The highly speculating 5G network has arrived, it’s arrival will bring about great transformation in technology. It has been nearly a decade in the making, it is now a reality, the mobile 5G will start making appearances in cities around U.S in 2019, with much more improvements rollouts to be expected in 2020.
So many people will want to know more about the functionalities of 5G, right now it seems there are more questions about 5G than there are answers. People are wondering what 5G is, and can’t wait to have them in their cities and start using them in their smartphones.
Before we explain how 5G works, it’s probably a good idea to explain what 5G is. There are a lot of specifics, which we talk about later in this post, but here’s a quick primer.
5G is the next generation of mobile broadband that will eventually replace, or at least augment, your 4G LTE connection. With 5G, you’ll see exponentially faster download and upload speeds. Latency, or the time it takes devices to communicate with each other wireless networks, will also drastically decrease.
Now that we know what 5G is, it’s a good idea to understand how it works, since it’s different from traditional 4G LTE. From spectrum bands to small cells, here’s everything you need to know about the inner workings of 5G.
Unlike LTE, 5G operates on three different spectrum bands. While this may not seem important, it will have a dramatic effect on your everyday use.
Low-band spectrum can also be described as sub 1GHz spectrum. It is primarily the spectrum band used by carriers in the U.S. for LTE, and is quickly becoming depleted. While low-band spectrum offers great coverage area and penetration, there is a big drawback: Peak data speeds will top out around 100Mbps.
T-Mobile is the key player when it comes to low-band spectrum. The carrier picked up a massive amount of 600MHz spectrum at an FCC auction in 2017 and is quickly building out its nationwide 5G network.
Mid-band spectrum provides faster coverage and lower latency than you’ll find on low-band. It does, however, fail to penetrate buildings as well as low-band spectrum. Expect peak speeds up to 1Gbps on mid-band spectrum.
Sprint has the majority of unused mid-band spectrum in the U.S. The carrier is using Massive MIMO to improve penetration and coverage area on the mid-band. Massive MIMO groups multiple antennas onto a single box, and at a single cell tower, they create multiple simultaneous beams to different users. Sprint will also use Beamforming to improve 5G service on the mid-band. Beamforming sends a single focused signal to each and every user in the cell, and systems using it monitor each user to make sure they have a consistent signal.
High-band spectrum is what most people think of when they think of 5G. It is often referred to as mmWave. High-band spectrum can offer peak speeds up to 10 Gbps and has very low latency. The major drawback of high-band is that it has low coverage area and building penetration is poor.
Both AT&T and Verizon are rolling out on high-band spectrum. 5G coverage for both carriers will piggyback off LTE while they work to build out nationwide networks. Since high-band spectrum trades off penetration and user area for high speed and coverage area, they will rely on small cells.
Small cells are low-power base stations that cover small geographic areas. With small cells, carriers using mmWave for 5G can improve overall coverage area. Combined with Beamforming, small cells can deliver very extremely fast coverage with low latency.
5G USE CASES
The shift to 5G will undoubtedly change the way we interact with technology on a day-to-day basis, but it also has a serious purpose. It’s an absolute necessity if we want to continue using mobile broadband.
Carriers are running out of LTE capacity in many major metropolitan areas. In some cities, users are already experiencing slowdowns during busy times of day. 5G adds huge amounts of spectrum in bands that have not been used for commercial broadband traffic.
Expect to see autonomous vehicles rise at the same rate that 5G is deployed across the U.S. In the future, your vehicle will communicate with other vehicles on the road, provide information to other cars about road conditions, and provide performance information to drivers and automakers. If a car brakes quickly up ahead, yours may learn about it immediately and preemptively brake as well, preventing a collision. This kind of vehicle-to-vehicle communication could ultimately save thousands of lives.
Public safety and infrastructure
5G will allow cities and other municipalities to operate more efficiently. Utility companies will be able easily track usage remotely, sensors can notify public works departments when drains flood or street lights go out, and municipalities will be able to quickly and inexpensively install surveillance cameras.
Remote device control
Since 5G has remarkably low latency, remote control of heavy machinery will become a reality. While the primary aim is to reduce risk in hazardous environments, it will also allow technicians with specialized skills to control machinery from anywhere in the world.
The ultra-reliable low latency communications (URLLC) component of 5G could fundamentally change health care. Since URLLC reduces 5G latency even further than what you’ll see with enhanced mobile broadband, a world of new possibilities opens up. Expect to see improvements in telemedicine, remote recovery and physical therapy via AR, precision surgery, and even remote surgery in the coming years.
Remember Massive Machine-Type Communications? mMTC will also play a key role in health care. Hospitals can create massive sensor networks to monitor patients, physicians can prescribe smart pills to track compliance, and insurers can even monitor subscribers to determine appropriate treatments and processes.
One of the most exciting and crucial aspects of 5G is its effect on the Internet of Things. While we currently have sensors that can communicate with each other, they tend to require a lot of resources and are quickly depleting LTE data capacity.
With 5G speeds and low latencies, the IoT will be powered by communications among sensors and smart devices (here’s mMTC again). Compared to current smart devices on the market, mMTC devices will require fewer resources, since huge numbers of these devices can connect to a single base station, making them much more efficient.