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IoT Modules: Small, but perfect form for data tools
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TRB256 Industrial NB-IoT Gateway The TRB256 is an industrial 4G LTE NB-IoT gateway designed to be applied to a broad range of IoT solutions. The device is equipped with multiple WAN interfaces, such as I/Os, RS232, RS485, and an Ethernet port, additionally boasting dual SIM functionality for continuous connectivity.
For more information, Visit: https://www.newtrend.ae/ Live chat: +971 507542792
#TRB256#IndustrialGateway#NB-IoT#IoTsolutions#4GLTE#Connectivity#TechInnovation#IndustrialIoT#DualSIM#EthernetConnectivity#IoTDevices#RS232#RS485#TechSolutions#SmartDevices#Automation#NewTrend
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(2024-02-25 image #globalsign) There are a growing number of IoT devices being deployed in the UK and elsewhere. These can be weather sensors, lorry locations, smart meters the list is large. They have a demand to uplaod data 9small amounts) to a server periodically. To do this they will use the mobile phone network, often the standard mobile phone network. But our 4G / 5G networks are designed to cope with laptops, mobiles that have a high data demand, especially in download. These Iot devices have a different demand profile and it is a waste for them to occupy space on a network not designed for them. Additionally these IoT devices have much more limited energy supply, and this should not be wasted on a big protocol that is not really necessary.
LTE-M is a protocol that uses a narrow band to communicate data over the 4G network. It is used for IoT devices to communicate, upload and download small pieces of data to the cloud or other server in an efficient manner.
BT/EE has just launched a new network based on NB-IoT technology. [NB = Narrow Band] It works in a similar manner to LTE-M, used for IoT devices sending small amounts of data to and from a server. NB-IoT is a low power network and BT/EE will use their 1800MHz frequency to deliver this network. It will share this network with 2G / 3G / 4G and does not require a separate designated band.
As a long term plan NB-IoT and LTE-M are designed to take over the IoT connections currently resident on 2G allowing for 2G to be switched of at the end of the decade. Just to note that Vodafone have had their own NB-IoT network for a number of years. To use the network businesses (and it is businesses usually) need a separate NB-IoT or LTE-M SIM which are available from a number of third party suppliers. Your normal BT/EE or Vodafone SIM will not work! The network LTE-M or NB-IoT networks are likely to power the smart meters when the 2G network is switched off. Vodafone have a contract to develop such a network.
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O Desligamento das Redes 2G e 3G: Impactos e Oportunidades
Créditos: Freepik Entendendo o Desligamento das Redes 2G e 3G Nos últimos anos, testemunhamos uma revolução no mundo da tecnologia, e um dos avanços mais significativos tem sido a evolução das redes móveis. Agora, estamos diante de uma transição crucial: o desligamento das redes 2G e 3G. Essa decisão, liderada pela Anatel, é um passo natural no desenvolvimento tecnológico, mas não deixa de…
#Desligamento 2G 3G#Gestão de Conectividade#Impacto Empresarial#Inovação em Telecomunicações#IoT no Brasil#NB-IoT e CAT-M1#Plataformas M2M#Redes Móveis#Tecnologia Móvel#Transição Tecnológica
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#LPWA modules#Cellular LPWA IoT Modules#NB IoT Module#LTE module#LPWA Wireless Solutions#LPWA Modules for Industrial IoT#LORAWAN Modules#Lpwa modules nb iot
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Real Time Locations Monitor with GPS Shipping Sea Container Tracking
Lansitec Sea Container Tracking helps improve supply chain visibility, prevent cargo theft, detect mishandling, and ensure optimal container conditions. "Monitor sea container locations in real time with our GPS shipping tracker. Our advanced solution provides continuous tracking and accurate updates, ensuring complete visibility from departure to destination. Improve route efficiency, reduce delays, and enhance container security. Perfect for global logistics, our GPS tracker simplifies container management with long-range monitoring under any conditions.
For More:
#LoRaWAN GNSS Tracker#container gps tracking device#container tracking#Container Tracker#Industrial Tracker#GNSS Industrial Tracker#lorawan gps tracker#lorawan tracker#lora tracker#gps container tracking#GPS Outdoor Tracker#NB-IoT Tracker#battery operated gps tracker#gps tracking device with battery
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Narrowband IoT (NB-IoT) Chipset Market Size, Share, Industry Report & Trend Analysis
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LTE Cat M1 and NB-IoT Wireless Module Market
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Global Narrowband IoT (NB-IoT) Market - WishTree Insight
Global Narrowband IoT (NB-IoT) Market - Market Size, Share & Industry Trends, Growth Analysis Report by Product Type, By Consumption and Forecast 2022 – 2032. Narrowband IoT (NB-IoT) is a low-power wide-area network (LPWAN) technology that is specifically designed for Internet of Things (IoT) devices and applications.
For more details visit: https://wishtreeinsight.com/reports-details/global-narrowband-iot-nb-iot-market-wishtree-insight
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Water Metering: Competitive advantage for scaled IoT
#1-Wire#Bluetooth#Councils#gateway#LoRaWAN#Modbus#Municipalities#NB-IoT#Network#Predictive Analytics#Real-time#Scale#Supply#Utilities#Water Meter
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High-Quality Components for Reliable Telecommunication Networks
As a leading provider of RF Passive Products korea, Jtuscat offers an extensive range of high-quality components that play a crucial role in the efficient and reliable functioning of telecommunication networks. Their product portfolio includes filters, couplers, splitters, and other essential RF components designed to meet the unique requirements of various network configurations. With a commitment to quality and performance, Jtuscat has established itself as a trusted source for RF Passive Products, ensuring seamless communication across diverse network environments.
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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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How Smart Water Meters Help Save Water and Cut Costs
Water is one of the most precious resources we have, and managing it wisely has become more important than ever. As populations grow and cities expand, water demand continues to rise. At the same time, leaks, wastage, and poor infrastructure lead to major losses. This is where smart water meters come into the picture. These advanced devices are transforming the way we measure and manage water in homes, apartments, industries, and cities.
In this blog, we'll explore what smart water meters are, how they work, why they're needed, and how they connect with other technologies like smart irrigation system using IoT, smart water management using IoT, and IoT device management.
What Are Smart Water Meters?
A smart water meter is a digital device that records water usage in real-time and transmits the data to utility providers or users through wireless communication. Unlike traditional meters, smart meters don’t need manual reading. They provide automatic, remote access to accurate usage data, helping users track consumption patterns and detect leaks early.
These meters use sensors to measure water flow and often include embedded communication modules such as NB-IoT, LoRaWAN, or GSM to send data to a central system. The collected data can be accessed through apps, dashboards, or cloud-based platforms.
Why Smart Water Meters Are Important
Accurate Billing: Traditional meters are prone to human error and estimation-based billing. Smart meters eliminate these issues by providing exact consumption data.
Leak Detection: If there's an unusual spike in water use or continuous flow when no one is using water, smart meters can alert users, helping detect leaks early.
Water Conservation: When users can track their real-time usage, they tend to be more conscious about saving water. It promotes responsible consumption.
Operational Efficiency: Water supply boards and utilities can remotely monitor thousands of meters, saving time, reducing manual labor, and minimizing human errors.
Data Analytics: The usage data collected can help authorities plan better infrastructure, manage supply and demand, and even detect non-revenue water losses.
How Do Smart Water Meters Work?
Smart water meters work in three main steps:
Sensing: A flow sensor inside the meter continuously monitors the amount of water passing through the pipe.
Processing: A microcontroller processes this data and stores it temporarily.
Transmitting: The device then sends this data wirelessly to a centralized cloud or local system for further analysis.
The communication technology used depends on the application. For example:
NB-IoT or GSM is preferred for wide-range, city-level smart meter networks.
LoRaWAN is used in large apartment complexes or gated communities.
RF or Zigbee can be used in smaller residential buildings.
Key Features of Smart Water Meters
Real-Time Data Collection
Wireless Communication
Leak and Tamper Alerts
Battery Operated (with 5-10 years of life)
Mobile App or Web Dashboard Access
Compatibility with IoT Platforms
Smart Water Meters in Apartments and Communities
In large housing communities, manual meter reading is time-consuming and often inaccurate. With smart water meters, every flat or villa can have its own unit, and data can be collected from all homes automatically.
Some benefits include:
Individual billing based on actual usage
Fair water cost sharing
Quick identification of leakages
Encouragement of water-saving habits
They also allow integration with IoT device management systems to ensure smooth operation, firmware updates, and remote troubleshooting of meters.
Smart Water Meters in Agriculture
Water wastage in agriculture is a major concern, especially in India. Farmers often overuse water due to the lack of proper data. When paired with a smart irrigation system using IoT, smart meters help monitor the exact quantity of water used for each field.
This brings multiple benefits:
Prevents over-irrigation
Saves energy and water
Improves crop yield
Enables remote control and monitoring
A farmer can now view water usage trends on their phone and adjust the irrigation system from anywhere, ensuring optimal usage.
Smart Water Management Using IoT
Smart water meters are a crucial part of the broader vision of smart water management using IoT. Here's how they fit into the system:
Monitoring: Real-time tracking of water consumption from multiple sources – residential, commercial, industrial.
Integration: Working together with pumps, valves, storage tanks, and irrigation systems to create an interconnected water network.
Analytics: Providing data to predict consumption patterns, forecast demand, and plan maintenance.
Decision Making: Alerts, automated shutoffs, and recommendations based on usage data help authorities make informed decisions.
Cities like Chennai, Pune, and Hyderabad are already seeing benefits from smart water metering systems under smart city projects and government initiatives like AMRUT.
Common Communication Technologies Used
NB-IoT (Narrowband IoT): Ideal for large-scale deployment. Offers low power consumption and long-range connectivity.
LoRa/LoRaWAN: Cost-effective for communities, farms, and campuses.
RF (Radio Frequency): Best for small areas or closed networks.
GSM/4G: Simple, works anywhere with mobile coverage.
Each has its advantages depending on scale, budget, and terrain.
Challenges in Implementation
While the benefits are clear, the adoption of smart water meters in India and other developing countries faces some hurdles:
Initial Cost: While long-term savings are significant, the upfront cost can be a barrier.
Awareness: Many users are still unfamiliar with how these devices work or the benefits they offer.
Infrastructure: In older buildings or rural areas, connectivity and plumbing might need upgrading.
Data Privacy: Users may have concerns about how their consumption data is used and stored.
With the right awareness and support, these challenges can be overcome.
Role of IoT Device Management in Water Metering
Large deployments often involve thousands of meters spread across cities. Managing each of them manually isn’t possible. This is where IoT device management becomes important.
It enables:
Remote configuration and control of meters
Real-time performance monitoring
Battery health checks
Firmware updates
Error detection and troubleshooting
Without proper device management, the reliability and success of smart water meters at scale can be difficult to achieve.
Future of Smart Water Meters in India
India is moving towards digitization in every sector, and water management is no exception. Smart water meters are already being adopted in many smart city projects. Government initiatives and sustainability goals are pushing water boards and municipalities to move away from manual readings.
In the coming years, we can expect:
More public-private partnerships for meter deployment
Integration with solar-powered systems in rural areas
Advanced analytics for predictive maintenance
Better support for multi-lingual mobile apps and dashboards
As more cities embrace smart water management using IoT, the role of smart meters will continue to grow.
Conclusion
Smart water meters are more than just tools to measure water usage, they are the foundation of a smarter, more efficient water management system. From reducing water waste to enabling fair billing and supporting larger IoT ecosystems, these meters are shaping the future of water conservation.
When combined with systems like smart irrigation system using IoT, smart water management using IoT, and efficient IoT device management, they can help tackle one of the most pressing challenges of our time, sustainable water use.
For homes, apartments, farmers, and governments alike, smart water meters offer a clear path to better water control, accountability, and long-term savings.
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ESP32 Embedded Development with Cellular Technologies: A Technical Report
Explore comprehensive insights into ESP32 embedded development with cellular technologies, including LTE, NB-IoT, and LTE-M integration, hardware options, software stacks, real-world projects, and best practices for IoT applications.
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How Startups Can Use an IoT Cost Calculator to Secure Funding
In today’s tech-driven landscape, IoT (Internet of Things) is no longer a futuristic concept—it's a thriving reality. From smart home devices and wearables to industrial sensors and healthcare monitors, IoT is transforming the way we live and work. For startups aiming to enter the IoT market, the biggest challenge is often securing funding. And here’s where an IoT Application Development Cost Calculator becomes a powerful ally.
Many investors hesitate to fund early-stage IoT projects due to the perceived complexity and cost uncertainty. But when startups use tools like an IoT cost calculator, they demonstrate not only financial foresight but also strategic thinking. That’s a major win in the eyes of potential investors.
In this blog, we’ll explore how startups can leverage an IoT cost calculator to prepare for funding rounds, craft more accurate business models, and increase their chances of attracting the right backers.
The Funding Challenge in IoT
Unlike mobile apps or SaaS platforms, IoT solutions often involve a mix of hardware, software, and cloud infrastructure. The capital requirements can be significantly higher, and the development cycle is often longer. For early-stage startups, this complexity makes it harder to:
Forecast costs accurately
Pitch a viable ROI to investors
Scale operations with limited resources
Investors want clarity. They want to know where their money is going, what milestones will be achieved, and how long the runway is. Using an IoT Application Development Cost Calculator helps break down these costs and present a realistic picture of what's required to bring the product to market.
What Is an IoT Cost Calculator?
An IoT cost calculator is an online or software-based tool that estimates the cost of building an IoT application based on various parameters, such as:
Type of device (wearable, industrial sensor, home appliance)
Connectivity protocol (Bluetooth, Wi-Fi, NB-IoT, etc.)
Cloud infrastructure and storage needs
Backend and mobile app integration
Security and compliance features
Maintenance and support
By inputting project-specific details, startups get an estimated budget, which they can then include in pitch decks, financial projections, or funding proposals.
How a Cost Calculator Helps Secure Funding
1. Demonstrates Due Diligence
Investors look for founders who understand their business from top to bottom. A cost calculator shows that you’ve done your homework and are not just relying on vague ballpark figures. It gives your financial plan credibility.
2. Enhances Your Pitch Deck
Your pitch deck isn’t just a place to show off your product—it’s where you prove you’re ready to run a business. Including an itemized budget from a trusted cost estimation tool strengthens your business case and helps you stand out from the competition.
3. Supports Financial Modeling
You’ll need to build multiple financial models: best-case, worst-case, and break-even. A reliable cost estimate helps you simulate all three with confidence. It also allows you to plan for different funding scenarios and investor demands.
4. Guides MVP Development
With a clear understanding of where the money goes, you can build a Minimum Viable Product (MVP) that fits both your budget and your goals. This strategic planning is something investors love to see.
Book an Appointment to Validate Your IoT Budget
Thinking about pitching to investors or planning your IoT product launch? Don’t go in blind. Our experts offer a free 30-minute consultation to help you validate your cost estimates, refine your pitch, and align your tech stack with investor expectations.
👉 Book an Appointment Now and take the first step toward funding your IoT vision.
Real-World Example: Startup X
Let’s say a startup is developing a wearable device for real-time health monitoring. They use an IoT cost calculator to estimate:
Hardware costs: $50,000
Firmware development: $30,000
Backend and mobile app: $60,000
Cloud hosting and data security: $20,000
Testing, certification, and support: $15,000
This results in a $175,000 estimate for the MVP. They use this figure in their funding pitch to angel investors, along with a timeline and milestone-based budget breakdown. The clarity and transparency impress the investors, and they secure an initial seed round of $250,000—enough to build and test their first prototype.
What to Look for in a Cost Calculator
Not all calculators are created equal. A good IoT cost calculator should:
Be customizable to your project type and scope
Offer breakdowns across development phases
Include both hardware and software costs
Reflect current market prices and development trends
Offer exportable reports for investor presentations
Ideally, it should be paired with a consultation service to help you interpret the results and refine your estimates.
Final Thoughts
Startups in the IoT space are uniquely positioned to create disruptive products—but with that opportunity comes the challenge of winning investor trust. By using tools like an IoT Application Development Cost Calculator, founders can present a clear, data-driven plan that speaks directly to what investors care about: return on investment, scalability, and cost control.
Whether you're building a smart home device, a healthcare wearable, or an industrial sensor platform, you’ll need a team that not only understands the tech but also understands how to bring it to market. That’s why choosing the right IoT app development company is critical to your success.
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