Skip to main content
  1. Home
  2. Phones
  3. Mobile
  4. Features

mmWave vs. Sub-6: The different types of 5G and how they work

Add as a preferred source on Google

If you’ve been keeping up on news about the next generation of wireless technology, 5G, you’ve likely come across the terms “low-band,” “mid-band,” and “millimeter wave” in your reading. But what do those terms actually mean? The answer provides a good overview of how 5G works, so we break it down in this guide to the different types of 5G.

If you want a full overview of 5G — from what it is to how it will be used — check out our in-depth explainer on 5G.

Recommended Videos

How radio wave spectrum works

Low-band, mid-band, and millimeter wave all refer to different segments of the electromagnetic spectrum. All three are within the radio wave range, but the spectrum also contains light, gamma rays, X-rays, microwaves, and much more.

U.S. 5G spectrum bands

  • Low-band: 600MHz, 800MHz, 900MHz
  • Mid-band: 2.5GHz, 3.5GHz, 3.7-4.2GHz
  • Millimeter wave (high-band): 24GHz, 28GHz, 37GHz, 39GHz, 47GHz

*Information courtesy of FCC.

In the radio wave range of the spectrum, things are pretty crowded. While radio spectrum is becoming increasingly dedicated to mobile devices, it also hosts broadcast TV, HAM radio, and aircraft communication, among other things. Radio spectrum ranges from 30 Hertz to 300GHz — 1 GHz being equal to 1 billion Hertz. That’s a pretty massive range, so it makes sense that spectrum at the far ends of that range act very differently.

Spectrum on the lower side, known as low-band, has longer wavelengths than spectrum on the higher side, which allows it to be more robust and travel longer distances at the expense of bandwidth. The waves get shorter and shorter through the mid-band frequencies, gaining bandwidth but losing transmission distance. Eventually, they reach millimeter wave.

The importance of millimeter wave

Millimeter wave has in its title a reference to the small size of its wavelengths, which range from around 10 millimeters to 1 millimeter. It’s an extremely effective swath of spectrum, with large bandwidth, but it’s also very sensitive to external variables — whether it’s walls, trees, or even just rain. Whereas low-band antennas are good for covering areas of up to several miles — whether it’s large patches of city, residential areas, or rural expanses — millimeter wave (or mmWave) makes more sense for small, targeted deployments such as inside a baseball stadium, or for fixed wireless in a specific area.

Image courtesy of Qualcomm. Image used with permission by copyright holder

Fixed wireless, or using wireless to replace wired internet, is actually one of the first use cases most carriers are attempting with 5G — and you can already find it available or launching soon from U.S. operators including AT&T, Verizon, and T-Mobile.

In addition to its larger bandwidth, one of the most exciting parts about mmWave for both telecommunications companies and consumers is the opportunity for larger channels of spectrum, which also aids in providing significant speed benefits.

Image courtesy of Cable Free. Image used with permission by copyright holder

Think of it like this: Rather than having several different narrow roads back and forth from your factory to the customer, wouldn’t it be more efficient to have a massive freeway? That’s the promise of mmWave, because it’s a relatively untapped resource. Until 5G, many in the industry were skeptical that such finicky spectrum could be put to commercial use in any sort of effective way. However, through the use of techniques like beam-forming (a method of focusing spectrum and shooting it directly at recipients), the engineers and scientists working on 5G have made it possible. And since there’s plenty of it to work with, telecoms can snatch up large contiguous sections of mmWave spectrum to create their data freeways.

Real world expectations

So what does all this mean? In a nutshell, tapping into mmWave was one of the biggest breakthroughs leading to the fifth generation of wireless, and it allows for some blazing fast, multi-gigabit speeds — but it’s early days yet. If you’re lucky enough to use mmWave in the next year or so, chances are it’ll be an intermittent experience on mobile, and it might drain your battery while it’s at work.

As for 5G on mid-bands and low-bands, improvements will be more incremental. The new wireless technology is more efficient than 4G LTE on existing bands, but not by a huge amount. 5G also is designed specifically to piggyback on the 4G network, with the aim of bolstering, rather than replacing, 4G speeds. Eventually, like any wireless technology, it will become dominant as carriers gradually upgrade their equipment, making for networks with much more consistently high speeds.

Ultimately, spectrum — and the need for more of it — is the major story behind the development of 5G. The early years of 5G may be bumpy (every wireless technology has had its awkward adolescence), but the opportunity these innovations afford are massive. With mmWave and improvements for low and mid-band spectrum, the future is looking more wireless data-focused than ever.

Rose Behar
Former Contributor
Rose is a contributor at Digital Trends, with a focus on Android. Her work also appears on Android Police and MobileSyrup. In…
5 reasons I keep coming back to Apple Reminders despite paying for premium task managers
I rely on OmniFocus for complex projects, but Apple Reminders still handles my everyday tasks better than any paid app.
Apple Reminders open on iPhone

The App Store is filled with premium task managers, and like Things 3, Todoist, and OmniFocus, despite buying and switching between several of them, I keep coming back to Apple Reminders. 

Don’t get me wrong, I still use OmniFocus to manage my projects. But when it comes to daily tasks and quick capture, Apple Reminders still remains my go-to app. In this guide, I'll walk you through the five biggest reasons why.

Read more
Google may finally ditch Samsung’s modem in the Pixel 11, and Tensor G6 could be better for it
FCC paperwork for Google’s next foldable points to MediaTek, raising hopes for lower power use and a cleaner break from Tensor’s Exynos roots
AI recreation of Pixel 11's Pixel Glow feature.

Google may be preparing its biggest Tensor hardware split yet. As spotted by Android Authority, FCC testing for an unreleased foldable Google phone includes a reference to MediaTek radio-frequency software, adding weight to reports that the Pixel 11’s Tensor G6 could leave Samsung’s Exynos modem behind.

Every previous Tensor chip has used Samsung modem hardware. Changing suppliers won’t guarantee better battery life or reception, but it gives Google a fresh path after years of leaning on the same underlying technology.

Read more
Apple’s iPhone Ultra could one-up the Galaxy Z Fold 7 with a bigger battery
4,883mAh total capacity, two cells, and two screens drawing power. Somewhere between "fine" and "I hope Apple's software does the heavy lifting."
Electronics, Phone, Mobile Phone

Apple's foldable iPhone is getting closer to its September announcement. Despite rumors of a delay, a recent report claimed that Foxconn is hiring temporary workers to ramp up production of the Ultra. Now we have a number for one of its most important specs: the battery.

I'll be honest: when I saw the battery figure, my reaction was somewhere between "that works" and "I was hoping for more."

Read more