2015 12-09-Lass移植LinkIt 7688 Duo 初步規劃與研究-v1MAKERPRO.cc
This document discusses the Linkit 7688 Duo, a board that combines an Arduino compatible microcontroller with an ARM Linux computer. It can run code written for Arduino on the microcontroller side using the Arduino IDE, while also running Python, Node.js, or C code on the Linux side. This allows accessing sensors and devices via the microcontroller from scripts running on Linux.
This document describes PlaatProtect, an open source home security and automation system built using a Raspberry Pi. The system uses various sensors like IR detectors, webcams, and smoke/fire detectors connected over Z-Wave and Zigbee mesh networks to detect movement and fires. It activates alarms, lights, and notifications in different scenarios like home, sleep, away. The system's features include a web GUI, motion recording, and push/email alerts. It integrates with smart home devices from Philips, Google, and others for lighting and fire protection control.
The iPORT NTx-GigE Embedded Video Interface is a hardware product that allows manufacturers to easily integrate GigE Vision 2.0 video connectivity into cameras and imaging systems. It is a compact and low power device that complies with GigE Vision and GenICam standards to ensure interoperability. It supports area scan and line scan modes with throughput up to 1 Gbps and includes features like a 128MB frame buffer and Power over Ethernet. Pleora provides related products and tools to help manufacturers design prototypes and products using the iPORT NTx-GigE.
This document provides an overview of Sigfox and its technology for IoT connectivity. Sigfox uses an ultra-narrowband radio protocol to transmit small amounts of data over long ranges with low power consumption. It operates on unlicensed spectrum and can connect battery-powered devices globally for years on a single battery. Sigfox focuses on simple connectivity for independent devices that only need to transmit small amounts of useful data infrequently. Its network is accessible through REST APIs to view and receive device messages.
This document discusses Sigfox, a company that has developed a radio communication protocol and operates a global IoT network. Sigfox does not sell hardware components but instead focuses on connectivity. Their network uses unlicensed bands to allow two-way communication between devices in an efficient and simple way. Sigfox envisions connecting billions of devices by 2025 for a variety of use cases like logistics, smart cities, maintenance and agriculture. They take an open hardware approach and offer low-cost subscriptions to their global network.
- SIGFOX is a global network operator focused on enabling low-power and low-bandwidth Internet of Things (IoT) devices through its proprietary radio communication technology.
- It aims to provide long range connectivity over distances of a few kilometers in cities and 40km in rural areas using little power, allowing battery-powered devices to operate for years on a single charge.
- At a hackathon, participants are provided with an Arduino shield called Akene to connect devices to the SIGFOX network using Telecom Design modules and send simple messages of up to 12 bytes every 140 times per day through basic AT commands.
This document discusses using .NET for Internet of Things (IoT) applications. It describes how IoT devices expose pins that can be programmed using electrical pulses and common IoT protocols. It provides an overview of the goals and capabilities for .NET IoT, including support for Azure IoT services, ARM architectures, Docker images, and device protocols. Libraries for GPIO, device bindings, and supported device types are mentioned. Sample code for blinking an LED using GPIO is shown.
The document discusses Internet of Things (IoT) support for .NET Core/5/6. It provides an overview of the goals for .NET in IoT, the capabilities that are available such as integration with Azure services and support for device protocols and libraries. It also includes examples of code samples and supported device types and sensors.
2015 12-09-Lass移植LinkIt 7688 Duo 初步規劃與研究-v1MAKERPRO.cc
This document discusses the Linkit 7688 Duo, a board that combines an Arduino compatible microcontroller with an ARM Linux computer. It can run code written for Arduino on the microcontroller side using the Arduino IDE, while also running Python, Node.js, or C code on the Linux side. This allows accessing sensors and devices via the microcontroller from scripts running on Linux.
This document describes PlaatProtect, an open source home security and automation system built using a Raspberry Pi. The system uses various sensors like IR detectors, webcams, and smoke/fire detectors connected over Z-Wave and Zigbee mesh networks to detect movement and fires. It activates alarms, lights, and notifications in different scenarios like home, sleep, away. The system's features include a web GUI, motion recording, and push/email alerts. It integrates with smart home devices from Philips, Google, and others for lighting and fire protection control.
The iPORT NTx-GigE Embedded Video Interface is a hardware product that allows manufacturers to easily integrate GigE Vision 2.0 video connectivity into cameras and imaging systems. It is a compact and low power device that complies with GigE Vision and GenICam standards to ensure interoperability. It supports area scan and line scan modes with throughput up to 1 Gbps and includes features like a 128MB frame buffer and Power over Ethernet. Pleora provides related products and tools to help manufacturers design prototypes and products using the iPORT NTx-GigE.
This document provides an overview of Sigfox and its technology for IoT connectivity. Sigfox uses an ultra-narrowband radio protocol to transmit small amounts of data over long ranges with low power consumption. It operates on unlicensed spectrum and can connect battery-powered devices globally for years on a single battery. Sigfox focuses on simple connectivity for independent devices that only need to transmit small amounts of useful data infrequently. Its network is accessible through REST APIs to view and receive device messages.
This document discusses Sigfox, a company that has developed a radio communication protocol and operates a global IoT network. Sigfox does not sell hardware components but instead focuses on connectivity. Their network uses unlicensed bands to allow two-way communication between devices in an efficient and simple way. Sigfox envisions connecting billions of devices by 2025 for a variety of use cases like logistics, smart cities, maintenance and agriculture. They take an open hardware approach and offer low-cost subscriptions to their global network.
- SIGFOX is a global network operator focused on enabling low-power and low-bandwidth Internet of Things (IoT) devices through its proprietary radio communication technology.
- It aims to provide long range connectivity over distances of a few kilometers in cities and 40km in rural areas using little power, allowing battery-powered devices to operate for years on a single charge.
- At a hackathon, participants are provided with an Arduino shield called Akene to connect devices to the SIGFOX network using Telecom Design modules and send simple messages of up to 12 bytes every 140 times per day through basic AT commands.
This document discusses using .NET for Internet of Things (IoT) applications. It describes how IoT devices expose pins that can be programmed using electrical pulses and common IoT protocols. It provides an overview of the goals and capabilities for .NET IoT, including support for Azure IoT services, ARM architectures, Docker images, and device protocols. Libraries for GPIO, device bindings, and supported device types are mentioned. Sample code for blinking an LED using GPIO is shown.
The document discusses Internet of Things (IoT) support for .NET Core/5/6. It provides an overview of the goals for .NET in IoT, the capabilities that are available such as integration with Azure services and support for device protocols and libraries. It also includes examples of code samples and supported device types and sensors.
This document discusses Internet of Things (IoT) physical devices and endpoints. It begins by defining IoT devices as objects connected to the Internet that can send and receive data. Basic components of an IoT device are then outlined, including sensing, actuation, communication, and data processing. The Raspberry Pi is presented as an exemplary IoT device, noting its low cost, credit card size, Linux operating system, and interfaces for connecting sensors and actuators. Programming the Raspberry Pi using Python is also mentioned. Finally, some other examples of IoT devices are listed.
This document provides an overview of the NIO100 IoT Gateway product from NEXCOM. It describes the key features of the NIO100 including its Intel Quark processor, support for multiple communication protocols, embedded IoT Studio gateway builder software, rugged design, and modular connectivity options. It also outlines several example applications and provides marketing support services available for the NIO100 product.
This document summarizes an Arduino workshop about using the Arduino MKRFOX board to connect to the Sigfox network. It introduces Nicolas Lesconnec, provides resources for the Sigfox and Arduino platforms, and outlines the steps to set up an Arduino MKRFOX board, send data to the Sigfox backend, visualize data, set up callbacks, and enable bi-directional communication using downlinks.
This document summarizes an advanced Sigfox workshop covering topics like downlink callbacks, event monitoring, geolocation callbacks, and using AT commands with the Xkit shield. It provides useful resources and contact information for Aurelien Lequertier and Nicolas Lesconnec. The workshop includes demonstrations of configuring downlink callbacks, monitoring for breaks in message sequences, geolocation callbacks, using IFTTT for advanced callbacks, and sending AT commands to the Xkit shield.
Colloque Enseignants IUT GEII (Génie Electronique et Informatique Industrielle)
Premiers pas sur le réseau Sigfox
* Utilisation d'une carte Arduino MKRFOX 1200 pour envoyer de premiers messages sur le réseau
* Utilisation d'une plateforme IoT pour recevoir et visualiser les données
This document provides an overview of Sigfox and how to use it for IoT applications. Sigfox is a wireless network designed specifically for low-power IoT devices. It allows devices to send small amounts of data using very little power. The document discusses Sigfox basics like its global network, security, energy efficiency, and long range. It also covers how to communicate with Sigfox modules, example payloads, and developing applications using the Sigfox backend and callbacks. The workshop portion involves sending "hello world" messages and handling downlink responses using Arduino boards and code samples.
This document summarizes a Sigfox workshop on using the Thinxtra Xkit to connect devices to the Sigfox network. It provides instructions on contributing code samples and experiments back to the community, registering devices on the Sigfox backend, sending "hello world" messages from an Arduino, and setting up callbacks and downlinks to receive data and send responses to devices.
Mikael Falkvidd IoT - Stena AB Faster ForwardMikael Falkvidd
Tech afternoon - IoT, Mikael Falkvidd, Independent IoT consultant
The challenge is no longer technology or economy- it´s for us to imagine useful scenarios
Everything that can be connected will be connected and Gartner predicts that 2020 we will have 20 Billion connected devices, others say 50. We need to learn and explore the future business value.
Mikael has a MsC in computer communications. He has experience from Ericsson and OP5 but has also been a freelancer writer for a Swedish computer magazine where he had to stay relevant and learn about the latest and most exciting technologies.
[Feb 2020] Cours IoT - CentraleSupelec - Master SIONicolas Lesconnec
This document provides an overview of Internet of Things (IoT) and Sigfox's role in IoT connectivity. It introduces Sigfox, describing it as the world's largest 0G network for connecting IoT devices. It outlines key aspects of Sigfox technology, including its ultra-narrowband radio protocol, global network coverage, security features, and integration with cloud platforms. Use cases for supply chain tracking are presented. The document concludes with a discussion of building IoT products and deploying sensors using Sigfox.
The document introduces the NIO100 Demo Box, which is designed to:
1. Demonstrate a live end-to-end IoT scenario simulating sensors connecting to the cloud through an IoT gateway.
2. Showcase how NEXCOM's IoT Studio gateway builder can quickly complete sensor data integration tasks.
3. Provide an easy, affordable, and portable demo setup for showcasing IoT solutions to customers and developers.
The demo box simulates a water treatment plant monitoring system using switches to represent sensor data, which is sent to the IBM Bluemix cloud platform via a NEXCOM IoT gateway and NIO100 device. The dashboard then visualizes the simulated sensor
IoT Workshop with Sigfox & Arduino - Copenhagen Business SchoolNicolas Lesconnec
Hands On IoT Workshop, using an Arduino MKRFOX board
(March 2019)
First steps on the Sigfox network :
* Send first messages
* Use the Sigfox Cloud to check incoming data
* Set up first callbacks to push data
* Complex frame handling
* Downlink communication
* Event monitoring
This ppt contain the information about KISMET which is one of the network analyzer in mobile communication. I have searched this and made it with great hard work so take advantage. And comment on this. This much information is not fully available on the net. So enjoyyy.
The document describes a smart home solution that allows centralized control of various smart home devices through a universal gateway. The solution uses a Raspberry Pi gateway connected to Z-Wave, Zigbee, and WiFi devices to control lighting, security, climate, media, and other functions. It is designed to work with different device brands and protocols to provide a flexible and scalable smart home system without vendor lock-in. The gateway runs open-source software like OpenHAB to integrate devices and create automation rules for comfort, energy savings, and security.
This document provides information about a hackathon hosted by Sigfox to find the best use of their low-power wireless network. It describes the Sigfox network which uses a proprietary protocol to allow battery-powered devices to transmit small amounts of data over long ranges with very low power consumption. The best project will win integration into Sigfox's startup program and access to their ecosystem and experts. The document also provides details on Sigfox's global network coverage and the capabilities of communicating with devices via their cloud platform.
Sigfox discovery workshop using an Arduino MKRFOX board.
* Getting started with the MKRFOX
* Getting started with the Sigfox Cloud
* First messages over the Sigfox network
* Downlink feature
* Callback settings
* Events configuration
* IFTTT demo
* API configuration
Session held in Cape Town on November 8th, 2017
Overview of the Sigfox Technology & Services
Used as support for a webinar to Sigfox partners (Universities, Developers & Startups) : https://www.youtube.com/watch?v=I1PaypiGO4Q
IoT Implementation of Sensor Data Acquisition in Surveillance Applications - ...Arun Joseph
This document describes an IoT-based surveillance system that uses sensors to acquire data. A Raspberry Pi is used as a gateway device connected to sensors on a Sensor Tag to measure environment variables. The sensor data is published to the cloud using MQTT protocol and can be monitored remotely. A camera is also used to stream visual data to a server.
15 minutes intro to the Sigfox service, before a Bosch presentation of their Sigfox usecases & implementation
Presentation made during Bosch Connected Experience (March 2017, Berlin)
This document discusses Yoonseok Hur, a PhD and IoT evangelist. It provides biographical details on Hur's background in software development and technical sales at IBM. It then covers topics related to Hur's home IoT project, including the technologies used (Esp8266, Raspberry Pi, MQTT, etc.), Amazon Alexa and Apple Homekit integration, and 3D printing designs. Useful links are also provided for IoT development resources, online circuit design tools, programming guides, and more.
AKCP is a manufacturer of networked monitoring sensors established in 1981 with over 100 employees. They provide intelligent monitoring solutions for environmental, security, power and access control across enterprises. Their main products include the SensorProbe, SecurityProbe and sensor modules that integrate with network management systems and provide features like notifications, logging, graphing and remote monitoring. The document provides details on several SensorProbe and SecurityProbe models that vary in the number of sensor and dry contact ports.
This document discusses Internet of Things (IoT) physical devices and endpoints. It begins by defining IoT devices as objects connected to the Internet that can send and receive data. Basic components of an IoT device are then outlined, including sensing, actuation, communication, and data processing. The Raspberry Pi is presented as an exemplary IoT device, noting its low cost, credit card size, Linux operating system, and interfaces for connecting sensors and actuators. Programming the Raspberry Pi using Python is also mentioned. Finally, some other examples of IoT devices are listed.
This document provides an overview of the NIO100 IoT Gateway product from NEXCOM. It describes the key features of the NIO100 including its Intel Quark processor, support for multiple communication protocols, embedded IoT Studio gateway builder software, rugged design, and modular connectivity options. It also outlines several example applications and provides marketing support services available for the NIO100 product.
This document summarizes an Arduino workshop about using the Arduino MKRFOX board to connect to the Sigfox network. It introduces Nicolas Lesconnec, provides resources for the Sigfox and Arduino platforms, and outlines the steps to set up an Arduino MKRFOX board, send data to the Sigfox backend, visualize data, set up callbacks, and enable bi-directional communication using downlinks.
This document summarizes an advanced Sigfox workshop covering topics like downlink callbacks, event monitoring, geolocation callbacks, and using AT commands with the Xkit shield. It provides useful resources and contact information for Aurelien Lequertier and Nicolas Lesconnec. The workshop includes demonstrations of configuring downlink callbacks, monitoring for breaks in message sequences, geolocation callbacks, using IFTTT for advanced callbacks, and sending AT commands to the Xkit shield.
Colloque Enseignants IUT GEII (Génie Electronique et Informatique Industrielle)
Premiers pas sur le réseau Sigfox
* Utilisation d'une carte Arduino MKRFOX 1200 pour envoyer de premiers messages sur le réseau
* Utilisation d'une plateforme IoT pour recevoir et visualiser les données
This document provides an overview of Sigfox and how to use it for IoT applications. Sigfox is a wireless network designed specifically for low-power IoT devices. It allows devices to send small amounts of data using very little power. The document discusses Sigfox basics like its global network, security, energy efficiency, and long range. It also covers how to communicate with Sigfox modules, example payloads, and developing applications using the Sigfox backend and callbacks. The workshop portion involves sending "hello world" messages and handling downlink responses using Arduino boards and code samples.
This document summarizes a Sigfox workshop on using the Thinxtra Xkit to connect devices to the Sigfox network. It provides instructions on contributing code samples and experiments back to the community, registering devices on the Sigfox backend, sending "hello world" messages from an Arduino, and setting up callbacks and downlinks to receive data and send responses to devices.
Mikael Falkvidd IoT - Stena AB Faster ForwardMikael Falkvidd
Tech afternoon - IoT, Mikael Falkvidd, Independent IoT consultant
The challenge is no longer technology or economy- it´s for us to imagine useful scenarios
Everything that can be connected will be connected and Gartner predicts that 2020 we will have 20 Billion connected devices, others say 50. We need to learn and explore the future business value.
Mikael has a MsC in computer communications. He has experience from Ericsson and OP5 but has also been a freelancer writer for a Swedish computer magazine where he had to stay relevant and learn about the latest and most exciting technologies.
[Feb 2020] Cours IoT - CentraleSupelec - Master SIONicolas Lesconnec
This document provides an overview of Internet of Things (IoT) and Sigfox's role in IoT connectivity. It introduces Sigfox, describing it as the world's largest 0G network for connecting IoT devices. It outlines key aspects of Sigfox technology, including its ultra-narrowband radio protocol, global network coverage, security features, and integration with cloud platforms. Use cases for supply chain tracking are presented. The document concludes with a discussion of building IoT products and deploying sensors using Sigfox.
The document introduces the NIO100 Demo Box, which is designed to:
1. Demonstrate a live end-to-end IoT scenario simulating sensors connecting to the cloud through an IoT gateway.
2. Showcase how NEXCOM's IoT Studio gateway builder can quickly complete sensor data integration tasks.
3. Provide an easy, affordable, and portable demo setup for showcasing IoT solutions to customers and developers.
The demo box simulates a water treatment plant monitoring system using switches to represent sensor data, which is sent to the IBM Bluemix cloud platform via a NEXCOM IoT gateway and NIO100 device. The dashboard then visualizes the simulated sensor
IoT Workshop with Sigfox & Arduino - Copenhagen Business SchoolNicolas Lesconnec
Hands On IoT Workshop, using an Arduino MKRFOX board
(March 2019)
First steps on the Sigfox network :
* Send first messages
* Use the Sigfox Cloud to check incoming data
* Set up first callbacks to push data
* Complex frame handling
* Downlink communication
* Event monitoring
This ppt contain the information about KISMET which is one of the network analyzer in mobile communication. I have searched this and made it with great hard work so take advantage. And comment on this. This much information is not fully available on the net. So enjoyyy.
The document describes a smart home solution that allows centralized control of various smart home devices through a universal gateway. The solution uses a Raspberry Pi gateway connected to Z-Wave, Zigbee, and WiFi devices to control lighting, security, climate, media, and other functions. It is designed to work with different device brands and protocols to provide a flexible and scalable smart home system without vendor lock-in. The gateway runs open-source software like OpenHAB to integrate devices and create automation rules for comfort, energy savings, and security.
This document provides information about a hackathon hosted by Sigfox to find the best use of their low-power wireless network. It describes the Sigfox network which uses a proprietary protocol to allow battery-powered devices to transmit small amounts of data over long ranges with very low power consumption. The best project will win integration into Sigfox's startup program and access to their ecosystem and experts. The document also provides details on Sigfox's global network coverage and the capabilities of communicating with devices via their cloud platform.
Sigfox discovery workshop using an Arduino MKRFOX board.
* Getting started with the MKRFOX
* Getting started with the Sigfox Cloud
* First messages over the Sigfox network
* Downlink feature
* Callback settings
* Events configuration
* IFTTT demo
* API configuration
Session held in Cape Town on November 8th, 2017
Overview of the Sigfox Technology & Services
Used as support for a webinar to Sigfox partners (Universities, Developers & Startups) : https://www.youtube.com/watch?v=I1PaypiGO4Q
IoT Implementation of Sensor Data Acquisition in Surveillance Applications - ...Arun Joseph
This document describes an IoT-based surveillance system that uses sensors to acquire data. A Raspberry Pi is used as a gateway device connected to sensors on a Sensor Tag to measure environment variables. The sensor data is published to the cloud using MQTT protocol and can be monitored remotely. A camera is also used to stream visual data to a server.
15 minutes intro to the Sigfox service, before a Bosch presentation of their Sigfox usecases & implementation
Presentation made during Bosch Connected Experience (March 2017, Berlin)
This document discusses Yoonseok Hur, a PhD and IoT evangelist. It provides biographical details on Hur's background in software development and technical sales at IBM. It then covers topics related to Hur's home IoT project, including the technologies used (Esp8266, Raspberry Pi, MQTT, etc.), Amazon Alexa and Apple Homekit integration, and 3D printing designs. Useful links are also provided for IoT development resources, online circuit design tools, programming guides, and more.
AKCP is a manufacturer of networked monitoring sensors established in 1981 with over 100 employees. They provide intelligent monitoring solutions for environmental, security, power and access control across enterprises. Their main products include the SensorProbe, SecurityProbe and sensor modules that integrate with network management systems and provide features like notifications, logging, graphing and remote monitoring. The document provides details on several SensorProbe and SecurityProbe models that vary in the number of sensor and dry contact ports.
Peripheral Programming using Arduino and Python on MediaTek LinkIt Smart 7688...MediaTek Labs
Want to add Wi-Fi to your IoT project? This 30 minute webinar, presented by technical consultant Ajith KP, demonstrated how to program (using Arduino and Python) for peripheral sensors connected to the MediaTek LinkIt Smart 7688 Duo’s microcontroller and how to communicate between the microcontroller and the MT7688 SOC.
Three ways to undertake the peripheral programming for the MediaTek LinkIt Smart 7688 Duo were covered:
1) Using a primitive UART connection
2) Using the Firmata protocol
3) Using the Arduino Yun Bridge Library
A recording of the live event can be found at http://home.labs.mediatek.com/technical-mediatek-linkit-smart-7688-webinar-recording-available/
Internet of things - The Present & The Futureiotians
The document provides an overview of the Internet of Things (IoT). It defines IoT as connecting "things" like sensors and devices to the internet. It describes the basic IoT architecture including hardware components like microcontrollers, sensors and connectivity modules. It also discusses software requirements like operating systems, communication protocols and front-end technologies to integrate IoT solutions. Finally, it highlights the growth of IoT and examples of IoT products in different domains like smart homes, fitness and more.
In this free 30 minute live webinar, followed by Q&A, you'll learn all about the new MediaTek LinkIt Smart 7688 development platform, the open-source Wi-Fi platform for a more connected world.
The MediaTek LinkIt™ Smart 7688 development platform enables rapid development of Wi-Fi enabled products for the smart home and office, such as advanced IP cameras, surveillance devices, and smart appliances.
In this webinar you will learn about:
• The architecture and capabilities of the MediaTek LinkIt Smart 7688
• How to undertake rapidly develop of Wi-Fi enabled products using Arduino, Python, Node.js or C/C++
Presented by Ajith KP, technical consultant, MediaTek Labs.
Checkout LinkIt Smart 7688 at http://labs.mediatek.com/7688
Overview of the Intel® Internet of Things Developer KitIntel® Software
The document provides an overview of the Intel Internet of Things Developer Kit. It discusses the various hardware kits available, including the Intel Galileo, Edison and various sensor kits. It also describes the software tools and libraries, cloud services, and the overall Intel IoT developer program which includes roadshows, online communities and support for developers.
The document discusses Internet of Things (IoT) topics including an introduction to IoT concepts and components, common IoT architectures, communication protocols like MQTT, embedded platforms like the ESP8266, and examples of IoT applications in areas such as smart farming, logistics, and environmental monitoring. It also provides an overview of the speaker's credentials and experience with embedded systems and microcontrollers and includes a demonstration of an IoT development board.
Republic of IoT 2018 - ESPectro32 and NB-IoT WorkshopAlwin Arrasyid
This document discusses NB-IoT and an ESPectro32 workshop. It introduces NB-IoT as a low power wide area network technology for IoT. It describes the ESPectro32 board and how to set up a development environment. It also discusses connecting the ESPectro32 to an NB-IoT backpack module to send telemetry data via NB-IoT networks. Code examples are provided for sending AT commands and communicating with an NB-IoT network using HTTP and MQTT protocols.
The document describes a tutorial for creating an arcade shooter game simulator called Shoot-A-Pi using the Eclipse Kura IoT application framework on a Raspberry Pi. The tutorial will cover setting up the hardware, creating OSGi bundles to interface with sensors and actuators, implementing the game logic, and deploying the bundles to the Raspberry Pi. Attendees will work through building the game over the course of the tutorial session.
The document provides an agenda for an Intel IoT Roadshow meetup in London. The agenda includes an overview of Intel IoT and introductions to the Edison and DevKit from 7:00-7:30PM, an IoT demo based on Edison from 7:30-8:00PM, a creativity session from 8:00-8:30PM, and networking from 8:30PM onward. The meetup will provide information about Intel IoT platforms and development tools.
Introduction to the new MediaTek LinkIt™ Development Platform for RTOSMediaTek Labs
The new MediaTek LinkIt™ Development Platform for RTOS is based on ARM Cortex-M4 MCU architecture and provides leading features for the creation of connected appliances, home and office automation devices, smart gadgets, and IoT bridges. Supporting a range of chipsets (initially the MediaTek MT7687F), LinkIt for RTOS offers the convenience of a single toolset and common API implemented over a popular RTOS. With this you can achieve economies across a full range of consumer and business IoT devices. The platform consists of a Software Development Kit (SDK), Hardware Development Kits (HDKs), including modules from supply chain partners, and related technical documentation. The first release of the platform supports the MediaTek MT7687F Wi-Fi SOC which has a 192 MHz MCU, 1×1 802.11b/g/n Wi-Fi subsystem, integrated security engine (AES and 3DES/SHA), embedded SRAM/ROM and 2MB flash. The new platform uses FreeRTOS with open-source modules for TCP/IP, SSL/TLS, HTTP (client and server), SNTP, DHCP daemon, MQTT, XML and JSON. Development and debugging is supported by free command line tools, plus a KEIL plug-in.
This document provides information about an IoT workshop hosted by Null Mumbai. It introduces the workshop organizers, Nitesh Malviya and Ganesh Naik, and their backgrounds in security and embedded systems. It then defines IoT and discusses its various components, including physical devices, sensors, networks, and cloud services. The document outlines common processor architectures, operating systems, protocols, and hardware that are used in IoT, such as Arduino, Raspberry Pi, MQTT, and more. It provides examples of how these pieces fit together in an IoT system and references materials for further learning.
This document provides information about hardware, software, and tools included in an Intel IoT developer kit for a hackathon. The kit includes an Intel NUC gateway device running Moon Island Linux, a Grove starter sensor kit that connects to an Arduino 101 board, and Node-RED for visualizing and processing sensor data. It describes the components and their capabilities and provides an example workflow of getting temperature from a Grove sensor, sending it to the cloud, displaying a chart, and triggering alerts if the temperature exceeds a threshold.
NXP FRDM-K64F Platform with ARM mbed Demo - Edinburgh 2016 WorkshopOpen Mobile Alliance
The presentation provides an overview of the mbed ecosystem for developing Internet of Things (IoT) devices. It discusses the mbed Device Connector for connecting devices, transmitting data, and managing devices from the cloud. It also covers mbed TLS for including cryptographic and security capabilities with a minimal code footprint. Examples of ARM Cortex-M microcontrollers that can be used for IoT development on the mbed platform are also provided.
By AWS & Espressif
Learn about Amazon FreeRTOS and the Espressif Systems’ ESP32-DevKitC. Determine how this fits into an IoT solution and look at examples of using cloud services in IoT microcontroller-based devices.
The document provides an overview of the Internet of Things (IoT). It defines IoT as connecting everyday devices to the internet to collect and exchange data. It discusses how IoT works using devices, gateways, cloud platforms and applications. It also describes common IoT domains like smart home, healthcare and transportation. Finally, it discusses IoT devices, boards, platforms and tools as well as example IoT projects.
The document discusses the architecture of IoT systems. It describes the different layers of an IoT architecture including the device layer, network layer, service layer, and content layer. It also discusses basic IoT technologies like big data warehousing, gateways, machine learning, and data analytics. Furthermore, it provides examples of using Packet Tracer software to simulate IoT networks for smart home applications.
NUS-ISS Learning Day 2019-Building IoT solutions with the PiNUS-ISS
This document provides an overview of a hands-on workshop on building IoT solutions with Raspberry Pi. It introduces Raspberry Pi and the GrovePi+ starter kit for connecting sensors. It describes how AWS services like IoT Core and Alexa can be used to build IoT systems. The workshop demonstrates setting up a basic IoT system with Raspberry Pi, testing sensors connected to it, and broadcasting sensor data to the AWS cloud. It aims to help participants understand how to create synergy between sensors, devices, and cloud services to develop health and other applications.
Similar to Geohackathon Technical Briefing slides 27 Nov 2015 (20)
This presentation by Katharine Kemp, Associate Professor at the Faculty of Law & Justice at UNSW Sydney, was made during the discussion “The Intersection between Competition and Data Privacy” held at the 143rd meeting of the OECD Competition Committee on 13 June 2024. More papers and presentations on the topic can be found at oe.cd/ibcdp.
This presentation was uploaded with the author’s consent.
This presentation by OECD, OECD Secretariat, was made during the discussion “Artificial Intelligence, Data and Competition” held at the 143rd meeting of the OECD Competition Committee on 12 June 2024. More papers and presentations on the topic can be found at oe.cd/aicomp.
This presentation was uploaded with the author’s consent.
This presentation by Thibault Schrepel, Associate Professor of Law at Vrije Universiteit Amsterdam University, was made during the discussion “Artificial Intelligence, Data and Competition” held at the 143rd meeting of the OECD Competition Committee on 12 June 2024. More papers and presentations on the topic can be found at oe.cd/aicomp.
This presentation was uploaded with the author’s consent.
1.) Introduction
Our Movement is not new; it is the same as it was for Freedom, Justice, and Equality since we were labeled as slaves. However, this movement at its core must entail economics.
2.) Historical Context
This is the same movement because none of the previous movements, such as boycotts, were ever completed. For some, maybe, but for the most part, it’s just a place to keep your stable until you’re ready to assimilate them into your system. The rest of the crabs are left in the world’s worst parts, begging for scraps.
3.) Economic Empowerment
Our Movement aims to show that it is indeed possible for the less fortunate to establish their economic system. Everyone else – Caucasian, Asian, Mexican, Israeli, Jews, etc. – has their systems, and they all set up and usurp money from the less fortunate. So, the less fortunate buy from every one of them, yet none of them buy from the less fortunate. Moreover, the less fortunate really don’t have anything to sell.
4.) Collaboration with Organizations
Our Movement will demonstrate how organizations such as the National Association for the Advancement of Colored People, National Urban League, Black Lives Matter, and others can assist in creating a much more indestructible Black Wall Street.
5.) Vision for the Future
Our Movement will not settle for less than those who came before us and stopped before the rights were equal. The economy, jobs, healthcare, education, housing, incarceration – everything is unfair, and what isn’t is rigged for the less fortunate to fail, as evidenced in society.
6.) Call to Action
Our movement has started and implemented everything needed for the advancement of the economic system. There are positions for only those who understand the importance of this movement, as failure to address it will continue the degradation of the people deemed less fortunate.
No, this isn’t Noah’s Ark, nor am I a Prophet. I’m just a man who wrote a couple of books, created a magnificent website: http://www.thearkproject.llc, and who truly hopes to try and initiate a truly sustainable economic system for deprived people. We may not all have the same beliefs, but if our methods are tried, tested, and proven, we can come together and help others. My website: http://www.thearkproject.llc is very informative and considerably controversial. Please check it out, and if you are afraid, leave immediately; it’s no place for cowards. The last Prophet said: “Whoever among you sees an evil action, then let him change it with his hand [by taking action]; if he cannot, then with his tongue [by speaking out]; and if he cannot, then, with his heart – and that is the weakest of faith.” [Sahih Muslim] If we all, or even some of us, did this, there would be significant change. We are able to witness it on small and grand scales, for example, from climate control to business partnerships. I encourage, invite, and challenge you all to support me by visiting my website.
Why Psychological Safety Matters for Software Teams - ACE 2024 - Ben Linders.pdfBen Linders
Psychological safety in teams is important; team members must feel safe and able to communicate and collaborate effectively to deliver value. It’s also necessary to build long-lasting teams since things will happen and relationships will be strained.
But, how safe is a team? How can we determine if there are any factors that make the team unsafe or have an impact on the team’s culture?
In this mini-workshop, we’ll play games for psychological safety and team culture utilizing a deck of coaching cards, The Psychological Safety Cards. We will learn how to use gamification to gain a better understanding of what’s going on in teams. Individuals share what they have learned from working in teams, what has impacted the team’s safety and culture, and what has led to positive change.
Different game formats will be played in groups in parallel. Examples are an ice-breaker to get people talking about psychological safety, a constellation where people take positions about aspects of psychological safety in their team or organization, and collaborative card games where people work together to create an environment that fosters psychological safety.
This presentation by Yong Lim, Professor of Economic Law at Seoul National University School of Law, was made during the discussion “Artificial Intelligence, Data and Competition” held at the 143rd meeting of the OECD Competition Committee on 12 June 2024. More papers and presentations on the topic can be found at oe.cd/aicomp.
This presentation was uploaded with the author’s consent.
• For a full set of 530+ questions. Go to
https://skillcertpro.com/product/servicenow-cis-itsm-exam-questions/
• SkillCertPro offers detailed explanations to each question which helps to understand the concepts better.
• It is recommended to score above 85% in SkillCertPro exams before attempting a real exam.
• SkillCertPro updates exam questions every 2 weeks.
• You will get life time access and life time free updates
• SkillCertPro assures 100% pass guarantee in first attempt.
Gamify it until you make it Improving Agile Development and Operations with ...Ben Linders
So many challenges, so little time. While we’re busy developing software and keeping it operational, we also need to sharpen the saw, but how? Gamification can be a way to look at how you’re doing and find out where to improve. It’s a great way to have everyone involved and get the best out of people.
In this presentation, Ben Linders will show how playing games with the DevOps coaching cards can help to explore your current development and deployment (DevOps) practices and decide as a team what to improve or experiment with.
The games that we play are based on an engagement model. Instead of imposing change, the games enable people to pull in ideas for change and apply those in a way that best suits their collective needs.
By playing games, you can learn from each other. Teams can use games, exercises, and coaching cards to discuss values, principles, and practices, and share their experiences and learnings.
Different game formats can be used to share experiences on DevOps principles and practices and explore how they can be applied effectively. This presentation provides an overview of playing formats and will inspire you to come up with your own formats.
This presentation by OECD, OECD Secretariat, was made during the discussion “The Intersection between Competition and Data Privacy” held at the 143rd meeting of the OECD Competition Committee on 13 June 2024. More papers and presentations on the topic can be found at oe.cd/ibcdp.
This presentation was uploaded with the author’s consent.
The importance of sustainable and efficient computational practices in artificial intelligence (AI) and deep learning has become increasingly critical. This webinar focuses on the intersection of sustainability and AI, highlighting the significance of energy-efficient deep learning, innovative randomization techniques in neural networks, the potential of reservoir computing, and the cutting-edge realm of neuromorphic computing. This webinar aims to connect theoretical knowledge with practical applications and provide insights into how these innovative approaches can lead to more robust, efficient, and environmentally conscious AI systems.
Webinar Speaker: Prof. Claudio Gallicchio, Assistant Professor, University of Pisa
Claudio Gallicchio is an Assistant Professor at the Department of Computer Science of the University of Pisa, Italy. His research involves merging concepts from Deep Learning, Dynamical Systems, and Randomized Neural Systems, and he has co-authored over 100 scientific publications on the subject. He is the founder of the IEEE CIS Task Force on Reservoir Computing, and the co-founder and chair of the IEEE Task Force on Randomization-based Neural Networks and Learning Systems. He is an associate editor of IEEE Transactions on Neural Networks and Learning Systems (TNNLS).
This presentation by Juraj Čorba, Chair of OECD Working Party on Artificial Intelligence Governance (AIGO), was made during the discussion “Artificial Intelligence, Data and Competition” held at the 143rd meeting of the OECD Competition Committee on 12 June 2024. More papers and presentations on the topic can be found at oe.cd/aicomp.
This presentation was uploaded with the author’s consent.
This presentation by Tim Capel, Director of the UK Information Commissioner’s Office Legal Service, was made during the discussion “The Intersection between Competition and Data Privacy” held at the 143rd meeting of the OECD Competition Committee on 13 June 2024. More papers and presentations on the topic can be found at oe.cd/ibcdp.
This presentation was uploaded with the author’s consent.
This presentation by OECD, OECD Secretariat, was made during the discussion “Pro-competitive Industrial Policy” held at the 143rd meeting of the OECD Competition Committee on 12 June 2024. More papers and presentations on the topic can be found at oe.cd/pcip.
This presentation was uploaded with the author’s consent.
2. We provide integrated hardware, mobile & cloud
infrastructure for anyone to build & develop IoT
products, solution and services
www.espert.co
3. GeoHackPack
• 2 x ESPresso Lite
• 1 x OLED LCD display module 0.96"
• 1 x DHT22 digital temp/humidity sensor
• 1 x Sound sensor
• 1 x PIR sensor
• 1 x Piezo buzzer
• 1 x FTDI-USB cable
• 1 x Breadboard
• 10 x jumper wires (m-m)
• 10 x jumper wires (f-f)
• 1 x Power bank 10,400 mAh
• 1 x RaspberryPi kit (webserver)
11. 1. ESPresso Lite
Program the ESPresso Lite with Arduino IDE with our libraries
to build customised solutions:
• Get data from sensors e.g. Temperature, Humidity,
Sound, Motion
• Display text information
• Beep Sound
• Connect to WiFi
• Send data through WiFi network
12. 2. Local webserver
Local server (Fog Computing) with
built-in:
• MQTT Broker with Web Socket
• MQTT Web Panel
• Freeboard for Data Visualisation
• Node-Red for Data Handling
13. 3. Cloud & Mobile
• ESPert app to log in to the cloud
• ESPresso Lite / Raspberry Pi can send & receive
data from cloud
• MQTT Broker
• Freeboard
• Push Notification Server
14. The Big Picture
LED Switch
Sensor
Display
ESPresso Lite
Sensor Cloud
Mobile
PC
WiFi
Local services (Fog computing)
26. Raspberry Pi as local
server
• WiFi Access Point: @ESPertNN (NN=Group number)
• Password: 123456790
• Setup Router: 192.168.77.1:8080
• IP Address: 192.168.77.1
• MQTT Broker: 192.168.77.1:1883
• MQTT Web Panel: http://192.168.77.1/mqtt
• Freeboard: http://192.168.77.1/freeboard
• Node-Red: http://192.168.77.1:1883
27. Setup Router
Each team will need to connect their RPi router
to 3G Wi-Fi provided on the day of hackathon
28. Cloud
To use the cloud service, go to http://www.espert.io
• MQTT broker: mqtt.espert.io
• MQTT panel: http://www.espert.io/mqtt
• Freeboard: http://www.espert.io/freeboard