Barring our constant debates on net neutrality, one of the places where the Federal Communications Commission has the largest footprint is with our wireless spectrum.
It’s a spectrum that has to serve many minders, and there are constant complaints about the spectrum being crowded. But those complaints, despite feeling modern and up-to-date, are far from new—we’ve been dealing with them pretty much ever since there was spectrum regulation.
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In fact those complaints actually led to the creation of such regulations in 1927, when the Federal Radio Commission was created.
The body, which provided the roots of the modern-day Federal Communications Commission, came about due to the Radio Act of 1927, a law enacted after it became clear that the Commerce Department had no real control over radio licensing.
In its initial annual report, the FRC noted the complexities of the radio spectrum were often underestimated by the public.
“The act embraces the whole field of radio communication, but public interest was concentrated almost wholly on the single section of it devoted to radio broadcasting,” the report stated.
And in many ways, it still is. With the need for better wireless devices crowding everything out, it’s worth pondering how we got to this point. Here’s how the wireless spectrum got busy.
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What crowded the wireless spectrum before smartphones, anyway?
We’ve always had trouble allocating wireless spectrum—the term for the different frequencies of electromagnetic waves which we use for different forms of wireless, or radio communication—in the right places. That’s in part because there’s only so much of it, and there’s always some random use case that we haven’t thought of.
In the 1920s, for example, major newspapers like The New York Times would rely on shortwave radio waves for news-gathering, and news groups called on the Federal Radio Commission to ensure that their access to their access to shortwave radio lines would continue unabated.
The spectrum problem only became more complicated over time. A 1950 article from Associated Press science writer Wayne Oliver spoke of the broad spectrum needs of the radio airwaves, “which includes television, short wave, transatlantic telephone, ship-to-shore, mobile telephone, wireless telegraphy, radar, and a host of other services.” (Yes, there were actually a few mobile phones at the time, generally in cars.) But the biggest space hog of the era is the one that was getting most of the attention at the time:
Of all these, television takes up by far the most space on the radio spectrum. That’s because of the tremendous number of impulses required to produce television’s 30 pictures a second. The engineers speak of it in terms of “information.” The more information you have to transmit, the more space you take up on the air—the more the traffic the wider the highway has to be.
And of course, the fact is that the United States isn’t the only country with spectrum needs, and there are parts of the airwaves that need to work between countries, such as shortwave radio, or maritime communication. An FCC report from 1949 lays out the depth of the issue:
The development of FM and TV broadcasting, the rapid growth of land mobile communication, the inauguration of microwave links for general radio communication relaying, the increasing use of electronic aids to air and sea navigation, and the expansion of Government radio services have all contributed to problems of frequency allocation in the upper part of the radio spectrum.
And, as the ether becomes more congested, interference grows in seriousness. That is why mutual working arrangements are being put into effect, not only between services, but between nations.
The international aspect of radio has developed to such an extent that the primary allocation of frequencies must now be made by treaty or other agreement. This will permit maximum radio use with minimum interference.
The burgeoning satellite industry complicated things further still. In a 1959 syndicated column on the issue, Dr. I.M. Levitt, the director of Philadelphia’s Franklin Planetarium Institute (and an early innovator on the subject of Martian time), highlighted concerns from Andrew G. Haley, the president of the International Astronautical Federation. Haley argued that an array of “baby” satellites would threaten the radio spectrum in the years to come, due to said satellites being put into the air without a way to turn them off.
“While the sputniks were in the sky the 20 and 40 megacycle bands were useless for certain periods of time. They have since been silenced. But as we have seen, the 108 megacycle band is cluttered up and will remain so for two centuries,” Levitt wrote.
(“Cycle” is an early term to describe wireless frequency units—with the term eventually replaced by “Hertz,” in honor of Heinrich Hertz, the man associated with the discovery of the electromagnetic wave in the 19th century.)
The satellite industry obviously evolved from there, pumping ever-more-sophisticated things through the spectrum—you know, like consumer internet, but also way beyond consumer internet. Ships need an easy way to communicate with the shore and to navigate the oceans. Astronomers need a way to see into space. And amateur radio operators deserve a spot in the spectrum, too.
Now take this already complicated state of affairs and add a whole bunch of smartphones to it—222.9 million, to be exact.
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“I thought Armstrong would invent some kind of a filter to remove static from our AM radio. I didn’t think he’d start a revolution—start up a whole damn new industry to compete with RCA.”
Damn Interesting*
The complicated map that lays out the myriad uses for wireless spectrum
Imagine, if you will, the world’s biggest Lego structure. There are a ton of blocks, and everyone wants one. Some of the blocks matter to just a few people. Others matter to just about everyone.
And there are certain “load-bearing” blocks that simply have to be there, that can’t move or something important will break. They’re glued into their current position, and moving them is going to be incredibly difficult.
But the problem is, there are some new blocks that are suddenly incredibly valuable, that need to get in—and it’s your job to figure out how exactly to do that, without knocking anything out of place, or at least putting much care into the blocks you are trying to remove.
That’s the game the FCC has long been playing with the wireless spectrum. Just check out this chart of frequency allocations, if you don’t believe me:
Does this puzzle look confusing? Just imagine the number of agreements, treaties, deals, and back-and-forth debating that went on over the past 90 or so years to get all of these spectrum blocks in place—along with how hard it is to win a new spot on the map.
(And the map, additionally, isn’t to scale: While the AM signals look like they take up a huge chunk of the spectrum map, it’s actually a microscopic part of the spectrum compared to the the parts at the bottom—the difference between a couple megahertz and hundreds of gigahertz. And the spectrums at the lowest levels have different technical properties from the ones at the highest, which is why 5G might be harder to pull off than 4G LTE was.)
Over the years, the FCC has put on a series of auctions that allow for different organizations to take control of different parts of the spectrum, something it was first allowed to do in 1993 as part of a budget bill. Often, the companies that fight for this spectrum are in the mobile phone sector.
There have been a number of these auctions over the years, most recently an auction completed in April in which T-Mobile alone purchased nearly $8 billion in wireless signal, a level that the company says covers every inch of the country.
T-Mobile CEO John Legere, who I have reached out to multiple times in hopes of interviewing him about his interest in slow-cookers, spoke with excitement about his company’s spectrum purchases.
“T-Mobile now has the largest swath of unused low-band spectrum in the country. That is a BFD for our customers!” Legere said in a press release. “Because T-Mobile customers will be able to speed on a brand-new, wide-open wireless freeway, while carrier customers have to crawl along on their clogged, congested low-band freeways.”
Of course, as I pointed out earlier, there’s only so much spectrum to go around, and when one piece of spectrum goes to T-Mobile, another piece of spectrum goes away. So who gave up? Well, a whole lot of UHF-band TV stations. These stations are going to have to find another place on the dial to hang out—some as soon as next year, others by 2020.
These Legos were the ones attached with glue, by the way, as lawyers with the powerful firm Pillsbury Winthrop Shaw Pittman recently argued on an industry blog.
“Given the FCC’s announcement that 957 stations will be involuntarily changing channels and that 30 more will be voluntarily moving to a VHF channel in return for an auction payment, the TV industry and its viewers are about to see a level of technical disruption that may be unprecedented,” the lawyers wrote.
It’s frustrating, but there’s only so much room, and something has to move.
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“Wireless spectrum has the potential to solve so many problems that have been so persistent in the 100 years of the phone system.”
discussing a shift toward making more room spoke frequently of a “spectrum crunch” some were skeptical was even a thing*
Sometimes, we get lucky and the march of technology changes the dynamic of the spectrum debate. The move toward converting television into a digital format, as painful and annoying as that was, is a great example of this in action.
Digital television simply doesn’t need as much space as analog TV ever did, which is why T-Mobile was able to buy a better network last month. As the push-and-pull over our limited amount of wireless spectrum rages on, we’re going to see more situations like this, where technology improvements that take up less spectrum room win out over prior technologies, and that incredibly confusing spectrum map inevitably gets reorganized.
But there are always strange edge cases. I recently pointed out one such edge case, involving wireless microphones in the United Kingdom. They’re supposed to have their own dedicated spectrum, but they keep getting moved around, in part because there are other things that need the spectrum more.
It’s a scarce resource. It may be all around us, but there’s only so much spectrum to go around.