I don’t mean to always sound like a 5G critic because over time 5G will vastly improve the cellular experience. However, many of the improvements being suggested by the cellular companies – like gigabit cellular service – may never happen. Of more immediacy is the fact that there won’t be any major improvements to cellular networks from 5G for at least 3 – 5 years. The carriers have the country and politicians fully convinced that 5G is right around the corner – but it’s not.
There was a recent article written by Sue Marek in FierceWireless that is a great example of why 5G is not going to be here tomorrow. Titled Network Slicing is a Security Nightmare for Operators, Marek explains how complicated it’s going to be to implement network slicing – perhaps the most important new aspect of 5G cellular service.
Network slicing is the ability of the cellular network to size the transmission path to exactly meet a customer’s bandwidth needs. Network slicing is one of the ways that will enable a cell site to communicate with many more customers at the same time. Today, every customer gets the same-sized data channel, meaning a lot of bandwidth is wasted when customers use less than a full channel.
Marek points out the difficult technical challenge for providing security for every slice of bandwidth. She says that getting this right is going to take two to three years. Until network slicing is viable there really is nothing that can be called 5G. The important takeaway from her article is how difficult it is to implement new technology. 5G is a drastic change from 4G in many ways. There are thirteen major changes in the 5G specification compared to 4G and implementing each of them will be a technical challenge.
What is annoying about the 5G marketing hype is that we’ve always known it would take up to a decade to fully implement 5G, just as it did to implement 4G. The cellular companies can’t seem to help themselves from overhyping new technology, but the 5G hype is many times worse than the 4G hype a decade ago. This mostly seems due to the fact that the cellular carriers decided to use the 5G hype as a way to cram through regulatory changes they’ve wanted for a long time. That forced them to really crank up the 5G rhetoric.
5G will take the same path used by all other electronic technologies – there is a tried-and-true method of introducing upgrades. New breakthroughs start in a lab. They then go to a ‘breadboard’ process where working models are developed. Once the breadboards have been thoroughly tested they go into prototype chips, which are then retested to make sure the performance made it through the conversion to silicone. Finally, the chip design is approved and the new breakthrough goes into production. At the very fastest this process might be done in 12 – 18 months, although this can take as long as three years. Breaking in new changes in the cellular world is doubly complicated because these same changes also have to be introduced into cellphone handsets.
The likely progression we’ll see for 5G is that some new aspect of the 5G specification will make it annually into chipsets. As that happens, only the newest phones will be able to use the upgrades, while earlier versions of 5G phones won’t recognize the new breakthroughs. The idea that the handset manufacturers are introducing 5G handsets in 2020 is laughable because practically none of the important 5G upgrades are yet in chip production. Those handsets will be 5G in name only (and still priced ridiculously high).
Marek is pointing out the complexity of getting 5G security right. There are dozens of other equally difficult technical challenges needed to fully realize 5G, and there are scientists in labs working on all of them. The labs will plow through all of this over time, and long after the hype is far in the past, we’ll get 5G phones that implement most of the 5G specification. It’s worth noting that there never may be a phone that meets the entire specification – because the specifications for a new technology are a wish list. It may turn out that some parts of the specification may never practically work in the field.