A giant shipment enters a busy Belgian port where it is difficult to navigate in bad weather; However, the captain can rest assured that a remote pilot guides the shipment to a port.
In Germany, an automaker and an airline form intelligent personal networks to carry out off-site simulations and quality inspections, leveraging a virtual technique to reduce costs, time, and carbon footprint.
And on the other side of the world, in Japan, a mobile operator is introducing innovative, customer-centric use cases for the next generation of lightweight wearable devices, such as glasses.
These types of advances in network technology, fueled by the deployment of 5G, only scratch the surface of what is imaginable today, while giving us a window into what is coming soon.
In fact, smart grid developers around the world create smart programs that replace play.
As we move through the generations of networks (from the advent of 4G a decade ago to the current arrival of the 5G complex), we see how networks are much smarter and, at the same time, more powerful and secure.
Innovative developers are experimenting with how those smarter public and network functions can be incorporated into smarter applications. Let’s look at some examples.
The second largest port in Europe is located in Antwerp, Belgium. Located at the end of a tidal estuary, it facilitates connections across the country and continent via rail, roads, rivers, and canals.
When the ships arrive at the port, they will have to dock nearby and wait for an authorized captain to board; Only then will they be able to safely navigate the narrow and busy passage. Unfortunately, this can introduce other safety hazards and delays in port response times, which have an effect on port revenues.
Recent technological advances in networks and programs are this process.
Licensed pilots can now steer ships remotely into port from an offshore hub. 5G networks operated through Telenet in Belgium, a division of Liberty Global, provide on-demand location accuracy and network quality, working in conjunction with a ship’s multiple sensors and cameras. When a ship enters a geofenced area, the port’s 5G networks are dynamically activated via the remote app to adjust the bandwidth and latency needed to transmit high-resolution video, offering the remote captain much greater visibility and awareness. .
This software innovation, coupled with 5G, allows shipping companies to save time, fuel, and operator hours, while reducing emissions. Ports, in turn, are more productive and have faster response times. Faster.
Manufacturing and testing highly complex machines in a software-defined era is incredibly expensive and time-consuming. But two major global corporations are smart grids to make those processes much faster and less expensive, without compromising quality.
Audi’s testing facilities in Germany put its premium cars through rigorous protection and functionality tests. To reflect the network conditions of its key markets around the world, Audi recently implemented an intelligent personal network that reflects the driver and passenger experience. Through this network, Audi can reduce time and costs through simulation and testing software that provides voice, video, safety, autonomous mobility, vehicle-to-cloud communication, OEM-to-customer interactions, and cellular vehicle for everything (C- V2X). Features and functionality.
Similarly, Lufthansa Industry Solutions, a component of athrution giant Lufthansa Group, has deployed a wise personal network for detailed remote inspection of aircraft components. This not only saves time and costs similar to traveling to Lufthansa’s German site for inspections, but also meets regulatory needs to conduct inspections remotely over consistent, high-quality network connections. The company’s new smart network has capacity for more than 1,000 connected devices, helping Lufthansa achieve ambitious sustainability goals to reduce travel-like carbon emissions.
In commercial services around the world, testers can increasingly rely on the combination of on-demand bandwidth quality and location accuracy of smart grids. Thousands of sensors can seamlessly send data to create virtual twins that simulate conditions, allowing testers to enjoy the settings in the virtual global before deploying them to the physical global.
Nokia’s own factory in Oulu, Finland, has been chosen through McKinsey and the World Economic Forum as a complex beacon of the Fourth Industrial Revolution. This “factory of the future” leverages Nokia’s personal wireless networks (4. 9G/LTE), IoT analytics running at the edge of the cloud, and a virtual real-time double of operational knowledge to drive more than 30% productivity gains and 50% time savings. Delivery of products to the market and annual savings of several million euros.
Similarly, factories and oil and fuel fields are drones for remote inspection, along with video analytics on smart grids, a generation that allows them to inspect pipeline corrosion and even detect adjustments in smoke color that may simply involve protection or production issues.
Today, it is possible to participate in immersive game reports or host business meetings remotely thanks to 3D technology. But the procedure relies heavily on bulky, uncomfortable and expensive VR headsets.
The mass adoption of these devices – and the notable global impact they enable – depends on their ability to make them much lighter, more affordable and more energy efficient. One of the obstacles is the large amount of processing power required to generate realistic photographs with very low latency. But what if you could simply offload that processing nearby, reducing the load on the devices?
This is exactly what NTT is experiencing in Japan. In their labs, they are lately testing a “network computing architecture for 6G” (INC), which uses Core SaaS, providing network resources available for a software subscription model. This platform is specifically designed for use cases such as metaverse and AI-powered video streaming analytics, both of which require maximum processing power and incredibly low latency.
By dynamically offloading processing to the INC platform, the nearby 5G core, devices no longer need to do “heavy lifting” and can be optimized for weight, cost, and force consumption. Customers who use AR/VR applications on lightweight wearable devices, such as smart glasses, can now enjoy an especially enhanced user experience thanks to the smarter underlying network.
Perhaps the most promising thing about the future of smart grids is that we’ve scratched the surface of what’s possible.
Early hackathons and industry outreach efforts democratize the generation globally, opening the door for the world’s app developers to work their magic. In turn, this drives innovation and generates experimental programs that span a variety of use cases, from the medical box to lunar communications and more. .
As telecommunications networks become increasingly intelligent, we will continue to see leading commercial corporations and application developers employing complex network functions to replace the way our society builds, tests, and consumes the products that have an effect on the way we live and work.