IoT

The Internet of Things connects sensors, machines, and devices to networks so they can report data and be controlled remotely, underpinning applications from smart metering and asset tracking to industrial automation. Cellular IoT spans technologies from low-power NB-IoT and LTE-M to higher-bandwidth 5G, with new reduced-capability (RedCap) devices filling the gap between them. As deployments scale, the focus has shifted from connectivity alone to managing fleets of devices, securing them, and turning their data into value. For operators, IoT is a connectivity-plus-platform opportunity; for enterprises, it’s the foundation of connected operations. This channel covers IoT across cellular technologies, platforms, and industry verticals — including device classes, security, and data — with analysis of where connected-device deployments deliver measurable outcomes rather than stalling at the pilot stage.

Boingo Wireless marks 25 years of innovation in neutral host wireless networks, winning global recognition for private 5G, DAS, and Wi-Fi 6/6E/7 deployments across airports, military bases, healthcare facilities, and venues. Boingo’s converged architecture combines secure, high-performance wireless infrastructure with AI, zero-trust security, and green initiatives for future-ready connectivity.
The European Commission’s Digital Networks Act (DNA) is a sweeping proposal to harmonize telecom rules, catalyze next‑generation investment, and turn 27 national markets into a functional single market for connectivity. The DNA is timed to underpin an AI‑driven economy that depends on fiber, 5G/6G, and low‑latency cloud‑edge fabrics spanning borders. Longer licence durations and more flexible sharing are intended to reduce renewal risk and unlock investment in 5G densification and 6G prep. Mandatory national plans to phase out copper between 2030 and 2035 will free OPEX and energy, but require careful migration of regulated wholesale products, vulnerable users, and critical services.
Enterprises are moving fast to private 5G to digitize operations, but the payoff only materializes if security scales with the new connectivity footprint. Private 5G brings deterministic wireless to factories, hospitals, ports, and energy sites, connecting robots, AGVs, cameras, and critical control systems. Security must follow identities and workloads, not subnets. Adopt a Zero‑Trust approach aligned to NIST SP 800‑207 with a single source of truth for identity and policy. Shift from perimeter controls to context-driven segmentation. Build on open standards and APIs to avoid lock‑in and simplify operations. Security must be foundational, measurable, and auditable from day one.
The article examines:
The energy and thermal implications of rising compute density in data centers, Limitations of traditional air-based cooling at high rack power,
How direct-to-chip and immersion liquid cooling technologies improve heat transfer and energy performance,
Market, operational, and sustainability drivers influencing adoption in modern compute environments,
Broader implications for system architecture, infrastructure design, and future research directions.

Written as an objective, insight-led analysis rather than promotional content, the piece is designed to engage IEEE’s audience of computing researchers, systems engineers, and infrastructure strategists who are exploring how emerging cooling solutions intersect with future computing platforms and energy-aware design. The article is original and unpublished, and I’m happy to work with your editorial team to tailor it to IEEE Computer’s style and technical depth.
Jaguar Land Rover's Solihull plant is now a model smart factory, thanks to Ericsson's private 5G deployment. The high-speed, low-latency network replaces traditional Wi-Fi and wired systems to support real-time data, AI automation, and scalable production. With collaboration from Ericsson, Fujitsu, and Litmus, the project boosts operational efficiency and showcases how private 5G is transforming the future of automotive manufacturing.
Boingo deployed a private CBRS network at the Rhode Island Convention Center and Amica Mutual Pavilion to modernize venue connectivity for large-scale events. Integrating Wi-Fi 6 and CBRS, the system supports high-density operations like ticketing, POS, streaming, and IoT. The converged network enhances staff performance and fan experience while giving operators full control over wireless infrastructure. This project showcases how private networks can meet modern connectivity demands in sports and event venues.
Invences & Trilogy are advancing smart farming with FarmGrid, a platform powered by private 5G, digital twins, and edge AI. Deployed across North Dakota, Nebraska, and California, FarmGrid delivers real-time farm monitoring, improves agricultural productivity, and extends rural broadband access. Using Azure IoT, Open RAN, and edge computing, the platform connects farmers with actionable data and sustainable practices.
GMR Energy's private 5G journey showcases how industrial operators are solving real-world connectivity challenges. In a 3–4 sq. km energy plant, traditional networks fell short. GMR adopted private 5G and edge computing to deliver ultra-reliable, low-latency connectivity across EMI-heavy and safety-critical zones — enabling drones, AI, and real-time command centers. This case study explores both operator and integrator perspectives to show how private 5G becomes a scalable platform, not a point solution.
This article highlights the top 10 private 5G and LTE deployments transforming energy and utility operations globally. From U.S. electric utilities to offshore rigs and oilfields in Africa and Asia, these real-world examples show how private networks deliver secure, resilient communications that improve reliability, safety, and operational intelligence—laying the foundation for scalable grid modernization, edge analytics, and automation.
Winner – Private Network Excellence in Airports: NTT DATA, in partnership with Fraport AG, designed and implemented a large-scale private 5G network covering more than 20 km² at Frankfurt Airport. The 5G campus network provides secure, low-latency connectivity across the apron and perimeter where Wi-Fi is limited, enabling real-time data transfer, autonomous and remote operations, and a foundation for future airport digitalization. Nokia supported with private 5G RAN alongside NTT DATA’s architecture, deployment, and integration services.
Verizon Business has officially launched the Edge Transportation Exchange, a 5G and mobile edge computing-powered vehicle-to-everything (V2X) platform. Already in use by partners like Volkswagen, the Arizona Commerce Authority, and DelDOT, the platform enables real-time data sharing between vehicles, infrastructure, and road users. It supports critical use cases like pedestrian detection, traffic signal data, and weather alerts—without relying on expensive roadside hardware.
From Singapore to Schiphol, airports are embracing private networks for airports alongside AI and digital twins to drive operational efficiency, predictive maintenance, sustainability, and smarter passenger flows. This article explores 12 real-world deployments showcasing how private network deployments for aviation are shaping the future of Airport 4.0 globally.

Frequently Asked Questions

What’s the difference between regular IoT and ‘massive IoT’?
Regular IoT typically refers to a moderate number of connected devices with meaningful data needs, like security cameras streaming video, smart home hubs, or connected vehicles transmitting diagnostic and location data continuously. Massive IoT refers to a fundamentally different scale: enormous numbers, potentially millions, of simple, low-power, low-data sensors, like utility meters, environmental monitors, or asset trackers, that each transmit only small amounts of data infrequently but need to remain connected reliably and cheaply across very large device populations. The distinction matters because massive IoT requires network technology specifically optimized for extremely low power consumption and the ability to support enormous device density per cell, priorities that differ from the higher bandwidth and lower latency priorities of more data-intensive regular IoT applications.
Why does 5G matter for IoT specifically?
5G matters for IoT in several specific ways beyond simply being a faster network. It’s designed to support a far greater density of connected devices per square kilometer than 4G, which matters enormously for massive IoT deployments involving huge numbers of sensors in a concentrated area. It also offers specialized operating modes tailored to different IoT needs: extremely low-power modes for simple sensors that need to run for years on a single battery, and ultra-reliable, low-latency modes for mission-critical applications like industrial robotics or autonomous systems where a delayed connection could cause real operational problems. This flexibility, supporting both massive numbers of simple devices and demanding, latency-sensitive applications on the same network, is a meaningful architectural advance over earlier cellular generations.
What are the biggest barriers to wider IoT adoption?
Several recurring barriers continue to limit how quickly IoT adoption scales. Device and connectivity costs, while falling steadily, still need to make economic sense across potentially millions of deployed units for many proposed use cases, and even small per-device costs add up quickly at that scale. Security concerns are significant, since managing the security of huge numbers of distributed, often physically unattended endpoints is meaningfully harder than securing a smaller number of centrally managed devices. Fragmented standards across different IoT use cases can complicate interoperability between devices and platforms from different manufacturers. Integrating the resulting flood of IoT data into existing business systems and deriving useful insight from it remains a genuine organizational challenge even after connectivity itself is solved.
How do cellular IoT connections compare to alternatives like Wi-Fi or LoRaWAN?
Cellular IoT, using carrier networks like 4G, 5G, NB-IoT, or LTE-M, offers wide-area mobility and carrier-grade reliability without requiring an organization to build its own local wireless infrastructure, making it well suited for devices that move across large areas or are deployed in remote locations without existing local coverage. Wi-Fi can be cheaper for localized deployments within a single building where infrastructure already exists, but doesn’t provide the same wide-area mobility without significant additional infrastructure. LoRaWAN and similar low-power wide-area technologies offer very long battery life and decent range at low cost, attractive for simple, infrequent-data sensors, but typically can’t support the data rates or mobility that cellular IoT can, and often require organizations to deploy their own gateway infrastructure.
What industries are the biggest users of IoT technology today?
Manufacturing has been one of the most active adopters of industrial IoT, using sensors throughout production lines for predictive maintenance, quality control, and real-time process monitoring. Logistics and supply chain companies rely heavily on IoT for asset tracking, monitoring shipment location and condition, like temperature for perishable goods, throughout transit. Agriculture uses IoT sensors to monitor soil conditions, irrigation needs, and livestock health across large rural areas where cellular IoT’s wide coverage is particularly valuable. Utilities use IoT extensively for smart metering and grid monitoring. Healthcare is an increasingly significant adopter too, using connected medical devices and wearables for remote patient monitoring, an application where reliability and security carry particularly high stakes.
How is AI changing what IoT devices and networks can do?
AI is increasingly applied directly to the enormous volumes of data IoT devices generate, since manually analyzing data from potentially millions of sensors isn’t practically possible without automated analysis. AI models are used to detect anomalies in sensor data that might indicate equipment about to fail, to optimize complex systems like energy grids or supply chains based on real-time data from many distributed sensors, and increasingly, to run directly on IoT devices themselves through on-device or edge AI, allowing analysis and decision-making to happen locally rather than requiring every piece of raw data to be transmitted back to a central system. This local processing is particularly valuable where bandwidth is limited or sending all raw data back centrally would be impractical given the volume involved.
What is ‘NB-IoT’ and ‘LTE-M,’ and how do they differ from regular cellular connections?
NB-IoT, short for Narrowband IoT, and LTE-M, short for LTE Machine-Type Communication, are specialized cellular technologies designed specifically for IoT use cases rather than general smartphone-style connectivity. They prioritize extremely low power consumption, allowing devices to run for years on a single battery, and excellent coverage, including reaching devices in challenging locations like deep indoors or underground, over the higher data speeds standard cellular connections prioritize. The two differ in their tradeoffs: NB-IoT generally supports even lower power consumption and better extreme-condition coverage, suited for simple, infrequent-data sensors, while LTE-M supports somewhat higher data rates and mobility, making it better suited for applications like asset tracking that need to maintain a connection while moving.
What security risks are specific to IoT devices, and why are they considered higher risk?
IoT devices are often considered higher security risk for several specific reasons. Many are deployed in huge numbers across physically unattended or hard-to-access locations, making it impractical to manually monitor or service the security of each individual unit. Cost pressures in massive IoT deployments can lead manufacturers to cut corners on security to keep per-unit costs low, sometimes resulting in weak default passwords, infrequent software updates, or limited encryption. Because IoT devices are often deployed for many years without replacement, vulnerabilities discovered after deployment can remain unpatched for extended periods if devices lack reliable update mechanisms. The sheer scale of many deployments also means a single vulnerability could potentially compromise an unusually large number of devices simultaneously.

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