this work, applications of wireless sensor network is carried out on online measurement and monitoring of reaction chamber, furnace etc, which is to be measured in the industries.
Intelligent fire detection and alert system using labVIEWIJECEIAES
Fire detection systems are designed to discover fires and allow the safe evacuation of occupants as well as protecting the safety of emergency response personnel. This paper describes the design and development of a fire detection and alert system. Temperature and flame sensors are used to indicate the occurrence of fire. This work consists of two parts, which are transmitter and receiver, both using ZigBee wireless technology. Arduino Uno is used as the microcontroller at the transmitter part to control the sensor nodes and give alert when over temperature and flame are detected. At the transmitter, the collected data from the sensors are transmitted by an XBee module operated as router node. At the receiver side, an XBee coordinator module which is attached to a computer using USB to serial communication captured the data for further processing. In addition, an interactive and user-friendly Graphical User Interface (GUI) is developed. LabVIEW software is used to design the GUI which displays and analyze the possibility of fire happening. The system can display the fire location and provides early warning to allow occupants to escape the building safely.
An electronic switch sensor with a point to-point intrusive monitoring systemZac Darcy
Sophistications in theft and other criminal damages necessitates for the symbiotic blending of technology with security needs. In this research, electronic switches in the form of sensors were used to implement a point-to point intrusive monitoring system for the detection of an unauthorized access to commercial and residential buildings. The system is a simple and reliable security system and uses switch sensor technology to revolutionize the standards of living. The system is also simple, adaptable and cost-effective. It is designed in six major units which include; the power supply, the input/sensor micro-switches, the monitoring and indicator, the timing, the tone generation and output units. To ensure steady power supply in the circuit, the power unit constitutes both the mains and DC supplies. The alarm unit are being activated by the normally closed sensor micro-switches unit which is connected in an electronic/door mat at both the entrance and exit of buildings. In order to facilitate easy location of the intruder, the exact point of intrusion is being determined by the monitoring and indicator unit which constitutes the quad R/S flip-flop IC and LED’s. The timing/tone generation unit is built on the 555 timer IC, in the Astable mode, which output keeps changing as far as there is a breakage of the sensors. The output of the system is mainly the LEDs and buzzer, which gives electrical light and audio signal to notify the owner of an intruder in the building. Major design issues considered include; efficiency, portability, cost-effectiveness, durability, compatibility as well as the availability of required materials. This system works on the principle of the micro-switch sensor and dependent on the condition that an intruder entered through the door and stepped in any one of the switches under the mat. Verification and validation of the system indicate compliances to design specification hence the output requirements were met.
My solution for this involves IoT device fixed on the safety jacket which is called Smart safety jacket.The Smart Safety Jacket enables complete safety of the employees working in mining and construction industries by installing a different type of sensors like Temperature sensor, Humidity sensor, Ultrasonic sensor, Motion sensor, Gas sensor, Sound sensor, RFID, Emergency Panel, and Notification Panel. These sensors connected to the network through Wi-Fi makes more relevant and valuable ever than before. In case of emergency, immediate notification will be sent to an admin who is monitoring entire miners in the mining industry and immediate action will be taken to rescue miner from the hazard.
The whole process can be stated in two points.
1. The miner has to wear the smart safety jacket (connected with the sensors) which is connected to the control room via a network.
2. A Monitor in the control room who is continuously monitoring the miners and the mining site should check the hazard status and alert and rescue the miners in case of any critical situation.
Thus the mining environment and miners will be protected from the hazard.
Study and Development of Temperature & Humidity monitoring system through Wir...IJERA Editor
Wireless sensor networks have become an integral part of any developing country as it is being used nowadays as the primary monitoring system in various applications. The wireless sensor networks eliminate the hazards associated with the wiring systems and make data measurement and monitoring process much easier and cost effective. The decentralized architecture of the wireless sensor network and its flexibility of deployment make wireless networks most suitable for various process plants, industries and remote & rural communication. In this work, applications of wireless sensor network is carried out on online measurement and monitoring of reaction chamber, furnace etc, which is to be measured in the industries.
Webinar embarcados - Simplificando seus projetos de Internet das coisas com o...Embarcados
Conheça o iMCP HT32SX – O componente para conectividade Sigfox, desenvolvido e fabricado no Brasil pela HT Micron Semicondutores S.A.! Perfeito para fazer protótipos do seu dispositivo IoT em menos tempo e com mais facilidade.
O iMCP HT32SX é um System-in-Package(SiP) que integra diferentes componentes e tecnologias dentro de um único encapsulamento. O sistema otimizado do SiP permite um melhor desempenho, menor consumo de energia e o desenvolvimento de dispositivos IoT com tamanhos super reduzidos.
Topic: Augmented Internet of Things
Speaker: Francois Guibert (Executive Vice President and President, Greater China and South Asia Region STMicroeletronics)
IEEE CS Phoenix - Internet of Things Innovations & Megatrends 12/2/15Mark Goldstein
Mark Goldstein, President, International Research Center (http://www.researchedge.com/) presented on the Internet of Things Innovations & Megatrends exploring the next Internet wave, the Internet of Things (IoT), expected to connect tens of billions of new sensors and devices in the coming years. Waves of change will roll through home, business, government, industrial, medical, transportation, and other complex ecosystems. This presentation examines how IoT will be implemented and monetized creating new business models from pervasive sensor deployments and data gathering, accompanied by new privacy and security risks. And it explores IoT’s roadblocks and operational challenges, emerging standards and protocols, gateway and wireless integration, and big data strategies and opportunities.
XES Automation is a startup in the field of surveillance and surveying technologies. We plan to start providing mobile robotic solutions for government sector and enormous private sector industries with our prime focus on the mining industry, defence operations and public safety.
The company was informally formed in March, 2014 and is ready to roll out its first remote survey robot TASSA-X in 2015, with a mission of re-allocating the 297 recorded abandoned/orphaned mines of India saving up to 10 billion tons of just coal reserves. Similar designs to TASSA-X have promised an increase of productivity of up to 30% in Korean mines. The secondary objective of TASSA-X variant is to serve in the military operations across the border for surveillance and for hazardous material handling operations for in Indian police.
Internet of Things Innovations & Megatrends Update 12/14/16Mark Goldstein
Mark Goldstein, President, International Research Center (http://www.researchedge.com/) presented an Internet of Things Innovations & Megatrends Update to the IEEE Computer Society Phoenix Chapter (http://ewh.ieee.org/r6/phoenix/compsociety/) on Wednesday, December 14, 2016 bringing up to date his presentation to the Chapter a year earlier. His long-form presentation explores the next Internet wave, the Internet of Things (IoT), expected to connect tens of billions of new sensors and devices in the coming years. Waves of change will roll through home, business, government, industrial, medical, transportation, and other complex ecosystems. This presentation examines how IoT will be implemented and monetized creating new business models from pervasive sensor deployments and data gathering, accompanied by new privacy and security risks. And it explores IoT’s roadblocks and operational challenges, emerging standards and protocols, gateway and wireless integration, and big data strategies and opportunities.
The fourth webinar in the series – From concept to consumer – make your IoT idea a commercial reality – looked into the challenges around power management for IoT devices.
As the desire for IoT solutions broadens to include features such as continual sensor readings, real-time data management, and on-board processing, the need to select the right hardware becomes ever more important. In addition is the requirement for effective power management.
The webinar looked at the challenges of power management including:
•Strategies to increase your battery performance
•Alternative techniques to deliver performance without compromising your output
•Identifying the trade-offs between use-cases and performance
Similar to Webinar: Potencializando a Indústria 4.0 com tecnologias ST (20)
Webinar: Controle de motores BLDC e de indução trifásicoEmbarcados
Pensando nas aplicações que necessitam de controle de motor e na complexidade envolvida, a Microchip tem desenvolvido diversos componentes, algoritmos e ferramentas para ajudar no desenvolvimento para o produto ir para o mercado em perfeito funcionamento e com menor tempo de desenvolvimento. Nesse webinar apresentaremos como você pode desenvolver facilmente aplicações para controle de motores BLCD e de indução trifásico usando os algoritmos FOC, Zero-Speed/Maximum-Torque Control, six step e v/f, com os softwares e hardware da Microchip.
Assista a gravação em: https://embarcados.com.br/webinar-controle-de-motores-bldc-e-de-inducao-trifasico/
Neste webinar serão abordadas topologias e aplicações nas quais o uso de FPGA é vantajoso em relação ao uso de processadores. Serão apresentadas comparações de designs equivalentes em FPGA e em software, apontando os cenários em que o uso de cada uma das tecnologias tem melhor performance.
Webinar: Especificação de Componentes PassivosEmbarcados
Nessa apresentação, descreveremos brevemente uma visão geral do portfólio do Grupo Yageo. Também daremos um mergulho mais profundo em alguns grupos de produtos, como capacitores de alumínio e polímero de tântalo, bem como na linha de magnéticos, sensores e atuadores.
Webinar: Projeto de hardware utilizando Conversores DC/DCEmbarcados
O objetivo do webinar é apresentar os conversores DC/DC da Vishay, especialmente projetados para sistemas embarcados, baseados em microprocessadores e/ou FPGAs. Em geral, estes sistemas exigem baixas tensões e altas correntes. Os CIs conversores da Vishay foram projetados para cumprir essa função com alta eficiência e facilidade de projeto.
Apresentação da nova linha de microcontroladores Cortex-M da Microchip e o framework MCC Harmony. O principal foco será nova linha PIC32CX é voltada para aplicações de conectividade e segurança. Apresentando como implementar uma comunicação Ethernet TCP com segurança.
Um grande desafio no desenvolvimento de sistema Linux embarcado é garantir a reprodutibilidade do trabalho. Um sistema Linux possui milhares de opções de customização e, somado a isso, cada fabricante e chip possui suas especificações.
Foi para resolver esses e outros problemas que o Yocto Project foi criado pela The Linux Foundation.
Nesse webinar vamos abordar o uso do Yocto Projeto no dia a dia, os conceitos básicos de sua arquitetura e em quais tipos de aplicações onde seu uso é mais indicado.
Para mais informações: https://embarcados.com.br/desvendando-o-yocto-project/
Webinar: Bancada de eletrônica profissionalEmbarcados
Durante o webinar, discutiremos a importância da escolha correta dos instrumentos e ferramentas para a bancada de um profissional de eletrônica e os cuidados necessários para melhor aproveitamento e manutenção desses instrumentos.
Apresentaremos os itens indispensáveis para ter em sua bancada de eletrônica profissional e os critérios para a escolha dos mesmos.
Não perca a oportunidade de conhecer equipamentos de qualidade com excelente custo/beneficio e entender por que é importante investir em equipamentos adequados, aprendendo como dimensionar os itens de acordo com suas necessidades.
Webinar: Como projetar sensores de baixo consumo utilizando microcontroladore...Embarcados
Participe do nosso Webinar e descubra como os Microcontroladores PIC e AVR podem simplificar projetos de sensores de baixa potência.
Durante a apresentação, abordaremos os periféricos analógicos integrados e as atualizações mais recentes desses dispositivos, além de como eles interagem com um sistema maior. Também destacaremos os recursos de baixo consumo de energia presentes nos dispositivos PIC e AVR mais recentes.
Para facilitar o desenvolvimento com esses microcontroladores, mostraremos exemplos práticos de placas de demonstração e ferramentas disponíveis no mercado.
Se você quer aprender a desenvolver projetos de sensores de baixa potência com Microchip, este é o webinar certo para você! Inscreva-se agora mesmo e participe dessa oportunidade única de ampliar seus conhecimentos aprendendo com um especialista da Microchip. Venha tirar suas dúvidas ao vivo no webinar.
O que você aprenderá nesse webinar:
Microcontroladores de 8 bits da Microchip? PIC e AVR
Periféricos analógicos integrados e atualizações recentes
Como esses dispositivos interagem com um sistema maior
Recursos de baixo consumo de energia em dispositivos PIC e AVR recentes
Placas de demonstração
Ferramentas
Como podemos começar a desenvolver com Microchip?
Webinar: Desvendando o seguidor de linha: sensores, montagem e programação co...Embarcados
Neste webinar, discutiremos as etapas envolvidas na construção de um robô seguidor de linha. Exploraremos os principais sensores utilizados em robôs seguidores de linha, como o sensor infravermelho e o sensor de reflexão, e como eles são usados para detectar e seguir uma linha, incluindo um teste comparativo entre eles para a utilização do PID. Também abordaremos os materiais necessários para a construção do robô, incluindo a placa PCB e a impressão 3D, e como eles são usados para construir um robô preciso e robusto.
Além disso, iremos explorar as diversas ferramentas e técnicas disponíveis para simplificar o trabalho colaborativo em projetos de robótica, incluindo o uso de plataformas de compartilhamento de código e documentação.
O que você aprenderá neste webinar
Você aprenderá sobre as etapas para construção de um robô seguidor de linha, os principais sensores, materiais e técnicas utilizados. Também conhecerá ferramentas de trabalho colaborativo em projetos de robótica.
Apresentação
Diogo Lacerda
Técnico em Mecatrônica e graduando de Física de Materiais pela Universidade de Pernambuco. Começou a carreira profissional como professor de robótica e depois migrou para o ramo de sistema embarcados. Atualmente trabalha no CESAR com modelagem e impressão 3D, utilizando a manufatura aditiva como ferramenta para desenvolver protótipos para circuitos eletrônicos e mecanismos de forma mais barata e rápida. Fez parte da equipe de robótica CESAR-Voxar Labs, que é bicampeão na categoria @home pela Competição Brasileira de Robótica (CBR). Faz parte da rede colaborativa http://robolivre.com/ desde 2012, onde ministra oficinas e palestras sobre robótica e Arduino.
Webinar Gravado: Um Estudo sobre a I2C e o Futuro com a I3CEmbarcados
Para saber mais e assistir ao video, acesse: https://embarcados.com.br/webinar-um-estudo-sobre-a-i2c-e-o-futuro-com-a-i3c/
Durante o webinar, você aprenderá sobre as características e o funcionamento básico da I2C, suas aplicações e os desafios enfrentados ao projetar com essa interface. Além disso, você conhecerá as inovações e melhorias trazidas pela I3C e aprenderá como interoperar com a I2C.
Será feita também uma comparação entre os padrões e suas implementações físicas e lógicas, o que ajudará a entender melhor as diferenças e vantagens de cada um deles.
Não perca a oportunidade de aprimorar seus conhecimentos sobre a I2C e a I3C. Inscreva-se agora mesmo no nosso webinar e saiba tudo sobre essa interface e seu futuro!
Apresentação
Huéliquis Fernandes - Business Development Manager
Huéliquis é um experiente profissional da indústria de semicondutores. Nos últimos 25 anos trabalhou para a Future Electronics, Motorola/Freescale, ST Microelectronics e Renesas.
Yoshinori Kanno - Field Application Engineer
Yoshinori é formado em Engenharia Eletrônica e possui mestrado em Processamento Digital de Sinais. Nos últimos 20 anos, ele trabalhou na Philips/NXP e em distribuidores globais.
Matthew Sauceda - Sr. Principal Applications Engineer - Nexperia
Matthew Sauceda is a Sr Principal Applications Engineer for Nexperia. He holds a M.S in Electrical Engineering specializing in Analog and Mixed Signal VLSI design. His work experience includes 10+ years in semiconductor field through work as application/system/ hardware design in Texas Instruments, and Advanced Micro Devices. In his spare time he enjoys hobbies such as fishing, traveling, and woodworking.
Descrição do Webinar
Nesse webinar você conhecera as soluções da Infineon e a família de Microcontroladores Traveo T2G. Iremos abordar quais os pontos diferenciais nessa linha de Microcontroladores ARM Cortex M4 e M7 e quais itens a Infineon pode lhe oferecer para facilitar o desenvolvimento. Iremos apresentar o ecossistema de parceiros, ferramentas de desenvolvimento e aplicações foco da linha Traveo T2G e demonstrar o porquê ele tem sido o líder em aplicações automotivas e industriais, quando são necessários requisitos de low power, conectividade e segurança para Over-the-Air (OTA).
O que você aprenderá nesse webinar:
Após esse webinar você entendera quais os requisitos básicos e diferenciais da família de Microcontroladores Traveo T2G. Também conhecera o ecossistema e como começar a desenvolver seus projetos utilizando a família Traveo T2G, desenvolvida para sistemas automotivos e industriais que requerem desempenho, low power, conectividade e segurança com suporte técnico e vendas no Brasil.
Webinar: Introdução à Reconfiguração dinâmica parcial em FPGAsEmbarcados
Nesse webinar foi apresentado sobre reconfiguração dinâmica parcial em FPGAs Xilinx! Regina abordou sobre os conceitos e termos básicos dessa tecnologia, seu fluxo de implementação, prós e contras, aspectos relevantes e aplicações.
Webinar: Microprocessadores 32 bits, suas principais aplicações no mercado br...Embarcados
Junte-se a nós para saber mais sobre as soluções de microprocessador (MPU) da Microchip e como o System in Package (SiP) e o System on Modules (SoM) podem simplificar drasticamente o projeto da sua PCB e reduzir o tempo de lançamento no mercado. Os produtos System in Package (SiP) com DRAM integrada simplificam o projeto de PCB, melhoram a robustez geral de EMI do seu sistema, removem o problema de fornecimento de DRAM e problemas de software e podem, em última análise, reduzir os custos gerais do sistema abrindo a porta para projeto de PCB de 4 camada para sua aplicação. As soluções SOM da Microchip fornecem uma plataforma de hardware qualificada projetada para longa vida útil e ajudam você a acelerar suas primeiras construções de produção com os SOMs e otimizar o custo de BOM, passando posteriormente para soluções chip-down em volumes maiores usando os arquivos de design e suporte fornecidos pela Microchip. Você também aprenderá sobre a estratégia principal do Linux da Microchip com suporte de longo prazo e um caminho fácil para uma solução gráfica de baixo custo. Os MPUs Microchip são adequados para uma variedade de aplicações, incluindo aquelas nos setores de consumo, automotivo, industrial e médico.
Neste Webinar apresentaremos as principais soluções em Timming devices (Ressonadores e Cristas) Murata, suas tecnologias, materiais utilizados, aplicações, como identificar possíveis falhas e como utilizar ferramenta de seleção da Murata Simsurfing.
Tópicos do Webinar
Tecnologia Timing Devices
Ressonadores e Cristais
Vantagens dos Ressonadores Murata
Vantagens dos Cristais Murata
Como identificar possíveis falhas nos Ressonadores e Cristais.
Matching - como identificar melhor Cristal de acordo com microprocessador.
Ferramenta Murata Simsurfing
Aplicações
Webinar: Silicon Carbide (SiC): A tecnologia do futuro para projetos de potênciaEmbarcados
Descubra as vantagens de utilizar MosFETs e Gate Drivers com SiC.
O webinar abordará a tecnologia SiC, suas vantagens e aplicações no mercado brasileiro, com destaque para a relação entre SiC e carros elétricos. A Microchip oferece produtos relacionados à tecnologia SiC, como Mosfets, Gate Drivers, demoboards e reference designs. O webinar será uma ótima oportunidade para conhecer mais sobre essa tecnologia promissora e entender o que a Microchip tem a oferecer nesse segmento.
Webinar: Por que dominar sistema operacional Linux deveria ser a sua prioridade?Embarcados
O sistema operacional Linux tem sido cada vez mais utilizado em diferentes setores da indústria, especialmente na área de sistemas embarcados. Hoje o Linux embarcado é utilizado em dispositivos eletrônicos de diversas áreas, como automação industrial, automotiva, agrícola, medica, aeroespacial, de comunicação e de entretenimento.
Com a crescente demanda por profissionais qualificados em Linux Embarcado, é importante entender por que dominar esse sistema operacional deve ser sua prioridade como desenvolvedor de sistemas embarcados.
No webinar, discutiremos as principais razões pelas quais você deve investir em seu desenvolvimento em Linux e como isso pode abrir portas para novas oportunidades profissionais. Também serão abordados os principais recursos e funcionalidades do Linux, além de dicas práticas para aprimorar suas habilidades como desenvolvedor.
Webinar: Estratégias para comprar componentes eletrônicos em tempos de escassezEmbarcados
Neste webinar, abordaremos a situação atual do mercado mundial de componentes para auxiliar as empresas de manufatura na elaboração de estratégias eficientes para a programação de compras.
Forneceremos informações valiosas para profissionais que atuam em departamentos de produto, compras e suprimentos. Além disso, apresentaremos como utilizar sua lista de materiais para realizar compras consolidadas e programadas, bem como outras ferramentas úteis para o processo de aquisição de materiais e suprimentos.
Webinar: ChatGPT - A nova ferramenta de IA pode ameaçar ou turbinar a sua car...Embarcados
Ninguém esperava isso. Com diferentes níveis de espanto, admiração ou surpresa, as pessoas descobriram o chatGPT e sua utilidade. Seria algo tão novo assim, sem nenhum precedente? E, o mais importante, será o fim do trabalho dos programadores? O que isso pode significar para quem está hoje, na bancada? Este webinar explora o tema, tentando apontar e auxiliar os desenvolvedores a tomar as melhores decisões nesse novo cenário.
Objetivo do Webinar
Debater pontos positivos e importantes sobre estas novas tecnologias. Avaliar o risco que trazem e o benefício que geram. Abraçar uma novidade que aumenta a produtividade de forma significativa, sem preconceitos ou restrições sem fundamento sempre colocam os praticantes em vantagem competitiva.
Webinar: Power over Ethernet (PoE) e suas aplicações no mercado brasileiroEmbarcados
Neste webinar vamos explorar os seguintes temas:
O que é Power over Ethernet (PoE)
Por que os desenvolvedores devem selecionar os dispositivos do sistema Microchip PoE
Como o portfólio de dispositivos e sistemas PoE da Microchip garante que o cliente tenha a solução adequada para cada situação
Exemplos de onde a Microchip implantou com sucesso suas soluções PoE
O que considerar ao pensar no desenvolvimento do projeto do PoE
Webinar: Utilizando o Yocto Project para automatizar o desenvolvimento em Lin...Embarcados
Nesse webinar conheceremos o Yocto Project, um conjunto de ferramentas open-source que possuem o objetivo de facilitar o desenvolvimento de distribuições e sistemas Linux. Também vamos entender como utilizar a ferramenta pode auxiliar na automatização do desenvolvimento de sistemas Linux Embarcado.
https://embarcados.com.br/webinar-utilizando-o-yocto-project-para-automatizar-o-desenvolvimento-em-linux-embarcado/
Let's dive deeper into the world of ODC! Ricardo Alves (OutSystems) will join us to tell all about the new Data Fabric. After that, Sezen de Bruijn (OutSystems) will get into the details on how to best design a sturdy architecture within ODC.
JMeter webinar - integration with InfluxDB and GrafanaRTTS
Watch this recorded webinar about real-time monitoring of application performance. See how to integrate Apache JMeter, the open-source leader in performance testing, with InfluxDB, the open-source time-series database, and Grafana, the open-source analytics and visualization application.
In this webinar, we will review the benefits of leveraging InfluxDB and Grafana when executing load tests and demonstrate how these tools are used to visualize performance metrics.
Length: 30 minutes
Session Overview
-------------------------------------------
During this webinar, we will cover the following topics while demonstrating the integrations of JMeter, InfluxDB and Grafana:
- What out-of-the-box solutions are available for real-time monitoring JMeter tests?
- What are the benefits of integrating InfluxDB and Grafana into the load testing stack?
- Which features are provided by Grafana?
- Demonstration of InfluxDB and Grafana using a practice web application
To view the webinar recording, go to:
https://www.rttsweb.com/jmeter-integration-webinar
Essentials of Automations: Optimizing FME Workflows with ParametersSafe Software
Are you looking to streamline your workflows and boost your projects’ efficiency? Do you find yourself searching for ways to add flexibility and control over your FME workflows? If so, you’re in the right place.
Join us for an insightful dive into the world of FME parameters, a critical element in optimizing workflow efficiency. This webinar marks the beginning of our three-part “Essentials of Automation” series. This first webinar is designed to equip you with the knowledge and skills to utilize parameters effectively: enhancing the flexibility, maintainability, and user control of your FME projects.
Here’s what you’ll gain:
- Essentials of FME Parameters: Understand the pivotal role of parameters, including Reader/Writer, Transformer, User, and FME Flow categories. Discover how they are the key to unlocking automation and optimization within your workflows.
- Practical Applications in FME Form: Delve into key user parameter types including choice, connections, and file URLs. Allow users to control how a workflow runs, making your workflows more reusable. Learn to import values and deliver the best user experience for your workflows while enhancing accuracy.
- Optimization Strategies in FME Flow: Explore the creation and strategic deployment of parameters in FME Flow, including the use of deployment and geometry parameters, to maximize workflow efficiency.
- Pro Tips for Success: Gain insights on parameterizing connections and leveraging new features like Conditional Visibility for clarity and simplicity.
We’ll wrap up with a glimpse into future webinars, followed by a Q&A session to address your specific questions surrounding this topic.
Don’t miss this opportunity to elevate your FME expertise and drive your projects to new heights of efficiency.
Epistemic Interaction - tuning interfaces to provide information for AI supportAlan Dix
Paper presented at SYNERGY workshop at AVI 2024, Genoa, Italy. 3rd June 2024
https://alandix.com/academic/papers/synergy2024-epistemic/
As machine learning integrates deeper into human-computer interactions, the concept of epistemic interaction emerges, aiming to refine these interactions to enhance system adaptability. This approach encourages minor, intentional adjustments in user behaviour to enrich the data available for system learning. This paper introduces epistemic interaction within the context of human-system communication, illustrating how deliberate interaction design can improve system understanding and adaptation. Through concrete examples, we demonstrate the potential of epistemic interaction to significantly advance human-computer interaction by leveraging intuitive human communication strategies to inform system design and functionality, offering a novel pathway for enriching user-system engagements.
Neuro-symbolic is not enough, we need neuro-*semantic*Frank van Harmelen
Neuro-symbolic (NeSy) AI is on the rise. However, simply machine learning on just any symbolic structure is not sufficient to really harvest the gains of NeSy. These will only be gained when the symbolic structures have an actual semantics. I give an operational definition of semantics as “predictable inference”.
All of this illustrated with link prediction over knowledge graphs, but the argument is general.
The Art of the Pitch: WordPress Relationships and SalesLaura Byrne
Clients don’t know what they don’t know. What web solutions are right for them? How does WordPress come into the picture? How do you make sure you understand scope and timeline? What do you do if sometime changes?
All these questions and more will be explored as we talk about matching clients’ needs with what your agency offers without pulling teeth or pulling your hair out. Practical tips, and strategies for successful relationship building that leads to closing the deal.
Kubernetes & AI - Beauty and the Beast !?! @KCD Istanbul 2024Tobias Schneck
As AI technology is pushing into IT I was wondering myself, as an “infrastructure container kubernetes guy”, how get this fancy AI technology get managed from an infrastructure operational view? Is it possible to apply our lovely cloud native principals as well? What benefit’s both technologies could bring to each other?
Let me take this questions and provide you a short journey through existing deployment models and use cases for AI software. On practical examples, we discuss what cloud/on-premise strategy we may need for applying it to our own infrastructure to get it to work from an enterprise perspective. I want to give an overview about infrastructure requirements and technologies, what could be beneficial or limiting your AI use cases in an enterprise environment. An interactive Demo will give you some insides, what approaches I got already working for real.
Smart TV Buyer Insights Survey 2024 by 91mobiles.pdf91mobiles
91mobiles recently conducted a Smart TV Buyer Insights Survey in which we asked over 3,000 respondents about the TV they own, aspects they look at on a new TV, and their TV buying preferences.
GraphRAG is All You need? LLM & Knowledge GraphGuy Korland
Guy Korland, CEO and Co-founder of FalkorDB, will review two articles on the integration of language models with knowledge graphs.
1. Unifying Large Language Models and Knowledge Graphs: A Roadmap.
https://arxiv.org/abs/2306.08302
2. Microsoft Research's GraphRAG paper and a review paper on various uses of knowledge graphs:
https://www.microsoft.com/en-us/research/blog/graphrag-unlocking-llm-discovery-on-narrative-private-data/
DevOps and Testing slides at DASA ConnectKari Kakkonen
My and Rik Marselis slides at 30.5.2024 DASA Connect conference. We discuss about what is testing, then what is agile testing and finally what is Testing in DevOps. Finally we had lovely workshop with the participants trying to find out different ways to think about quality and testing in different parts of the DevOps infinity loop.
2. • Industry 1.0: Mechanization, Steam Power
• Industry 2.0: Mass Production, Assembly Line, Electrical Energy
• Industry 3.0: Automation, Computers and Electronics
• Industry 4.0: Cyber Physical Systems, IoT, Networks
What is “smart industry”?
2
3. Big data
& Cloud computing
Local, mass
customized production
Producing more efficiently
and in more environmentally
friendly manner
Evolved man-machine
cooperation
Safer working
environments
More efficient
operation
Less waste
Collecting and
using manufacturing and
supply chain data better
Responding to demand with
more flexibly and with more
customization
With a better and safer human
experience
Smart Industry Scope and Goals
3
5. Architecture for predictive maintenance
5
Predictive algorithms
• Analytical models limited to representing linear characteristics
• Machine learning techniques based on classification methods
Monitoring
• Sensors to detect anomalies
• Communication at factory level
• Processing (e.g. FFT analysis in vibration
monitoring)
• Secure communication outside the factory
• Remote monitoring from the Cloud
Analytics
Low power / Scalable / Secure / Real-time
Sensing – Processing – Connectivity
7. Discovery Kit
IoT Node
SensorTile.boxNFC Dynamic Tag
Sensor Node
SensorTile Wireless
Industrial Node
Complete ecosystem offering by ST
7
Lower barriers from
prototyping to first product
Connectivity solutions
Analog components
Sensors & actuators
Power management
Microcontrollers
Secure solutions
Motor control
All building blocks
for IoT devices
Lower barriers for
developers getting started
Enable product & service
commercialization
Stackable boards
& modular SW
Form-factor boards
Pre-integrated software
for vertical applications
Development ecosystem
Partner Program and ST community
Integration of Cloud Provider SDKs
STM32 Nucleo Development
& Expansion Boards
9. Launching in 2020
Launched in 2019
Ultra-low-power MCUs
Mainstream MCUs
Cortex®-M0
Cortex®-M0+
Cortex®-M3 Cortex®-M4 Cortex®-M7
High-performance MCUs
Wireless MCUs
Cortex®-M33
MPUs
STM32 portfolio positioning
Keep releasing your growing creativity > 1600 Part Numbers
More than
60,000 customers
Note : Cortex-M0+ Radio Co-processor
Multi Core MPU
Dual Core Cortex®-A7
& Cortex®-M4
Dual Core MCU
Cortex®-M7
& Cortex®-M4
10. STM32 Information and Sharing
10
Information MCU Selection Community
+ Local trainings / Technical Support
+ Local Sales forces / Distributors
st.com/en/
microcontrollers-microprocessors.html ST MCU Finder community.st.com
Get connected to STM32 world !
Social Media
facebook.com/stm32
youtube.com/STonlineMedia
twitter.com/@ST_World
linkedin.com/stmicroelectronics
21IC
YouKu
11. • http://www.st.com/stm32education
• STM32 step-by-step is a learning program, part of the STM32 Education initiative, designed for anyone
interested in getting started on building projects with the STM32 microcontroller and its powerful
ecosystem of development boards and software programming tools.
• Whether you are an experienced embedded programmer or an enthusiastic beginner, learn in 5 tutorials
from the basics of the STM32 ecosystem installation to advanced software development with sensors,
UART messages and Bluetooth communication.
• Start now and quickly become a professional STM32 developer!
11
Building projects with the STM32 MCUs and its
Ecosystems
12. • STM32 online training courses
in MOOC format to help you
design with ST products,
software and tools.
• The MOOC platform enables you to
• study from any place, even from your
bed,
• study at any time, midnight owls
welcome!
• study at your own pace from any
internet connected device.
• ST online courses are free of charge,
your only investmentis the applicable
STM32 Discovery kit from your local
distributor and some USB cables.
12
STM32 MOOC
Massive Open Online Courses
13. • Our teams of training experts provide free multiday courses for our
microcontroller products.
13
STM32 Training Courses
• Sessions provided
by our Training
Partners offer you
several services
and extended
flexibility in terms
of:
• Coverage and
available
sessions
• Language
options
• Combined
sessions with
RTOS, tools,
communication
protocols
14. • Browse our media library selection of videos on our STM32 platform.
14
STM32 Videos
15. ST MCU Finder
All STM32 & STM8 in one place
15
www.st.com/stmcufinderDownload it !
Tell your colleagues and customers
Now available on Windows®, Linux® and macOS™
Select your MCU and instantly access to all resources from one place
17. Train NN Model
2
1
4
The key steps behind Neural Networks
Neural Network (NN) Model Creation Operating Mode
Clean, label data
Build NN topology
Capture data
Convert NN into
optimized code for MCU
Process & analyze new
data using trained NN
5
17
3
18. STM32CubeMX extension
AI conversion tool
Input your framework-dependent,
pre-trained Neural Network into the
STM32Cube.AI conversion tool
Automatic and fast generation of an
STM32-optimized library
STM32Cube.AI offers interoperability
with state-of-the-art Deep Learning
design frameworks
Train NN Model
Convert NN into
optimized code
for MCU
Process & analyze new
data using trained NN
18
Any framework that can export
models in ONNX open format can be
imported
And more
20. Imbalance Looseness Output shaft Gear Mesh
t
Monitoring of an industrial motor
typical use case
20
Any parameters deviation is an indicator of potential failure
• Displacement
• Speed
• Acceleration
• Acoustic noise
• Angular speed
• Torque
Mechanical
vibration
• Current
• Voltage
• Electrostatic
discharge
• Magnetic flux –
internal
• Magnetic flux –
external
Electromagnetic
• Winding temperature
• Bearing temperature
Thermal
21. Sensors for predictive maintenance
21
Machine
conditions
Time
Conditions
start to
change
Power
days
Smoke
minutes
months
Ultrasound
weeks
Noise
Vibration
The curve slope depends
on the life-cycle of the
equipment
Failure
Temperature
26. • Environmental data
• Humidity and temperature data coming
from HTS221
• Pressure coming from LPS22HH
• Wide band Accelerometer FFT
analysis
• Data coming from IIS3DWB
• Ultrasound emission analysis - FFT
• Data coming from MP23ABS1
DSH-PREDMNT
26
29. ST industrial sensors
29
10-Year Product Longevity
Benefits
10-YEAR
LONGEVITY FROM
PRODUCT
INTRODUCTION
DATE
EXTENDED
TEMPERATURE
RANGE AND
ENDURANCE TO
SHOCK AND
VIBRATION
DESIGN AND
MANUFACTURING
FOR HIGHER
ROBUSTNESS &
PERFORMANCES
CALIBRATION &
TESTING FOR
HIGHER
ACCURACY &
QUALITY
Growing Product Family
https://www.st.com/content/st_com/en/about/quality-and-reliability/product-longevity.html
30. IIS3DWB ultra wide bandwidth, low noise
3-axes digital vibrometer
30
Pin2pin compatible with ISM330x/LSM6DSx
devices
LGA-14 2.5x3mm2
Parameter Value
N. of axis 3-axis
Full Scale [g] ±2/±4/±8/±16
Output i/f Digital: SPI
Bandwidth (-3dB) [kHz] 5
ODR [kHz] 26.7
Noise Density [µg/√Hz] 90 (65 in single axis)
Current Consumption [mA] 1.1
Features
FIFO (3kbyte)
Programmable HP Filter
Interrupts
Temp. Sensor
Embedded Self Test
Operating Temp [°C] -40 ; +105
Operating Voltage [V] 2.1 ÷ 3.6
Package [mm3] LGA 2.5x3x0.83 14Lead
31. IIS3DWB KPIs for condition monitoring
31
#1 Wide & Flat measurement bandwidth
#2 Flat freq. response, Sharp out of band roll-off, No aliasing
#3 Low noise levels
#4 Stable thermal behavior over extended temperature range
32. • Frequency response:
• Bandwidth
• frequency response flatness in pass band
• attenuation in stop band (to avoid frequency aliasing)
• Noise density
• Full Scale and number of axis
• Operating temperature range
• Power consumption (for wireless sensor nodes)
• Interface (analog / digital)
IIS3DWB frequency response
32
Freq. Resp ±5%
+3dB
-3dB
Resonance Freq
Example of a typical Frequency response of
an Analog Accelerometer with the relevant features.
Frequency response of ST’s IIS3DWB Digital Accelerometer, no external
component needed for A2D conversion, nor for frequency response equalization
Freq. Resp ±5% -3dB
KPI for Accelerometer for Vibration Monitoring
33. • The output of the ADC converter is filtered with a digital low pass filter LPF1 to
ensure the intended sensor’s frequency response:
IIS3DWB filtering chain
33
Frequency response determined by CAD simulation – at the output of LPF1
Frequency response at the output of LPF1
#2 KPI
Sharp out of band roll-off
(>90 dB/dec)
Attenuation >70 dB at
frequencies higher than ODR
6.3kHz
#1 KPI
Wide & Flat measurement
bandwidth 5kHz (6.3kHz
simulated)
34. Noise density
34
#3 KPI
IIS3DWB recalculated velocity resolution in mm/s, with respect to the sensor noise is typically ~0.05
mm/s, which is much better than requirement (1.4 - 2.8 mm/s RMS velocity limit) for medium sized
motors, in rigid support in Zone B of ISO10816-3
35. Sensitivity drift vs temperature
35
#4 KPI
IIS3DWB sensitivity drift over temperature range is negligible. Zero g offset drift over temperature is
not important for a vibrometer (DC component is not interesting)
36. • Analog bottom port single ended microphone with 63dB SNR min and low distortion with AOP of
132dB
• Low power and with ultra flat frequency response: roll off @ 15Hz
MP23ABS1
36
High-accuracy, ultra-low-power, 3-axis digital output magnetometer
15Hz
• Perfect companion of earbuds, active-noise canceling headsets or application based on noise
cancelling algorithms
37. Key features
• Operating temperature -40 °C to +125 °C
• Temperature accuracy: typ. ± 0.25 °C /max: ± 0.5 °C (-10 °C to
+60 °C)
• Supply voltage: 1.5V to 3.6 V
• Factory calibrated
• One-shot mode for power saving (1.75 µA)
• 2 x 2 x 0.50 mm 6-lead UDFN package with exposed pad down
New product released: STTS22H
37
Evaluation
• STEVAL-MKI200V1K (DIL24
board) +STEVAL-MKIGIBV1 adapter
board
• STEVAL-MKI109V3 motherboard
• Unico GUI graphical user interface
Applications
• Wearable devices
• Portable consumer devices
• Smartphones
• Home appliances
• Asset and goods tracking
+ +
Integrated Ultra-Low Power, High Accuracy Temperature Sensor
39. IPS family for smart industry
Intelligent Power Switches and Industrial Connectivity Devices
Industrial Connectivity
IPS Multiple Channels & Single Channel for SiL
Galvanic Isolated IPS
HighandLow-sideSwitches
39
40. IPS family
Why Industrial IPS? Compact, Robust & Reliable ….
External component count
Versatile
High Reliability & Safety
EMC proof
Diagnostics
on chipSelf Diagnostic:
Open Load in ON and OFF state, Under-
Voltage; Thermal shut-down ...
Minimized external components
Galvanic Isolation …
Capability to drive any type of loads:
Capacitors, Big inductors, Resistors, Lamps……
Designed to be compliant with all the
severe industrial IEC Norms in terms of
electromagnetic compatibility: Surge,
Burst, ESD contact/air (IEC 61000-4-5/4/2)
Integrated Approach, fully protected:
Over-load, Short Circuit, Over-Voltage, Over
Temperature (junction/case) ..
Energy Saving
Very low conduction losses
Low Rds(on) values of the Power Stage
40
41. IPS targeted applications
Focus on Industrial Applications
• Factory Automation / CNC / Robotics
• Programmable Logic Controller
• Programmable Automation Controller
• Distributed I/O modules
• Process Instrumentation
• Industry Machines
• Vending M.
• Sewing M. (Textile)
• Motor Drives
• Servo Drives / Motor Break
• Frequency Inverters
• Additional I/Os for sensors
& actuators
• Agricultural Systems & Vehicles
• Hydraulics/pneumatics control
(due to 24V supply system)
• Green Energy Applications
• Windmills (auxiliary functions)
• Building Automation
• Lighting/ Alarms / Security systems
Focus apps Other apps to address
41
42. Automation system architecture
IOCPU
Industrial Ethernet
Industrial
Internet of Things
IO
Connectivity
101011
101011
IO IO IO
Distributed IO modules
IO-Link
Human Machine Interface
RFIOIO
Analog:
4-20mA,
0-10V
±10V…
• Proximity, Temperature,
pressure, flow, pH…
Sensing
Actuation
• Valves, pumps, lamps,
relays, contactors…
Digital:
HART,
Binary 24V,
IO-Link
Industrial PC
IPC
Safety Relays,
Circuit Breakers
42
44. Galvanic isolation – where & why?
44
Protected environment Harsh environment
• Where
• At most PLC I/O modules
• Between the backplane bus ASIC
and I/O circuits (IPS, CLT)
• Can be embedded in ASIC or I/O circuits
Process interface
ASIC Digital
Outputs
ST IPS
Memory
Backplane interface
Power supply
+24VDC
Actuators
Backplane
communication
EMC
Disturbance
PLC Digital
Output Module
CPU
• Why
• To guarantee separation of power supplies for
different module peripheries
• To avoid ground current loops
• To protect CPU and other modules against
EMC disturbances
45. ISO8200B/BQ
45
Driving up to 8 channels with galvanic isolation
Low power dissipation
Synchronous mode
Extended temperature range
RF communication
Embedded galvanic isolation
Compact QFN
9 x 11mm
KEY APPLICATIONS
Industrial automation:
• Programmable logic control
• Industrial PC peripheral input/output
• Numerical control machines
• Drivers for all types of loads
Saving BOM and costs with more performance and reliability
46. ISO8200 B / AQ / BQ - octal HSD (110mΩ)
Embedded Galvanic Isolation
ISO8200B
PowerSO-36
ISO8200AQ + BQ in tiny QFN
9 x 11 mm only!
Power circuitsSignal circuits
Glass
isolation
VCC CLAMP
OUTPUT CLAMP
VDD
SDI
/CS
/CLK
SDO
PGOOD
FAULT
GNDDD
VCC
OUT1
GNDCC
LOGIC
POWER
MANAGEMENT
LOGIC
UNDERVOLTAGE
LOCKOUT
CURRENT LIMITATION
CASE TEMP
DETECTION
JUNCTION TEMP
DETECTION
8x
RPD OUT8
…
OUT_EN
Ideal for factory
automation
PLCs, CNCs,
industrial robotics
46
48. Intelligent Power Switching in Factory Automation
Parameters of Intelligent Power Switch (IPS) driven by industrial standard IEC 61131-2*
60V supply overvoltage often required for SIL
GND
R ~ 48Ω
L ~ 1.15H
C ~ 30µF
OUT
+24V (-15%/+20%)
Control Vcc, 5V or (3V3)
RPD
Driver
Tjunction
-40°C to +125°C
Example of loads:
Lamps, relays, contactors,
selenoid valves…
Fast switch-off of inductance
with active clamp VCLAMP
Serial/parallel interface
& Diagnostics
All outputs must go in OFF state
@ GND disconnection
Power MOSFETs fully protected
(overload, short-circuit, EMC…)
* Typical loads for 0.5A rated OUT
(*) IEC 61131 is an IEC standard for Programmable
Logic Controllers. Part 2: Equipment requirements
and tests
Electromagnetic immunity requirements:
48
Type of disturbance Related standard Target immunity
Burst IEC 61000-4-4 ±4kV
Surge IEC 61000-4-5 ±2kV
ESD (contact/air) IEC 61000-4-2 8kV / 16kV
RF IEC 61000-4-6 3V @ 80kHz to 150MHz
49. Intelligent Power Switches – Portfolio
• For High and Low-side configurations, can drive any industrial load (R,L,C)
Quad Channels
OutputCurrent/Channel(A)
IPS161H, IPS161HF*
L6375, L6377
TDE1707, TDE1897,
TDE1898
IPS160H, IPS160HF*
IPS1025H*, IPS1025HF*
VN540, VN751, L6370
VNI2140J
VNQ860
L6374
IPS4260L (Low Side)
VNI4140K
L6376
VN330SP, VN340SP
VNI4140K-32
VN340SP-33
VN808(CM), VNI8200XP
ISO8200AQ, ISO8200B
ISO8200BQ
VN808(CM)-32
VNI8200XP-32
TDE1708, TDE3247
TDE1787, TDE1747
Single Channel Dual Channels Octal Channels
IPS1025H-32* IPS2050H-32*
IPS2050H*
(*) In Development
≤ 60V
Isolated
4 A
2 A
1 A
0.5 A
<0.5 A
51. Factory Automation…yesterday
51
Typical Application Environment
Various transfer
principles
Analog information
transfer
Low configuration
options
No diagnostics
• Temperature, pressure, flow,
proximity…
IOCPU
IO
Sensing
Actuation
Industrial Ethernet
101011
• Valves, pumps, lamps,
relays, contactors…
4-20mA 0-10V
Fieldbus
4-20mA
DIN mounting Limited modularity
(system upgrade)
Sensitivity to noise
Difficult to modify/adapt
the system
Painful maintenance
(long downtimes!)
System attributes:
SIO, ASi...
52. Factory automation tomorrow with IO-Link
52
IOCPU IO-Link IO-Link
IoT
Industrial Ethernet
IO
Fieldbus
101011
101011
101011
Unified access to
sensors & actuators
Digital information
transfer
Bidirectional
communication
Simplified & modular
system structure
Reliable communication
Allows use of smart
sensors & actuators!
Easy monitoring
& system diagnostics
(minimized downtimes)
System attributes:
• Temperature, pressure, flow,
proximity…
Sensing
Actuation
• Valves, pumps, lamps,
relays, contactors…
Typical Application Environment
53. IO-LINK technology
53
Market data
Source: http://www.io-link.com/
Installed IO-Link Nodes in the field
• Position (especially optical)
• Pressure
• Flow
• Level
• Temperature
• Proximity
Key Sensor Types implementing
IO-Link is mostly spread in sensors
Long-term TAM for IO-Link: to target 100M units / year for
Devices + another 100M units for Masters (world-wide)
54. Powered by STMicroelectronics
54
Typical Application Environment
L6360
I/Q
L+
L-
C/ QiSTM32
C/ Qo
UART,
I2C
L6362A
GND
L+
I/Q
OUTL STM32
OUTH
GPIO
~
~
~
Sensor / Actuator - DeviceController - Master
L+
L-
C/Q
Speed up to
230.4kBd
Three-wire cable
up to 20m
• First standardized technology for digital communication with sensors and actuators:
• IEC 61131-9
• 3-wire point-to-point digital communication compatible with the conventional binary sensors & actuators (Standard IO)
including the cable material and connectors!
IO-Link Stack: Available at partner company www.teconcept.de