Accelerating the Industrial Internet of Things
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Number of Case Studies195
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 Hardware176
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 Suppliers295
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
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)
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 Cases33
Gas Detection Predictive Maintenance
Gas Detection Predictive Maintenance
Operators use gas detection devices to monitor and prevent gas leaks.Detection of gas levels and leakages in industrial environments, surroundings of chemical factories and inside mines involves significant costs, and is of crucial importance for operating safety. While preventive maintenance could provide for another IIoT solution, at remote sites it is costly and sometimes ineffective.
Structural Health Monitoring (SHM)
Structural Health Monitoring (SHM)
Structural Health Monitoring (SHM) enables engineers to improve the safety and maintainability of critical structures. SHM combines multiple sensing technologies with an embedded measurement controller to capture, log, and analyze real-time data. CHALLENGES / REQUIREMENTS - A system is required to monitor the real-time structural parameters and analyze the health of the structureSTAKEHOLDERS - Users and owners of the structureKEY OBJECTIVES - To detect and repair problems in a structure before it collapses- Human safety- To detect and repair problems in a structure before it collapsesTYPICAL SYSTEM CAPABILITIES - To detect the structural hazards in a specific structure and adjust repair schedule accordinglyUSAGE VIEWPOINT - Sensors located on the structure send real-time data to the analytical software tools- According to the inputs from sensors, health and life of the structures is decided- If any hazard found, repair schedule is planned accordinglyFUNCTIONAL VIEWPOINT - Sensors: Civil structure health sensor nodes- Network: Wide Area Network (WAN)- Standards: - Augmented Intelligence: Descriptive analysis- Augmented Behavior: Machine-to-machine (M2M) interfacesStructural Health Monitoring (SHM) is the process of implementing a damage detection and characterization strategy for engineering structures in order to maintain the system’s performance. The SHM process involves the observation of a system over time using periodically sampled response measurements from an array of sensors, extracting damage-sensitive features from these measurements, and performing statistical analysis of these features to determine the current state of system health. Over the long term data analysis increases visibility into the ability of the structure to perform its intended function. After extreme events, such as earthquakes or blast loading, SHM is used for rapid condition screening and aims to provide reliable, real time information regarding the integrity of the structure. SHM can be applied to fixed infrastructure, such as building and bridges, or mobile infrastructure, such as airplanes and trains. Health Assessment of Engineered Structures of Bridges, Buildings and other related infrastructures:Commonly known as Structural Health Assessment (SHA) or SHM, this concept is widely applied to various forms of infrastructures, especially as countries all over the world enter into an even greater period of construction of various infrastructures ranging from bridges to skyscrapers. Especially so when damages to structures are concerned, it is important to note that there are stages of increasing difficulty that require the knowledge of previous stages, namely:1) Detecting the existence of the damage on the structure2) Locating the damage3) Identifying the types of damage4) Quantifying the severity of the damageIt is necessary to employ signal processing and statistical classification to convert sensor data on the infrastructural health status into damage info for assessment.SHM Components:SHM System's elements include:- Structure- Sensors- Data acquisition systems- Data transfer and storage mechanism- Data managementData interpretation and diagnosis:1) System Identification2) Structural model update3) Structural condition assessment4) Prediction of remaining service lifeAn example of this technology is embedding sensors in structures like bridges and aircraft. These sensors provide real time monitoring of various structural changes like stress and strain. In the case of civil engineering structures, the data provided by the sensors is usually transmitted to a remote data acquisition centres. With the aid of modern technology, real time control of structures (Active Structural Control) based on the information of sensors is possibleKey vendors: Campbell Scientific, National Instruments, SENSeOR, SmartPatch
Seismic Acquisition
Seismic Acquisition
Seismic acquisition is a service for oil and gas companies and helps them to explore, develop, and manage hydrocarbon accumulations. 2D, 3D and 4D seismic data acquisition involves applying a seismic energy source at discrete surface location. The resulting energy is reflected back from interfaces where rock properties change.By recording this reflected energy at an array of geophones placed in the ground surface, the results can be processed to produce an image of underground geological structures and a range of attributes that can be used to infer the physical rock properties.
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.
195 Case Studies
176 Hardware
295 Suppliers
15 Events
7 Organizations
33 Use Cases
99 Terms
7 Guides
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