Accelerating the Industrial Internet of Things
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Number of Case Studies212
Remotely Monitor Pollution & Gases with Alphasense Industrial IoT Sensors
Remotely Monitor Pollution & Gases with Alphasense Industrial IoT Sensors
To implement air quality monitoring of Ozone / O3, VOCs, Nitrogen Oxides / NO2, Dust Particulates, PM1, PM2.5, PM10.
AEMS: Adroit Environmental Monitoring Framework
AEMS: Adroit Environmental Monitoring Framework
Instead of tags, OEM sensor manufacturers and suppliers work with sensors. Different sensor interfaces can readily be included for overall management. OEM sensor manufacturers wanted a single user interface that can interact with different sensors and manufacturers in a beneficial and efficient manner.
Remote Sensor Monitoring & Fleet Tracking for Industrial Vehicles
Remote Sensor Monitoring & Fleet Tracking for Industrial Vehicles
• To implement fleet tracking with industrial equipment and sensorsHow will you know when a pump on any of your trucks is on or off? Or how many RPMs your mobile pumps are running at? If you’ve got vacuums and/or tanks on your trucks then you want to know what the current status is, how they’ve been used, whether or not they’re due for maintenance, and other information available using Industrial IoT Sensor Solutions with Tools.Valarm.net.
Number of Hardware182
Sensor and Detector Interface
Sensor and Detector Interface
PHOTOELECTRIC SMOKE DETECTOR WITH INTERCONNECT, TIMER, AND LATCHING ALARM INDICATOR
Sensor and Detector Interface
Sensor and Detector Interface
Sensor and Detector Interface 30V Automotive 16-Pin SOIC N Tube
Sensor and Detector Interface
Sensor and Detector Interface
Sensor and Detector Interface 5.5V 20-Pin HSOP EP Tape and Reel
Number of Suppliers333
Biduk Electronic
Biduk Electronic
Biduk is a manufacturer of industrial sensors in China. They have a wide product profile including inductive proximity sensor, high temperature sensor, high pressure sensor, capacitive proximity sensor, photoelectric sensor, area photoelectric sensor,optic fiber amplifier, optic fiber cables and other controllers.
Miramems Sensing Technology Co., Ltd 明皜传感
Miramems Sensing Technology Co., Ltd 明皜传感
Suzhou Minghao Sensing Technology Co., Ltd. is the innovator and pioneer of MEMS sensor technology. Ming Hao sensing mainly engaged in MEMS sensor research and development, design and production, and provide related technical services. The main products are: acceleration sensors, gyroscopes, pressure sensors and magnetic sensors, designed to consumer electronics, automotive electronics, industrial automation and aviation and other fields to provide the necessary products and integration programs.
Shenzhen Ligent Sensor Tech (Ligentcn)
Shenzhen Ligent Sensor Tech (Ligentcn)
Ligentcn is dedicated to develop, manufacture, sell industrial standard sensors and control meters. The company is providing clients with fitting solutions. The main products are load sensors, pressure sensors, control meters and automation systems.
Number of Organizations7
IO-Link
IO-Link
IO-Link is the first standardised IO technology worldwide (IEC 61131-9) for the communication with sensors and also actuators. The powerful point-to-point communication is based on the long established 3-wire sensor and actuator connection without additional requirements regarding the cable material. So, IO-Link is no fieldbus but the further development of the existing, tried-and-tested connection technology for sensors and actuators.
IIoT World
IIoT World
IIoT World™ covers the economic and technological implications of the transformation taking place as IIoT proliferates throughout the enterprise.IIoT World™ combines journalistic coverage with data analysis to expose the stories, players, trends and innovations that shape the IIoT.  
Bluetooth SIG
Bluetooth SIG
The Bluetooth Special Interest Group (SIG) is the body that oversees the development of Bluetooth standards and the licensing of the Bluetooth technologies and trademarks to manufacturers.Created in 1994, Bluetooth® technology was conceived as a wireless alternative to data cables by exchanging data using radio transmissions. The name Bluetooth came from a tenth century Danish King, Harald Blåtand or, in English, Harold Bluetooth. As the story goes, King Blåtand helped unite warring factions in parts of what are now Norway, Sweden and Denmark. Similarly, Bluetooth technology was created as an open standard to allow connectivity and collaboration between disparate products and industries.One of the most popular applications for Bluetooth historically has been wireless audio—headsets and hands-free connectivity in cars to wireless speakers and headphones that stream music from your phone or tablet. This uses a version of Bluetooth called BR/EDR (bit rate/enhanced data rate) that is optimized for sending a steady stream of high quality data (i.e. music) in a power efficient way.With the advent of Bluetooth with its low energy functionality (Bluetooth Smart or BLE), developers are now able to create small sensors that run off tiny coin-cell batteries for months, and in some cases, years. Many of these Bluetooth sensors use so little energy that developers are starting to find ways to use scavenged energy, like solar and kinetic, to power them—a potentially unlimited life from a power perspective. This allows you to find Bluetooth technology in billions of devices today, everything from phones to headsets to basketballs and socks—the use cases are limited only by a developer’s imagination.
Number of Use Cases27
Water Quality and Leakage Monitoring
Water Quality and Leakage Monitoring
Smart Water Monitoring Platforms are ultra-low-power sensor nodes designed for use in rugged environments and deployment in hard-to-access locations. They detect damages in the water supply infrastructure and potential risks to public health or environmental damage in real-time.Water leaks typically go undetected or are responded to only after the event. Therefore, a significant amount of water is lost due to excessive irrigation (only 70% of water supplied is consumed by agriculture).The demand for innovative solutions to enable more efficient use of available water resources, to improve drinking water quality, and improve water resource planning is growing. Due to this, some analysts estimate the global water sector to be worth 1 trillion USD per year by 2025.IoT enables a precise control over water resources data, thus allowing an efficient and optimized management of water companies. Smart water management systems can make a fast and significant improvement to the cost and reliability of water supplies, especially in urban areas and in agriculture.According to various reports as a result of water leakages, pressure or network operations inefficiencies and expensive maintenance, water utilities around the world are collectively losing over $9.5 billion every year and spending $2.5 billion to detect and repair leaks. Of this loss, most of it is attributed to wasted operational expenditures on water production, followed by energy pumping costs and chemical costs of lost water. Adopting smart water management solutions could save utility companies between $7.1 billion and $12.5 billion each year.There are various applications for smart water management such as water leakage detection, watering management through sensors, drinking water quality monitoring, quality control of pools and water reserves, etc. At present, water companies have numerous sensors and devices which are able to provide input for detailed reports about relevant business critical factors – including water temperature, water quality/composition, water pressure, water flow, etc. However, most water companies still lack advanced real-time reporting and prediction capabilities to monitor “changing” factors. As a consequence, there is a focus on real-time data extraction, reporting, visualization.
Structural Health Monitoring (SHM)
Structural Health Monitoring (SHM)
Structural health monitoring is a tool used to ensure the safety and soundness of structures. Structural health monitoring uses an assortment of sensors to collect and analyze data pertaining to any damage or deterioration that a structure may receive over the course of its life. The data that structural health monitoring systems acquire can help its users avoid structural failures.Numerous structural health monitoring systems are available. They differ by cost, quality, purpose and technology. They use many types of structural health monitoring devices and software systems to analyze the data retrieved from the devices. The type of structural health monitoring system that should be used is specific to the structure or structures being monitored.Structural health monitoring is used on structures such as bridges, skyscrapers, stadiums, wind turbines, ships, airplanes and many others.
Precision Farming
Precision Farming
Precision farming enables farmers to increase production (yield), lower their operational costs and economize their applications of chemicals and fertilizers. Precision Conservation Management (PCM) focuses on improving crop yield through the analysis of real-time data from a variety of environmental sensors and other data sources located in commercial crop fields or throughout the enterprise.
Number of Terms99
Semantic Sensor Web (SSW)
Semantic Sensor Web (SSW)
Encoding sensor data with Semantic Web languages enables more expressive representation and analysis.
Application Specific Sensor Nodes (ASSN)
Application Specific Sensor Nodes (ASSN)
Integrating sensors and sensor fusion in a single device, ASSNs have a built-in intelligence to cope with the complexity of applying multiple sensors to a specific problem such as augmented reality, navigation, positioning, and more.
Sensor Fusion
Sensor Fusion
The process of combining and processing the raw data coming out of multiple sensors to generate usable information.
212 Case Studies
182 Hardware
333 Suppliers
15 Events
7 Organizations
27 Use Cases
99 Terms
7 Guides
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