#lorawan temperature sensor
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Specification • PM2.5, PM10 based pollution Detection, • CO2 level monitoring for traffic density. • Auto path clearance for Ambulance and fire brigade based on RF communication to traffic light via Mobile/Web application MCU Specification • SX1262+STM8L152 integrated. • Frequency Range: 865MHz ~ 867MHz. • Maximum Power +21dBm constant RF
#Best LoRaWAN Air Pollution Monitoring#Hydraulic Trainer kit & Pneumatic Trainer kit manufacturers#LoRaWAN Air Pollution Monitoring system manufacturers#lorawan device#lorawan vs lora#lorawan temperature sensor#lorawan end node
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LoRaWAN-Based Temperature and Humidity Sensors: Revealing Accuracy in Networking
The combination of Temperature and Humidity Sensors based on LoRaWAN has become a revolutionary force in the quickly evolving IoT world, changing how we monitor and comprehend our surroundings. This essay delves into the nuances of this innovative technology, examining its uses in several sectors and highlighting its indisputable benefits over conventional approaches.
#technology#lansitec#iot#lora#temperature sensor#humidity sensor#lora temperature sensor#wireless#lorawan#sensors
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Warehouses are an integral part of any supply chain management process. A temperature-controlled environment is required to store raw materials, products, spares, etc. In some cases, temperature and humidity variations can degrade the quality of a product to an excessive extent. Maintaining a specific temperature and humidity for food products until they are transported is necessary.
Most of the warehouses have a temperature-monitoring system, which is a wired system. Either such warehouses have solutions where past-recorded data in data loggers are used to analyze the trend, or a wired system is laid to obtain real-time data involving cost, effort, and time. Such solutions include issues as given below.
UniConverge Technologies offers Temperature/Humidity sensor node device, which provides real-time ambient temperature and humidity at remote locations. Multiple node devices can easily connect with Wireless Ethernet Gateway, which can transfer data to a cloud server through MQTT or to a local server through Modbus TCP/IP for monitoring the real-time data.
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What is the difference between LoRa and LoRaWAN?
Introduction:
LoRaWAN serves as the communication protocol connecting the LoRa signal (which carries sensor data) to the respective application(s). To simplify, think of LoRa as the radio signal transporting the data, while LoRaWAN acts as the governing framework that dictates how this data travels and communicates within the network.
What is LoRa?
LoRa, short for Long Range, is a wireless technology known for its extended range and energy-efficient characteristics. It operates within unlicensed wireless frequencies, similar to how Wi-Fi utilizes the unregulated 2.4 GHz and 5 GHz bands. The specific frequency employed by LoRa varies depending on the geographic location of the deployment. For instance, in North America, LoRa operates in the 915 MHz band, while in Europe, it utilizes the 868 MHz band and in India it is 865 MHz to 867 MHz.
It is crucial to be aware of the legally permitted frequencies for LoRa deployments in each respective location. In terms of its communication range, LoRa can transmit data up to a distance of 10 kilometers in ideal conditions with a clear line of sight.
Low Power Wide Area (LPWA) technology can be categorized into two main types. On one hand, there's cellular LPWA, which utilizes mobile networks. Examples of cellular LPWA technologies include Narrowband IoT (NB-IoT) and Long Term Machine Type Communications (LTE-M). On the other hand, there's non-cellular LPWA like LoRa, which disseminates data by dividing it into encoded packets and transmitting them across various frequency channels and data rates.
What is LoRaWAN?
LoRaWAN is a network protocol that serves as the bridge between the LoRa signal, which carries sensor data, and the applications that use this data. In simpler terms, LoRa represents the radio signal responsible for transmitting the data, while LoRaWAN is the communication protocol that manages and defines how this data is transmitted across the network.
LoRaWAN offers several valuable advantages, including low power consumption, extensive coverage range, and cost-effective connectivity for devices that don't require high data transfer speeds. It's an excellent choice when cellular connectivity is too expensive or Wi-Fi coverage is unavailable. Some of the most compelling use cases for LoRaWAN include:
Agriculture: LoRaWAN's long-range capabilities provide reliable connectivity for rural applications where high data transfer rates are not necessary, making it ideal for agricultural applications. LoRaWAN sensors for agriculture are used for cattle management, soli monitoring, and temperature monitoring.
Asset Tracking and Logistics: LoRaWAN supports cost-effective location tracking of assets, with optimized battery life, making it a practical choice for asset management and logistics.
Smart Metering: LoRaWAN's sensors have the ability to reach even in underground utility locations makes it a suitable choice for smart metering applications.
Smart Homes: LoRaWAN can penetrate obstacles like walls and supports battery-powered devices with low data consumption, making it an attractive connectivity option for smart home applications.LoRaWAN sensors for smart homes are used for Air quality monitoring, water quality monitoring, and temperature & humidity monitoring.
Healthcare: The low power consumption, affordability, and reliability of LoRa technology make it suitable for connected health applications. IoT solutions based on LoRa hardware can monitor high-risk patients or systems around the clock, ensuring comprehensive health and medical safety management.LoRaWAN Gateways and sensors enhance production practices, enable efficient tracking and monitoring of shipments, and facilitate the development of cutting-edge medications.
Industrial Applications: LoRa-enabled devices and sensors play a crucial role in the transformation of industrial IoT operations like mentioned above. They digitize legacy processes and equipment, leading to increased profits, lower costs, and enhanced efficiency. These devices provide real-time data for predictive maintenance, machine health monitoring, reduced downtime, and more.
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Winext low-cost LoRaWAN Sensors for Temperature & Humidity
In my search for low-cost LoRaWAN sensors for temperature and humidity, I came across the range offered by the Chinese company Winext (https://winext.cn/#/en/product).
I was particularly interested in the LoRa temperature and humidity sensors AN-103A (outdoor use) and AN-303 (indoor use) with the following technical features:
Auf der Suche nach kostengünstigen LoRaWAN-Sensoren für Temperatur…
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CO₂, temperature, humidity and barometric pressure sensors for LoRaWAN®
What level of CO₂ Concentration is terrible for us?
Carbon dioxide (CO₂) levels in the air are measured in parts per million (ppm). Up to 800 ppm of CO₂ is generally regarded as safe.
Between 1,000 ppm and 1,500 ppm, elevated CO₂ levels can induce symptoms such as fatigue, sleepiness, and reduced concentration. Beyond 1,500 ppm, individuals may experience headaches, with severity increasing as CO₂ concentrations rise.
Mutelcor Smart CO₂ LoRa Sensor
The Mutelcor Smart CO₂ LoRa Sensor incorporates sensors for carbon dioxide, temperature, and humidity, all of which deliver data through a dedicated web dashboard.
It measures CO₂ levels automatically every 2 seconds and allows users to customize the interval for sending updates to the dashboard.
You could also call this device a LoRa Carbon Dioxide Sensor or CO₂ Gas Sensor.
Now, let’s delve into the functionality of the CO₂ sensor. When the CO₂ level is below 800 ppm, a green light illuminates.
At 800 ppm, a yellow light remains on until the level drops below 750 ppm. If the CO₂ level reaches 1000 ppm, a red light indicates this until the level falls below 950 ppm, at which point it turns yellow.
When the CO₂ level exceeds 1500 ppm, the red light activates along with three beeps lasting 5 seconds. Additionally, as long as the CO₂ level remains above 1450 ppm, the sensor emits two buzzer sounds for 5 seconds every 10 minutes.
All data is recorded on the CO₂ sensor dashboard, accessible for review with various filter options.
In residential and office settings, CO₂ sensors are configured with safety margins that can be adjusted to suit specific requirements.
For instance, environments like mushroom farming necessitate CO₂ levels as high as 16,000 ppm. In such cases, the sensor can be configured to display a green light within this range. If the CO₂ level drops below this threshold, a red light indicates the deviation, while a yellow light may signify elevated levels beyond the optimal range.
This customization ensures the sensor effectively meets diverse operational needs while maintaining safety and efficiency in various applications.
What is this CO₂ Sensor
CO₂ sensors in HVAC
HVAC, which stands for Heating, Ventilation, and Air Conditioning, is essential in homes for regulating temperature and ensuring proper ventilation.
CO₂ sensors play a critical role in determining optimal ventilation timing, while temperature and humidity sensors assist in managing cooling cycles effectively.
CO₂ sensor for Smart Homes
Smart homes integrate all electronic devices with internet connectivity, enabling remote management. This technology allows homeowners to control lighting, air conditioning, and fans from anywhere, without physical presence.
Within smart homes, CO₂ sensors can alert users via mobile devices or a central dashboard about ventilation, enhancing indoor air quality management.
CO₂ sensor for Automated Buildings
Automated buildings represent advanced iterations of smart homes and HVAC-equipped residences, integrating diverse sensors to optimize building maintenance.
For instance, CO₂ sensors are strategically placed to regulate ventilation, while temperature and humidity sensors are utilized to ensure consistent indoor climate control across the entire building.
CO₂ Sensor for Schools
During winter, classroom environments typically keep doors and windows closed to maintain warmth. To ensure optimal air quality without disrupting students’ focus and well-being, CO₂ sensors are employed to facilitate periodic ventilation. Additionally, CO₂ sensors are integral to the operation of air-conditioned classrooms, supporting efficient management of indoor air quality throughout the school day.
CO₂ Sensor for Universities
CO₂ sensors in universities play a crucial role in maintaining air quality across classrooms, laboratories, and common areas, promoting a conducive environment for student productivity and concentration. These sensors also contribute to the optimization of HVAC systems throughout the university campus.
CO₂ Sensor for Senior Residences
CO₂ sensors are instrumental in maintaining a healthy environment in senior residences, while also optimizing energy use for ventilation systems serving elderly residents.
CO₂ Sensor for Apartments
The shift towards remote work and increased apartment living underscores the importance of maintaining a healthy lifestyle, where CO₂ sensors play a crucial role in ensuring environmental health.
CO₂ Sensor for Shopping Malls
In shopping malls, HVAC systems are essential for regulating temperature and creating a comfortable shopping experience. CO₂ sensors are strategically positioned throughout malls to detect elevated CO₂ levels, triggering ventilation cycles as needed to uphold indoor air quality and enhance visitor comfort.
CO₂ Sensor for Hospitals & ICU
In hospitals, critical areas such as ICUs, operating theaters, and emergency rooms require utmost focus from healthcare professionals to ensure patient safety and optimal care.
Maintaining a healthy environment is crucial throughout the facility, and CO₂ sensors play a vital role in ensuring good air quality for patients and medical staff.
CO₂ Sensor for Offices & Coworking Spaces
In office environments, maintaining high levels of concentration directly impacts business productivity and revenue. CO₂ sensors provide timely insights into air quality, enabling teams to optimize conditions and sustain focus, thereby enhancing overall productivity
Conclusion
Carbon Dioxide in the atmosphere helps us to maintain our blood pH level. If the CO₂ concentration is high in the atmosphere then blood acidification starts taking place, which causes fatigue, sleepiness, and difficulty concentrating to the point of severe headaches depending on the concentration of the CO₂ around you.
Prolonged exposure or regular exposure to high levels of CO₂ Concentration may also negatively impact your life expectancy and can cause you illnesses.
The CO₂ Level is measured in ppm (Parts per Million); up to 1,000 ppm is considered safe, and between 1000 to 1500 is regarded as a yellow zone with fatigue & sleepiness; after 1,500 ppm, you will start experiencing severe headaches.
Mutelcor CO₂ Sensor helps you know the CO₂ concentration so you can ventilate your room for a good environment at your place.
Then we learned how this system works and records data; Later, we went through the use cases of CO₂ sensors at different places like hospitals, Shopping Malls, and Offices.
For More Details Please Visit Or Call Us Now:-
Site:- https://mutelcor.com/
Email:- [email protected]
Phone: +49 203 7299 60 70
Fax: +49 203 7299 60 71
Address:- Mutelcor GmbH An der Bastei 42a 47259 Duisburg Germany
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Data Security and Precision Control: Precision Application of Smart Irrigation Using LoRa Technology and LoRaWAN Gateway
The application characteristics of LoRa modules in smart irrigation technology are mainly reflected in the following aspects:
Low Power Consumption: LoRa modules are characterized by extremely low power consumption, enabling devices to operate for extended periods on battery power. This reduces the hassle of frequent battery replacements and enhances the system's lifespan and reliability.
Anti-Interference Capability: LoRa technology has excellent anti-interference capabilities., ensuring stable communication quality even in environments with multiple radio signals.
Long-Distance Transmission: Utilizing low-frequency transmission, spread spectrum technology, and high-sensitivity receivers, LoRa modules can achieve wireless communication over distances ranging from several kilometers to over ten kilometers.
MESH Self-Organizing Network: LoRa modules can establish communication connections through self-organizing networks, eliminating the need for complex infrastructure and network wiring.
Precision Irrigation: LoRa modules offer stable and accurate data transmission, enabling real-time delivery of information such as soil moisture and weather conditions.
High Penetration: LoRa technology boasts strong signal penetration and stability, ensuring reliable signal transmission even in complex environments.
Multi-Node Support: LoRa modules support applications with multiple nodes. A single LoRa gateway can connect multiple sensor nodes, forming a complete network system for extensive, multi-point monitoring and management.
Data Security: LoRa modules provide high data security, employing encryption technology to protect data during transmission, preventing data theft or tampering, and ensuring the confidentiality and integrity of agricultural data.
Wide Coverage: LoRa technology can achieve wide coverage, typically ranging from several kilometers to over ten kilometers, without the repeaters.
Module Compatibility: LoRa modules are compatible with various types of sensors and control devices, offering a high level of system integration and facilitating seamless cooperation among different devices.
How the LoRa modules achieve precision irrigation in smart irrigation?
Remote Monitoring: Using LoRa modules, the irrigation system can achieve remote monitoring and control. Users can access real-time environmental data such as soil moisture and temperature from a distance and remotely control irrigation equipment, enabling precision irrigation.
Data Analysis: After the cloud platform receives sensor data, it analyzes and processes the information to promptly understand soil moisture conditions, providing a scientific basis for irrigation decisions.
Remote Control of Equipment: LoRa modules transmit commands to various irrigation nodes through long-distance, low-power wireless communication, controlling valve switches, irrigation times, and irrigation amounts.
Timed Irrigation: The irrigation schedule can be preset, and the LoRa module can be used to control the irrigation equipment to irrigate at the best time.
Feedback Mechanism: After irrigation is completed, the system re-monitors soil conditions and feeds the data back to the central control system.
Functions of the LoRaWAN Gateway LG1301-PF in Smart Irrigation Systems
Features of the LG1301-PF Gateway
LG1301-PF is the LoRaWAN gateway. It can work with any LoRaWAN node which comply Standard LoRaWAN protocol V1.0.
The gateway use linux platform as host.It mainly consists of concentrator ,GPS module ,WIFI and Ethernet. The GPS module send NMEA frames containing time and geographical coordinates data to the host. The GPS module also output one pulse to the sx1301 per second.
The gateway receives the RF data from nodes and sends it to the server. It also receive data from the server and transmit to the nodes. The gateway connects to the server via Ethernet or WiFi.
Support for LoRaWAN Protocol: Adapts to the LoRaWAN protocol, enabling the device to communicate with standard LoRaWAN networks for remote data transmission and management.
UART Interface: Provides a UART interface for convenient data exchange and integration with other devices or sensors.
AES128 Encryption: Uses the AES128 encryption algorithm to ensure the security and privacy of data transmission.
8-Channel Simultaneous Communication: Supports up to 8 channels of communication simultaneously
Configurable Parameters: Users can flexibly configure various parameters according to specific application needs.
Global Positioning System Support: GPS functionality enables precise positioning and tracking of the device.
Remote Transmission: Supports remote data transmission, allowing real-time data transfer and management between the device and the cloud via an internet connection.
Frequency Band Support: Covers multiple frequency bands (such as EU433M, EU868M, KR920M, AS923M, CN780M, CN470M, US915M, AS915M, etc.).
By using NiceRF LoRa gateway devices, sensor equipment in the irrigation field (such as temperature sensors, humidity sensors, light sensors, CO2 sensors, etc.) can be connected in real-time. These sensors collect data in real-time and periodically upload it to the cloud platform or local host computer via LoRa modules. This setup enables remote monitoring, fault alarms, equipment management, and provides scientific and reliable data support for adjusting irrigation strategies.
Data Monitoring Function: The sensor equipment monitors data such as air temperature, air humidity, CO2 levels, light intensity, soil moisture, and soil temperature. This data is transmitted through the LoRa gateway to the cloud platform, allowing users to analyze and process the information conveniently.
Remote Control and Adjustment: The LoRa gateway can connect to irrigation equipment, enabling remote control of the irrigation system. By sending commands from the cloud platform to the LoRa gateway, users can adjust irrigation equipment, such as remotely starting or stopping the equipment or adjusting irrigation parameters. This allows for intelligent irrigation based on feedback from soil moisture sensors, providing precise water management, reducing waste, and improving irrigation efficiency.
Anomaly Alarms and Warnings: The LoRa gateway can monitor abnormal conditions in the farmland environment and send alarm messages to users through the cloud platform. For instance, if soil moisture levels are too low or too high, the LoRa gateway can promptly issue an alert, reminding farmers to take appropriate irrigation measures.
Energy Efficiency Optimization: The gateway is designed with low power consumption features. By optimizing energy management and data transmission frequency, it effectively extends the operating time of the equipment, reduces energy costs, and enhances system sustainability.
For details, please click:https://www.nicerf.com/products/
Or click:https://nicerf.en.alibaba.com/productlist.html?spm=a2700.shop_index.88.4.1fec2b006JKUsd
For consultation, please contact NiceRF (Email: [email protected]).
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How Businesses in USA Can Thrive in the Digital Age with IoT Solutions
In today's rapidly evolving business landscape, the importance of embracing technological advancements cannot be overstated. One such innovation that has become a business imperative is the Internet of Things (IoT). A recent report predicts a staggering $24 trillion investment in IoT solutions annually by 2027, emphasizing the need for businesses to adapt or risk being left behind. Bridgera, a technology company headquartered in Raleigh, USA, understands the significance of IoT and its transformative impact on businesses.
At the core of IoT lies a complex ecosystem of hardware, software, and connectivity. IoT devices serve as sensory appendages, collecting real-time data from the physical world. These devices, ranging from simple temperature sensors to sophisticated industrial equipment, form the foundation of any successful IoT solution.
Connectivity is the nervous system that links these devices together, facilitating seamless communication. Wi-Fi, cellular networks, Bluetooth, and LoRaWAN are just a few examples of the technologies employed for this purpose. The choice of connectivity depends on factors such as range, power consumption, and data transfer rates.
Central to the IoT ecosystem is the IoT platform. This software infrastructure processes and analyzes data from connected devices, serving as the brain of the system. An effective IoT platform enables data storage, visualization, integration with other systems, and the development of IoT applications that transform data into actionable insights and services.
Integrating IoT solutions into core business operations offers several benefits that can help businesses in US thrive:
Increased productivity: By optimizing processes and automating tasks, businesses can achieve significant productivity gains. IoT-enabled sensors provide real-time data on equipment performance, enabling predictive maintenance and minimizing disruptions.
Cost reduction: IoT solutions drive operational efficiency, leading to cost reductions throughout the value chain. Leveraging data analytics, businesses can identify areas for optimization and eliminate wasteful practices.
Enhanced customer experiences: IoT-powered products and services create personalized and engaging customer experiences. For instance, smart devices can provide valuable insights into customer preferences, enabling tailored offerings.
New revenue streams: IoT opens up opportunities for innovative business models. By developing IoT-based products and services, businesses can tap into emerging markets and capture new revenue streams.
While off-the-shelf IoT solutions offer a starting point, developing custom IoT solutions tailored to specific needs is often necessary for businesses to fully realize their potential. Bridgera understands this and offers comprehensive services to empower businesses in their IoT journey.
Key considerations for developing custom IoT solutions include a clear definition of requirements, careful selection of devices that align with objectives and environmental conditions, integration with a scalable and secure IoT cloud platform, robust data analytics capabilities, and prioritizing data protection and device security. Scalability should also be a key design element to accommodate future growth and expansion.
Implementing IoT solutions presents definite challenges, such as complexity, data management, security risks, and demonstrating return on investment. To overcome these hurdles and capitalize on the potential of IoT, businesses in Raleigh require a strategic approach, technological expertise, and a strong partnership.
Bridgera, headquartered in Raleigh, NC, specializes in delivering cutting-edge IoT solutions using connected intelligence. Their services include IoT strategy development, platform selection and implementation, device configuration, data analytics, security and compliance, and ongoing support and maintenance.
In conclusion, for businesses looking to thrive in the digital age, embracing IoT solutions is no longer a choice but a necessity. By harnessing the power of IoT, businesses can increase productivity, reduce costs, enhance customer experiences, and tap into new revenue streams. For comprehensive IoT implementation, Bridgera, with its expertise and commitment to excellence, is the ideal partner for businesses seeking to unlock the full potential of the IoT revolution
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An In-Depth Exploration of IoT Connectivity Technologies and Their Uses
Discover the top IoT connectivity technologies and their applications in this detailed guide. Learn how to select the right technology for your needs.
Imagine a world where everyday objects communicate seamlessly to enhance the efficiency and convenience of our lives. The Internet of Things (IoT) has revolutionized how we interact with technology. By 2030, it's projected there will be over 32.1 billion IoT devices globally, nearly doubling from 15.9 billion in 2023. Examples include smart home appliances that adjust the temperature upon entry and wearable fitness trackers that continuously monitor health. These devices connect and exchange data thanks to IoT networking technologies. Let's explore these technologies further.
What Are IoT Connectivity Technologies?
IoT connectivity technologies encompass the various methods and protocols used to connect IoT devices to the internet or each other. These technologies enable communication, data transfer, and control for IoT devices, with over 29 billion connections anticipated by 2027.
Why Is IoT Connectivity Important?
The choice of IoT connectivity technology significantly impacts the performance, cost, and scalability of your IoT solution. High-speed, ultra-low latency connectivity is crucial for some applications, making 5G or 4G cellular IoT connectivity ideal despite higher costs and power usage. Conversely, simpler deployments might benefit from low-speed connections, which are more cost-effective and require less power.
Top 5 IoT Connectivity Technologies and Their Applications
Cellular Networks Cellular networks, essential in daily life for phones and tablets, provide wide coverage, reliability, and enhanced security. They are ideal for mobile IoT systems and serve as alternatives to LPWAN technologies like Sigfox and LoRaWAN.
Use Cases:
Point of Sale and Kiosks: Enables vending machines and kiosks to operate without Wi-Fi, expanding retail opportunities.
Delivery Tracking: Provides real-time shipment tracking across diverse environments, including remote or mobile scenarios.
High Data Rate Cellular (3G/4G/LTE/5G) With high Mbps speeds, these networks suit data-intensive IoT applications, mobile devices, and real-time video streaming. They support "massive IoT" deployments, connecting thousands of devices across large areas.
Use Cases:
Fleet Management: Real-time tracking optimizes operations, enhancing route planning and fuel efficiency.
Health Monitoring: Continuous health data transmission from wearables to healthcare providers ensures prompt intervention.
Ethernet Ethernet offers a reliable, low-latency wired connection, ideal where infrastructure is in place. It provides stable performance unaffected by physical barriers, suitable for stationary IoT devices.
Use Cases:
Security Cameras: Ensures uninterrupted video surveillance in homes or businesses.
Game Systems: Minimizes latency for gamers seeking reliable network performance.
Stationary Medical Devices: Facilitates real-time data transmission from medical equipment to centralized systems.
Wi-Fi Common in homes and offices, Wi-Fi supports secure, high-bandwidth connectivity within a limited range. It's ideal for localized IoT ecosystems where devices are confined to a specific area.
Use Cases:
Smart Gadgets: Integrates smart devices like TVs and appliances into home networks.
Digital Signage: Enables content updates and management in commercial settings.
Bluetooth Bluetooth excels in connecting small, battery-powered devices within short ranges, typically up to 30 feet. It offers low energy consumption, widely used in consumer electronics and small-scale IoT deployments.
Use Cases:
Smartwatches/Fitness Trackers: Syncs health data to smartphones, facilitating mobile monitoring.
Bluetooth Low Energy Sensors: Collects and transmits data from sensors in homes or small businesses.
These technologies cater to diverse IoT needs, each offering unique advantages in range, bandwidth, power efficiency, and scalability. The right choice depends on specific application requirements and environmental considerations.
Essential Requirements for Your IoT Connectivity Solution
Each use case has specific requirements translating into particular technology needs:
Technical Requirements: Consider data speed, latency, range, power consumption, and network coverage. High-speed applications might require advanced cellular technologies, while low-power long-range deployments might favor LPWAN solutions.
Commercial Requirements: Costs include initial setup and ongoing operational expenses. Technologies with lower power needs and simpler infrastructure can reduce costs, ideal for large-scale deployments.
Ecosystem Requirements: Compatibility with existing systems, availability of support and development resources, and integration with future technologies are crucial considerations.
Factors to Consider When Choosing IoT Connectivity Technology
Selecting the most suitable connectivity technology involves a careful assessment of each deployment’s characteristics. This strategic decision affects the immediate performance and cost-efficiency of your service and its long-term scalability and future-proofing.
Conclusion
The field of IoT connectivity technologies holds great promise. The IoT ecosystem evolves daily with advancements in low-power protocols, wireless networks, and emerging technologies. Significant advancements in connectivity technology, such as the implementation of 5G networks, will offer extremely low latency and fast speeds, facilitating seamless communication and new possibilities for real-time applications.
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Design and enactment of an IoT gateway to build smart environments
Designing and implementing an IoT gateway for creating smart environments involves several crucial steps that ensure seamless integration and efficient data handling. This process is particularly impactful in applications like Smart Fire Monitoring, where real-time data and rapid response are critical.
Design Phase
Requirements Analysis
The first step in designing an IoT gateway is to understand the specific requirements of the smart environment. For Smart Fire Monitoring, this includes identifying the types of sensors (e.g., smoke detectors, temperature sensors, gas sensors) that need to be connected, the data they will generate, and the communication protocols they use (e.g., Zigbee, LoRaWAN, Wi-Fi).
Hardware Selection
Choosing the right hardware is essential for building a reliable Industrial IoT gateway. The gateway must support various communication protocols and have sufficient processing power to handle data aggregation and preliminary analysis. It should also have robust security features to protect data integrity and prevent unauthorized access.
Software Architecture
The software architecture of the IoT gateway must be designed to manage data flow efficiently. This includes implementing middleware that can handle protocol translation, data filtering, and local data storage. The gateway should also be capable of edge computing, allowing it to perform initial data processing and reduce the load on central servers.
Implementation Phase
Sensor Integration
The first step in implementation is integrating the sensors with the IoT gateway. This involves configuring the sensors to communicate with the gateway and ensuring that data from all sensors can be aggregated and processed. For Smart Fire Monitoring, the sensors must be placed strategically to cover all potential fire risk areas.
Data Management
Effective data management is crucial for the IoT gateway. This includes setting up data filtering to remove noise, data compression to save bandwidth, and local storage for temporary data holding. The gateway should be configured to transmit only relevant data to the cloud or central server, optimizing bandwidth usage and ensuring timely responses.
Security Measures
Implementing robust security measures is vital to protect the data being transmitted. This includes encrypting data at rest and in transit, using secure communication protocols, and ensuring that the gateway has built-in firewalls and intrusion detection systems.
Edge Computing
Incorporating edge computing capabilities allows the gateway to perform initial data analysis and make quick decisions without relying on cloud processing. For Smart Fire Monitoring, this means the gateway can trigger alarms or initiate fire suppression systems immediately upon detecting a fire risk, even if the internet connection is down.
Deployment and Testing
Once the IoT gateway is implemented, it needs to be thoroughly tested in a real-world environment. This involves validating that all sensors are accurately reporting data, the data is being processed correctly, and the gateway can handle the expected data load. Smart Fire Monitoring also includes testing the response times and ensuring that the system can reliably trigger alarms and notifications.
#iot gateway#industrial iot gateway devices#IIoT Gateway Devices#Industrial IoT Gateways & Devices#IIOT solution for manufacturing#iot in manufacturing industry
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The Internet of Things (IoT): A Revolution in Connectivity and Innovation
Introduction
Introduction to IoT
The Internet of Things (IoT) represents a paradigm shift in technology, bringing about a world where devices, sensors, and systems are interconnected, enabling them to collect and exchange data. This interconnected network of "things" encompasses a vast array of objects from everyday household items to complex industrial machinery. The advent of IoT has revolutionized numerous sectors, driving innovation and efficiency while transforming how we interact with technology.
IoT-Enabled Products
IoT-enabled products are the tangible manifestations of this technology, designed to bring convenience, automation, and intelligence to various aspects of life. These products span numerous categories, including smart homes, healthcare, transportation, agriculture, and industrial applications.
Smart Homes
In the realm of smart homes, IoT-enabled devices such as smart thermostats, security systems, lighting, and appliances enhance comfort, security, and energy efficiency. Products like the Nest Thermostat learn user preferences and adjust temperatures accordingly, while smart security cameras and doorbells from companies like Ring offer real-time monitoring and alerts, ensuring safety.
Healthcare
The healthcare sector benefits immensely from IoT through devices that enable remote monitoring and telemedicine. Wearable health monitors, like the Fitbit and Apple Watch, track vital signs and physical activity, providing valuable data for both users and healthcare providers. IoT-enabled medical devices such as insulin pumps and connected inhalers ensure better management of chronic diseases, improving patient outcomes.
Transportation
IoT's impact on transportation is profound, with innovations like connected cars, fleet management systems, and smart traffic management. Connected vehicles from manufacturers like Tesla and Ford are equipped with sensors and software that enable autonomous driving, real-time diagnostics, and over-the-air updates. Fleet management solutions optimize routes and maintenance schedules, enhancing efficiency and reducing costs.
Agriculture
In agriculture, IoT facilitates precision farming through devices that monitor soil conditions, weather patterns, and crop health. Drones and automated machinery equipped with IoT sensors ensure optimal planting, watering, and harvesting, increasing yields and reducing waste. Companies like John Deere are pioneering smart agricultural equipment that leverages IoT for better farm management.
Industrial Applications
The industrial sector sees significant advancements through IoT in the form of smart factories and Industry 4.0. IoT-enabled machinery and sensors monitor equipment health, predict failures, and optimize production processes. This leads to increased efficiency, reduced downtime, and lower operational costs. Siemens and GE are at the forefront of integrating IoT into industrial operations, creating more responsive and adaptive manufacturing environments.
Technologies Behind IoT
The successful implementation of IoT relies on several key technologies that enable connectivity, data collection, and analysis.
Sensors and Actuators
Sensors are the eyes and ears of IoT devices, gathering data from the environment. They come in various types, including temperature sensors, motion detectors, and pressure sensors. Actuators, on the other hand, enable devices to interact with their surroundings by executing physical actions, such as turning on a light or opening a valve.
Connectivity
IoT devices require robust and reliable connectivity solutions to communicate with each other and central systems. This is facilitated by various communication protocols and networks, including Wi-Fi, Bluetooth, Zigbee, LoRaWAN, and 5G. Each has its own strengths and applications, from short-range, low-power communications to long-range, high-speed data transfer.
Edge Computing
Edge computing processes data closer to where it is generated, reducing latency and bandwidth usage. This is crucial for real-time applications like autonomous driving and industrial automation, where immediate decision-making is required. By processing data locally, edge devices can respond more quickly and reliably than if they had to rely solely on cloud computing.
Cloud Computing
Cloud computing provides the infrastructure for storing, processing, and analyzing vast amounts of data generated by IoT devices. It offers scalability and flexibility, enabling businesses to manage their IoT deployments effectively. Platforms like Amazon Web Services (AWS) IoT, Microsoft Azure IoT, and Google Cloud IoT provide comprehensive solutions for managing IoT ecosystems.
Artificial Intelligence and Machine Learning
Artificial intelligence (AI) and machine learning (ML) are integral to IoT, allowing devices to learn from data and make intelligent decisions. Predictive maintenance, anomaly detection, and autonomous operations are some of the capabilities enabled by AI and ML. These technologies transform raw data into actionable insights, driving innovation and efficiency across various sectors.
Leading IoT Manufacturers
Numerous companies are driving the development and deployment of IoT technologies, each contributing to the ecosystem with their unique offerings.
Cisco
Cisco is a global leader in networking and cybersecurity solutions, playing a crucial role in the IoT landscape. Their IoT solutions encompass connectivity, security, and analytics, providing a comprehensive framework for managing IoT devices and data. Cisco's IoT portfolio includes industrial networking, edge computing, and cybersecurity products designed to support various industries.
IBM
IBM's IoT solutions leverage their expertise in AI and cloud computing to deliver innovative applications for smart cities, industrial automation, and more. IBM Watson IoT platform provides powerful tools for connecting, managing, and analyzing IoT data, enabling businesses to harness the full potential of their IoT deployments.
Intel
Intel is at the forefront of IoT innovation with its range of processors, modules, and solutions designed for IoT applications. Intel's IoT products are used in various sectors, including healthcare, retail, and industrial automation, providing the computational power and connectivity needed for advanced IoT systems.
Siemens
Siemens is a pioneer in industrial IoT, offering solutions that integrate hardware, software, and services to optimize manufacturing processes. Their MindSphere platform is a leading industrial IoT as a service (SaaS) solution, enabling businesses to connect their machines and products to the digital world and harness the power of data analytics.
Google
Google's contributions to IoT are centered around its cloud services and AI capabilities. Google Cloud IoT offers a suite of tools for managing IoT devices and data, integrating seamlessly with Google's AI and machine learning services. This allows businesses to build intelligent, data-driven IoT applications with ease.
Challenges and Future Prospects
While the IoT presents immense opportunities, it also poses several challenges. Security and privacy are paramount concerns, as the proliferation of connected devices increases the risk of cyberattacks and data breaches. Ensuring robust security measures and protecting user data are critical for the continued growth and acceptance of IoT.
Interoperability and standardization are other significant challenges, as the vast array of devices and protocols can lead to compatibility issues. Developing common standards and frameworks is essential to ensure seamless integration and communication between different IoT systems.
Looking ahead, the future of IoT is promising, with advancements in technologies like 5G, AI, and edge computing driving further innovation. The ongoing development of smart cities, autonomous vehicles, and industrial automation will continue to expand the scope and impact of IoT, making our world more connected and intelligent.
Conclusion
The Internet of Things is a transformative force, reshaping industries and improving lives through connectivity and data-driven insights. IoT-enabled products, powered by advanced technologies and driven by leading manufacturers, are paving the way for a smarter, more efficient future. As the IoT ecosystem continues to evolve, addressing challenges and leveraging new opportunities will be key to unlocking its full potential.
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What's to come Calls: Investigating IoT and Smart App Development
Presentation:
In the present quickly advancing mechanical scene, the Web of Things IoT & Smart App Development stand at the front of advancement. This article dives into the meaning of IoT and the complexities of creating smart applications, revealing insight into their effect across different areas.
Figuring out IoT:
The Web of Things, or IoT, alludes to the organization of interconnected gadgets inserted with sensors, programming, and different innovations, empowering them to gather and trade information. These gadgets can go from regular articles like home appliances and wearables to modern apparatus and vehicles. IoT works with consistent correspondence between gadgets, offering remarkable degrees of mechanization, proficiency, and accommodation.
The Advancement of Smart App Development:
Smart applications are the main impetus behind IoT, engaging clients to easily associate with and control associated gadgets. From smart home frameworks that control temperature and lighting to medical services applications observing essential signs continuously, smart apps are changing the way in which we communicate with innovation. The advancement of smart app development includes utilizing state of the art innovations like man-made consciousness, AI, and information examination to make instinctive, client driven encounters.
Key Parts of IoT and Smart App Development:
Equipment Incorporation: Coordinating sensors, actuators, and other equipment parts into IoT gadgets shapes the underpinning of smart app development. Strong equipment guarantees precise information assortment and consistent cooperation with the advanced biological system.
Information The board and Examination: The tremendous measures of information created by IoT gadgets require refined administration and investigation methods. Smart applications influence information examination to infer noteworthy experiences, empowering prescient support, customized suggestions, and streamlined activities.
Availability Conventions: Laying out dependable correspondence channels between IoT gadgets and smart applications is fundamental for consistent usefulness. Normal availability conventions incorporate Wi-Fi, Bluetooth, Zigbee, and LoRaWAN, each fit to explicit use cases in view of elements like reach, power utilization, and information move rate.
Security and Protection: With the expansion of associated gadgets, guaranteeing the security and security of client information becomes fundamental. Smart app designers carry out hearty encryption, validation, and access control components to protect delicate data and relieve network safety dangers.
Applications Across Enterprises:
Smart Home Robotization: IoT-empowered gadgets like smart indoor regulators, lighting frameworks, and surveillance cameras offer property holders phenomenal command over their residing spaces, improving solace, accommodation, and energy effectiveness.
Medical care and Wearable Innovation: Wearable gadgets outfitted with biometric sensors and wellbeing observing capacities engage people to follow their wellness levels, screen constant circumstances, and get customized wellbeing bits of knowledge continuously.
Modern IoT (IIoT): In modern settings, IoT advancements streamline processes, further develop resource the executives, and improve wellbeing by empowering prescient upkeep, remote checking, and independent activity of apparatus and hardware.
Smart Urban communities: IoT arrangements assume a critical part in building smarter, more practical urban areas by improving transportation frameworks, overseeing energy utilization, and upgrading public wellbeing through advances like smart matrices, traffic the executives frameworks, and natural checking gadgets.
Difficulties and Future Standpoint:
While IoT and smart app development offer tremendous potential, they likewise present critical difficulties, including interoperability issues, information protection concerns, and network safety chances. Tending to these difficulties requires cooperative endeavors from industry partners, policymakers, and innovation trend-setters.
Looking forward, the cooperative energy among IoT and smart app development is ready to drive further advancement across different areas, changing ventures, improving lives, and forming the fate of associated biological systems.
End:
All in all, IoT and smart app development address a change in perspective by they way we see and cooperate with innovation. By bridling the force of interconnected gadgets and insightful applications, we open additional opportunities for productivity, comfort, and maintainability, making ready for a smarter, more associated world.
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Exploring the Benefits of a LoRa Temperature and Humidity Sensor
Enhance your environment monitoring with our Temperature and Humidity Sensor. This compact device accurately measures temperature and humidity levels, providing valuable data for optimizing comfort and energy efficiency. With its easy installation and compatibility with smart home systems, this sensor is a must-have for anyone seeking to create a healthier and more comfortable living or working space. The sensor operation mode can be adjusted via the LoRa network.
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#lansitec#iot#lora#technology#temperature sensor#humidity sensor#lora temperature sensor#wireless#lorawan
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Empowering Connectivity: Exploring the Evolution of IoT Remote Monitoring Devices
In an era defined by connectivity and data-driven decision-making, IoT (Internet of Things) remote monitoring devices have emerged as indispensable tools across various industries. These compact yet powerful devices enable real-time monitoring, management, and control of assets, processes, and environments from virtually anywhere in the world. In this article, we delve into the transformative potential of IoT remote monitoring devices, exploring their applications, benefits, and the evolving landscape of this dynamic technology.
The Essence of IoT Remote Monitoring Devices
At the heart of IoT remote monitoring devices lies the convergence of hardware, software, and connectivity technologies. These devices are equipped with an array of sensors capable of capturing diverse environmental parameters, such as temperature, humidity, pressure, vibration, and more. By harnessing wireless communication protocols like Wi-Fi, cellular, Bluetooth, or LoRaWAN, IoT remote monitoring devices transmit the collected data to cloud-based platforms for analysis, visualization, and action.
Applications Across Industries
The versatility of IoT remote monitoring devices extends across a myriad of industries, revolutionizing operations and unlocking new opportunities for efficiency and optimization:
Manufacturing: In manufacturing facilities, IoT remote monitoring devices enable predictive maintenance by continuously monitoring equipment health and performance metrics.
Healthcare: In healthcare settings, IoT remote monitoring devices facilitate remote patient monitoring, allowing healthcare providers to monitor vital signs, medication adherence, and disease progression from a distance. This enhances patient care, enables early intervention, and reduces the need for frequent hospital visits.
Agriculture: In agriculture, IoT remote monitoring devices help farmers optimize irrigation, monitor soil health, track weather conditions, and manage livestock remotely. By providing real-time insights, these devices enable data-driven decision-making, resulting in higher crop yields and sustainable farming practices.
Energy Management: In the energy sector, IoT remote monitoring devices enable efficient management of energy assets, including power plants, substations, and renewable energy installations. By monitoring energy consumption, detecting anomalies, and optimizing resource allocation, these devices contribute to energy conservation and cost savings.
Logistics and Supply Chain: In logistics and supply chain management, IoT remote monitoring devices provide end-to-end visibility into the movement and condition of goods during transit. From temperature-sensitive pharmaceuticals to perishable food items, these devices ensure compliance with regulatory requirements, maintain product quality, and mitigate the risk of spoilage or damage.
Benefits and Advantages
The adoption of IoT remote monitoring devices offers a myriad of benefits to organizations across industries:
Real-time Visibility: Organizations gain real-time visibility into their operations, enabling proactive decision-making and rapid response to changing conditions.
Cost Savings: By enabling predictive maintenance, optimizing resource utilization, and minimizing downtime, IoT remote monitoring devices help organizations reduce operational costs and improve efficiency.
Enhanced Safety and Compliance: In industries where safety and regulatory compliance are paramount, IoT remote monitoring devices provide continuous monitoring and early detection of potential hazards, ensuring a safe and compliant working environment.
Scalability and Flexibility: IoT remote monitoring solutions are inherently scalable and adaptable, allowing organizations to deploy and expand their monitoring capabilities as needed, without significant infrastructure investments.
The Future of IoT Remote Monitoring Devices
As technology continues to evolve, the future of IoT remote monitoring devices holds immense promise.
Edge Computing: The integration of edge computing capabilities into IoT remote monitoring devices enables real-time data processing and analysis at the edge of the network, reducing latency and bandwidth requirements.
AI and Machine Learning: The integration of AI and machine learning algorithms enhances the intelligence of IoT remote monitoring devices, enabling predictive analytics, anomaly detection, and autonomous decision-making.
Blockchain Integration: The use of blockchain technology ensures data integrity, security, and transparency, enhancing trust in IoT remote monitoring systems, particularly in industries where data provenance is critical.
Interoperability and Standards: Efforts to standardize communication protocols and ensure interoperability among IoT devices facilitate seamless integration and data exchange, driving widespread adoption and innovation.
In conclusion, IoT remote monitoring devices represent a paradigm shift in how organizations monitor, manage, and optimize their operations. By harnessing the power of connectivity, data analytics, and intelligent automation, these devices empower organizations to achieve new levels of efficiency, safety, and sustainability in an increasingly interconnected world. As technology continues to advance, the potential applications and benefits of IoT remote monitoring devices are limited only by imagination.
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Which are the most important/common use cases of LoRaWAN?
LoRaWAN® has been employed in various IoT applications spanning multiple industries. In the forthcoming section, we will delve into the foremost real-world applications of LoRaWAN® that are essential for everyone has to be aware of. Even I’m not a professional expert in this field. But have to know some applications and knowledge about it:
Facility Management- Today, property managers and homeowners have the opportunity to enhance the efficiency of their properties while minimizing costs by implementing innovative IoT solutions based on LoRaWAN® technology. This can be achieved with minimal investment in infrastructure and maintenance.
These solutions allow for the control of various aspects, including motion detection, room occupancy monitoring, smart water metering, CO/CO-level monitoring, as well as temperature and humidity monitoring, among others.
Healthcare- The utilization of LoRaWAN®-connected IoT devices in healthcare settings enables the continuous monitoring of high-risk patients and medical systems, ensuring that the health and safety of individuals are never compromised.
This technology enables the reliable monitoring of vital signs in hospital patients, high-performance athletes, senior care recipients, and anyone else in need of real-time health support. This, in turn, greatly enhances the efficiency of doctors and healthcare providers.
Public Safety- In our current era, the importance of public safety and security has reached unprecedented levels. IoT network-based solutions offer first responders valuable tools to mitigate risks and optimize individual safety. This includes wearable IoT devices such as identification badges or systems equipped with panic buttons that can instantly transmit distress signals along with the user's location.
Space Optimization- The pandemic has accelerated the adoption of remote work, leading to extended periods of inactivity in office spaces within corporate buildings and urban areas. Managing and making optimal use of available space has become a logistical challenge for businesses.
LoRaWAN®-enabled IoT devices provide real-time insights into space utilization, allowing people to access workspace conveniently whenever they need it, eliminating the hassle of finding suitable workspaces.
Disaster Preparedness- Devices and gateways equipped with LoRaWAN® networks can continuously collect and transmit real-time data on environmental conditions. This technology can be invaluable in identifying potential concerns before disasters strike, helping protect communities from environmental threats.
Agriculture Advancements- Farmers worldwide are recognizing the importance of gaining insights, analyzing data, and making informed decisions about their livestock, crop yields, and equipment. With the assistance of LoRaWAN®-enabled IoT devices, they can effectively monitor and manage their agricultural operations.
These devices provide data on sunlight exposure, allow precise fertilizer application, and help maintain optimal temperatures for crops, ultimately enhancing agricultural efficiency.
Streamlined Logistics and Transportation- LoRaWAN®-based IoT devices have significantly improved supply chain management. Logistics companies can efficiently track high-value assets, even in transit through remote or challenging geographic areas, thanks to LoRaWAN®'s exceptional long-range capabilities.
Fleet Management Optimization- IoT-powered fleet monitoring solutions utilizing LoRaWAN® offer cost savings by enabling fleets to operate more safely and efficiently, leading to increased fuel efficiency and extended time on the road. Additionally, LoRaWAN® enhances visibility into maintenance needs, further enhancing overall operational efficiency.
Overview of IoT Connectivity with LoRaWAN® connects IoT sensors to the cloud, facilitating real-time data communication and analysis, ultimately boosting productivity and efficiency. These networks are particularly well-suited for wireless sensors due to their ability to transmit data over long distances.
LoRaWAN® sensors feature high-performance link margins, enabling them to transmit signals effectively even in environments with significant radio frequency (RF) noise interference. The impact of LoRaWAN® on the IoT landscape is remarkable, revolutionizing communication capabilities for various applications.
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Exploring the Internet of Things (IoT): Connecting the World
The Internet of Things (IoT) is a ground-breaking idea that is changing how we work and live. Connecting everything in our physical environment to the digital world goes beyond simply connecting computers and cell phones to the internet. We'll examine the Internet of Things (IoT) in more detail in this blog, including its functioning and effects on our daily lives.
UNDERSTANDING IOT
The key components of an IoT system include:
Devices and Sensors: These are the physical "things" that collect data. They may have built-in sensors, such as temperature sensors, GPS, or cameras.
Connectivity: To transmit data, these devices need to be connected to the internet. This can be achieved through various means, including Wi-Fi, cellular networks, or low-power networks like LoRaWAN.
Data Processing: Once the data is collected, it's sent to the cloud or a local server for processing. This is where the magic happens, as the data is analyzed, aggregated, and turned into actionable insights.
User Interface: The insights and information are made accessible to end-users through web or mobile applications.
Benefits of IoT
IoT offers a plethora of advantages:
Efficiency: Businesses can streamline operations and reduce waste with real-time data and analytics.
Cost Savings: By optimizing processes, energy consumption, and maintenance, IoT can save money in the long run.
Improved Quality of Life: IoT-enabled healthcare, transportation, and smart cities can make our lives safer, healthier, and more convenient.
CONCLUSION -
The Internet of Things is not just a trend; it's a technological revolution that's changing the way we interact with the world. From smart homes to connected cities, IoT is making our lives more efficient, safer, and enjoyable. However, it's crucial to address security and interoperability issues to unlock its full potential. As IoT continues to evolve, it's an exciting time to be part of this digital transformation. Whether you're a tech enthusiast or just an everyday user, IoT is impacting all of us, and understanding its potential and challenges is essential in our increasingly connected world.
#artificial intelligence#information technology#it services#it products#it technology#itservices#technology#internetofthings#internet of things#it solutions#video conferencing
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