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About Massive MIMO Beamforming

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What is Massive MIMO Beamforming?

Let’s put them together, beamforming and massive MIMO, and we get massive MIMO beamforming. This combination of great ideas and technology allow us to go beyond what has been done in the past.  It takes all the antenna elements to work together and separately to create 3D beamforming and with over 32 elements to push data and coverage to the outer limits. Read on to learn more.

Coming soon, the “Road to 5G” book with reports on Massive MIMO, Beamforming, and more about the trend of the tech industry.

To recap:

  • Massive MIMO is where the elements in the antenna each have an individual radio head feeding them, could transmit or receive or both (TDD).
  • Beamforming is where the beam focuses the “transmit” and/or “receive” in one specific area to avoid interference from outside sources and to increase gain and throughput.

In Massive MIMO they use 3D beamforming. This focuses the beam both vertically and horizontally. It is going to allow the element to talk to specific users if they need to. It allows the RF to focus on one area while the other elements can focus on other areas. It increases coverage and densification without moving an antenna or dropping in a small cell. WOW!Get the Wireless Deployment Handbook today!

Learn more in a blog about Massive MIMO, found here, https://wade4wireless.com/2017/11/27/what-is-massive-mimo/. Then, read the blog about beamforming, found here, https://wade4wireless.com/2018/01/08/what-is-beamforming/.

How is it done?

How can they do that? With a control beam that can track where a user is located. This was brought to light with MU-MIMO, Multi-User MIMO. It allows the elements to talk to more than one user at a time. Mainly because you have so many elements that are readily available to focus on users.

Can you imagine where you have more carriers and spectrum to communicate to the UE device? Not only that, but each element can talk to a device while the next element can talk to another simultaneously. All at the same time, using different chunks of the same spectrum along with 64 or 256 QAM. It’s really amazing, so much so there is no way I can explain how it works in detail. Sorry, look at the resources below to learn more technical details.

Here we’ll learn the high-level overview. The RF will be able to be utilized more efficiently than ever because it will be focused in a very concentrated area while other elements can concentrate on their specific users.

Please note, there is SU-MIMO, Single User MIMO, I don’t talk about that here because I think the key is to talk to as many users as possible at the same time.

While Massive MIMO Beamforming is thought of like a 5G technology, it can be and will be used in LTE. They will call it LTE Advanced, LTE-A, but really it’s LTE evolution to get more throughput. It is a critical factor in getting to 5G, so it is going to be part of the NR, New Radio. (New Radio, not a creative name at all!) I think it’s important to remember that all of these advances in LTE will be a foundation of what’s to come for 5G, but I digress, let’s get back to massive MIMO Beamforming.

Massive MIMO paves the way for 3D beamforming for several reasons. First, it’s an active antenna that has a radio head dedicate do each element. This makes it exceptionally smart. Second, it has fiber and power to the antenna which has embedded antennas, so the electronics of the element allow it to focus energy the way the radio head sees fit. That means this can pick a user, focus all of its energy on that user, and slice out RF for that user, and communicate directly with that user.

Why is the last statement so important? I am glad you asked! It’s because the UE Device doesn’t need to match the MIMO of the transmit antenna. I don’t see SAMSUNG and APPLE putting in 32 or 64 antennas on their smartphones, do you? I know they’re getting bigger, but we’re lucky they put 4 in each one. Not only that, but they have to put a crapload of RF chips in each device to handle any carrier. It’s a lot to ask of a smartphone, yet we expect it today, don’t we? Don’t deny it! You would be pissed if you couldn’t take your device and use it on another carrier or maybe even in another country. Now, pile that on top of all the formats they need to communicate, like GSM, CDMA, LTE, TDD. To make it simpler for you, 3G, 4G, Wi-Fi, and soon 5G. Yowsa that is a lot to ask of that device that used to fit in your hand. Now we want them bigger, but not too big!

What made all of this possible? The OFDM format, it helped us build to what we have today. The other thing that helps is beam tracking. The beam can track where the user is and where they are going to keep the RF concentrated on that user, beam steering.

Why does it matter?

Why does massive MIMO beamforming matter? You ask some great questions! It matters because where we once thought that the antenna would just point to where we thought we needed the coverage. Then we had MIMO to allow us to pass more data simultaneously to a user, but it was really SU-MIMO passing more than twice the data to an individual user. We also had beamforming, used heavily in TDD, like Wi-Fi, to reduce interference and concentrate that low power signal to where the users were. Lower interference and increase gain to the user.

Now, on the road to 5G, we have mutated all of this to something extreme. You know, like the X-Men, we have LTE and RF superpowers! The superpower to increase coverage and densification using the antenna and the radio and the electronics to make one antenna do the job of 32 or 64 or even 128 at this time. Who knows what the future will hold.5g-deployment-plan-front-cover-3k-pixels

With beamforming you can concentrate the signal to one user, increasing the gain of that element and talk to one user while the elements are talking to another user.

Does this save money for the carrier?

Trick question! I wanted to see if you were paying attention here, so I threw in a trick question to make sure your on your toes and wearing your thinking cap.

It will cost money up front. The carriers have to replace the antennas and the radio heads. They now have to install the massive MIMO antennas. They have to run fiber and power to the antenna because it no longer has the radio head broken out. It is all one unit. They have to upgrade their BBUs, I would think, and upgrade the backhaul, (fiber) so that they can deliver 10Gbps to every macro site, maybe 100Gbps. Because now you could have 64 users all crying for 1Gbps to each device.

Up front, they have to replace hardware, install new units, and replace most everything at the cell site. Up front, it’s more money.

OpEx will increase for the backhaul. They will need more fiber, more bandwidth, more monthly cost on the backhaul

Now, it will save money in the long run. Here is what I see and it’s not as clear as I would like to make it. Please, use your imagination, will you?

The savings will be that the macro site can now supply well over 10 times the users it could before. In urban areas, this is a game changer! What does this mean? Fewer small cells to be deployed for offloading! If you have a kick-ass macro site throwing data out to many users simultaneously, who needs those pesky small cells in the same coverage area as the macro site? If you don’t think this is a thing, look at any carrier in NYC or LA, they have to offload everywhere. This can start to decline.

Coverage improves as the elements offer higher gain to individual use. This is a small gain, but the edge of the macro should see better coverage as well as throughput. Again, better handoffs and fewer small cells on the edge.

The equipment is smaller than before, and you eliminate the need for the radio head and all that annoying coax between the radio head and the antenna. You heard me! One unit, an active antenna that eliminates the need for coax at the site. This means no more Passive Modulation Interference from all those coax connections. Don’t you hate doing all the PMI testing at the site? I do, and it costs a lot of money, and there is no guarantee that it won’t happen 3 days after you leave the site. Yes, PMI sucks!

Smaller equipment at the site means that it could save the carrier money on-site rental. However, I have to tell you, ATC and CCI have ironclad leases. This is more of a pipe dream. One thing I learned is that the tower owners will NOT lower rent, they only increase rent, and they have leases so tight that Houdini could not get out of one. The thing it may hurt is the small cell leases. If the macro is kicking ass in coverage and loading, maybe a carrier could eliminate some of its small cell sites. That is a considerable cost saving when you look at the backhaul and rent. The equipment and installation are cheap, but the fiber costs are still pretty high.

Who will roll this out?

I have to tell you, the best way that I see massive MIMO beamforming rolling out is by using TDD. It’s cost effective and eliminates the need for separate transmit and receive elements. That means that if you use FDD, you would need 64 transmit and 64 receive elements in one antenna. Ouch, that just got really expensive. But wait, if you have TDD, then you could use 64 elements because the transmit and receive are shared in the same element.

Now, who has TDD in the USA? Can you guess? Go on. I’ll give you another minute. That’s right; Sprint has a crapload of 3.5GHz spectrum that is all TDD that is no longer Wi-MAX. In fact, they are migrating to LTE everywhere. They have a prime opportunity to roll out an incredible system. Will they do it? I hope so, but only time will tell.

That is why the other carriers are clamoring for mmwave and cmwave so that they can also have this technology. Does that make sense?

For this reason, I see Sprint winning this race, if they can get out of their own way. they have not made the best tech decisions in the past decade, in my opinion. Keep the deployment simple, get the teams on the same page, and for GOD’s sake, align with your vendors.

What spectrum will use this technology?

Another good question. It appears that 2GHz and up will work well for this. That means Sprint has prime 2.5GHz spectrum that aligns well with this technology.

The CBRS, 3.5GHz is well suited for this technology. While it is low power, this offers great control to allow the carriers to get the biggest bang for their buck. The lightly licensed users may not use the technology because of price and payback. Usually, private LTE networks won’t invest in anything this impressive, (code work for expensive).

It looks like the 4.4 to 4.9GHz spectrum is also ideal, good news for Japan!

Above 20GHz, where the mmwaves live, it looks to be ideal. So, when AT&T and Verizon start pushing this envelope, they will rely on this technology to deploy. Why, because the massive MIMO will allow them to cram a lot of elements into one antenna. You see, at that spectrum, the antenna elements are tiny, so they could see antennas with a high count of elements. I would think they would see 128 by 128 for almost everything. It would be a game changer, especially for fixed wireless.

Summary:

This new technology takes what the OEMs learned form MIMO and beamforming and put it together to create a new type of macro site. This makes the antenna a team player getting the signal to the end-user in the most efficient way possible. The elements of the antenna each have their own radio head and control. Using this technology to create parallel RF streams of data to the user increases throughput and loading all at the same time. That is what I call smart technology.

We have an active antenna that can do massive MIMO and 3D beamforming all controlled by a base station with even more features in it like carrier aggregation, higher throughput, more carriers, and advance interference rejection. All that and coverage improves, better densification from one BTS. WOW! We’ve come a long way, baby.

All of this so that the throughput and use loading goes way up.

I have it listed in the resources section, but a good paper on this has been put out by Nokia at https://onestore.nokia.com/asset/201377/Nokia_5G_Beamforming_mMIMO_White_Paper_EN.pdf if you have time to read it.

What can you do?

Prepare for this new technology! Come on, all the cool kids are learning it. The OEMs are relying on this as a precursor to 5G for whatever the carrier plans to use it for. What services will be needed for this? Let me count the ways:

  • RF Design – to deploy, it needs to be planned out properly to avoid self-interference.
  • Installation of new material.
  • Site engineering.
  • Commissioning, Integration, Testing, Optimization all done for the new sites.
  • Drive testing to verify it works the way we all hope it works.
  • Then, self-optimization should start cleaning up the services.
  • Then the end users will have to evaluate how awesome it is.
  • Then the carrier can start re-evaluating the use of small cells.

Resources:

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What is Beamforming?

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Antenna’s that can control their own beam shape, what?!? Control the beam on demand? How can that be? Beamforming is a little more complicated than that.

First, a quick, high level, history lesson.

I don’t know how familiar you are with antennas, but they must be installed correctly. You could physically tilt the antenna a few degrees to match your coverage. It’s like azimuth, that must be appropriately aligned for coverage. Older antennas were installed with a set “up tilt” or “down tilt.” They were fixed in tilt and azimuth. So, what they saw is what they heard, based on the antennas fixed pattern. The antenna pattern would determine what the antenna could hear and talk to. That was it, very simple. I know, there is gain, but for the sake of argument, let’s say they would talk to UE devices in their specific coverage area.

Then there was evolution! There were new ways to control tilt. CommScope had RET, Remote Electrical Tilt, for this purpose. I think it was a good idea, but it’s still a physical system. Basically, if I understand this, it’s an actuator that can change adjust the tilt + or – 3 or more degrees. However, it opened options to the end-user, the carriers, where they did not need a tower crew to adjust the tilt. Pretty cool!

How does it work?

Now a new type of evolution, beamforming!

With beamforming, none of the physical alignment goes away; we still need the proper tilt and azimuth to get started. Beamforming is done by very smart antennas, but the carriers did not have the corner on this technology. As a matter of fact, the Wi-Fi vendors have made significant advances in this technology. They did a great job getting 802.11 to do this. The BTS controls the beam from there so that the antenna can do its thing. Again, they all must work together to make this happen.

Where did this idea come from? Don’t let the carriers or OEMs fool you; it came from Wi-Fi. In fact, I believe one of the pioneers in beamforming was Ruckus! That’s right, the carrier-grade Wi-Fi OEM. Also, I must give credit to Linksys for putting the technology in their home Wi-Fi routers. Awesome! Thank you to Network World for making a video on this, (link is below in “Learn More” section).

Massive MIMO puts that on steroids. It takes the signal, both ways, and focuses on a user. If you have 64 by 64, then, in theory, you can focus on 64 individual users on that antenna. The idea is to hear users you want to hear at any moment. This allows the radio to talk to specific users simultaneously without sharing precious spectrum. How can they focus?  Beamforming is how they do it. They employ a technique called 3D beamforming that dimensions the signal from that element in 3D, 3 dimensions. Beamforming will focus the beam on the specific user.

Now the carriers are asking the OEMs to take it to the next level. It is the cornerstone of making massive MIMO even more useful.

You see, massive MIMO relies on the beamforming technology to make it more efficient and push even more bandwidth through it! It is a crucial factor, like carrier aggregation. It all has to work together.

Now, by controlling the beam to match the user’s antenna, it becomes more efficient in several ways. Signal strength helps, but now the spectrum stream can be dedicated to that specific user the duration of the conversation. Not only the best signal possible but a dedicated conversation with that unit for a limited time.

Massive MIMO takes this to a new level. Now the angle of delivery can be controlled. WOW! That is specific to the user based on each element. Assuming it really works that way, the antenna will have to be smart. This is called 3D beamforming, looking at all 3 dimensions. It’s steering the beam to match the end-user, basically taking a lobe that focuses all 3 dimensions to the user’s antenna. Almost like a microwave shot to the antenna. Beamforming is shaping the beam to match that of the UE device. The antenna will narrow the beam so that it is only talking to the device or devices that you want it to talk to and not the surrounding units.

That makes the antenna elements very efficient. This increases the number of devices the antenna can talk to as well as increasing the throughput to each device with a dedicated stream from each element.

Remember that the antenna will need power now since the radio heads are in the antenna and the elements need to be agile. The elements will control the beamforming, and they need to have control signals sent to them. It’s a whole new level of technology.

MIMO helps to utilize beamforming by using the radiators in the antenna to focus on specific users and not “hear” everything. That’s the key, listen to what matters and forget the rest.

By the way, if you want to get technical. Try one of the links below. I am providing a view of what a field worker would need to know. If you’re in a classroom or device design, research the details. I just need to know how it’s going to work with massive MIMO and in the real world. I am in the real world of deployment, that’s what I worry about. If you want to see more detail, I would start here, http://home.iitk.ac.in/~javeda/PhD_SOTA.pdf to learn more.

Why does it matter?

The OEMs figured out that if Wi-Fi can use beamforming so efficiently for license free, then there must be something they can use it for licensed spectrum. At first, it didn’t seem like much because the carriers are always listening for subscribers. Then came MIMO, and suddenly it seemed like a game changer.

With MIMO they would use the spectrum more efficiently, especially using OFDM. Then they would pass more data, more bandwidth in the same spectrum, awesome.

Now, enter massive MIMO, the big daddy of antennas and data throughput. It’s a landslide of data that can use the spectrum efficiently to more than 32 users simultaneously! It makes the 8×8 MIMO look pathetic!

It matters because to get the data throughput we all crave to multiple used efficiently in the spectrum we have; we need to utilize every tool we can, like MIMO, carrier aggregation, and beamforming. Although, no one will mention beamforming when discussing massive MIMO because it’s expected to be there. In fact, it’s what makes MIMO so impressive! (In my opinion.)

What spectrum does beamforming work in?

As far as I can tell it works me any spectrum. There are arguments to put it on the higher spectrum, but the reality is that I have read reports that it will work in 2GHz to 70GHz. I mean it works in Wi-Fi. What I don’t know is if it will work below 1GHz. I see that many say sub 6GHz, but I haven’t read about anyone using it below 2GHz, to be honest.

I think the carriers will get it working on all their spectrum; they need to get it rolling. Whether it’s FDD or TDD, it will be the foundation for massive bandwidth to the end-user. It’s a matter of how to reach the user.

Who will use it? (Looking at the USA only.)

You mean after all the Wi-Fi vendors? They are already using beamforming and, massive MIMO because it really helps throughput. Then the carriers are all going to use this. It means changes at the sites. New antennas, upgraded BTS systems, and even backhaul and fronthaul upgrades. This all must be upgraded.

They all want it though, they all want to serve the public. The question is how? Anyone working with massive MIMO will use beamforming. Beamforming is a hidden X-factor. As I have been telling you, massive MIMO is a huge stepping stone towards 5G evolution. Whether it’s fixed or mobile, it’s a critical component.

For instance, if you read Verizon and AT&T press releases you see that they intend to deliver high-speed broadband to homes via cmwave and mmwave. They intend to open new markets to the end-user that would, in my opinion, compete directly with any cable company’s model. Get ready Comcast! You will have competition from more than satellite.

I would like to say Sprint could do this. They have the perfect spectrum in 2.5GHz for beamforming and massive MIMO, but can they get out of their own way to deploy? Your guess is as good as mine! I know they want to do it, and they could do it, but can they execute? They may need some help.

T-Mobile has more spectrum in the 600MHz range. I think when the technology is ready and proven, (and the bugs are worked out), they will jump on this. However, will they do it in the 600MHz spectrum? I don’t know, ask John Legere, I am sure he has an answer. I certainly don’t want to speak for him, but I know once they get this technology and have faith in it, they will go crazy to get it out there to remain faster than anybody else in urban areas.

The cable companies, meaning Comcast and the others, should be eager to do this, but I don’t see them aggressively doing anything with it. I see them investing, (even more), in Wi-Fi. They must see the writing on the wall! We all see LTE throughput matching and passing Wi-Fi speeds, yet, they don’t seem worried. They even saw John Legere mention how he was going to go after them, yet, they seem very relaxed, (maybe overconfident). I don’t get it, but they’ve been successful Only a few cable companies are debt-ridden. They seem to be doing something right by staying out of the mobile arena. They have a corner on the suburban markets for sure, but the urban markets may start falling behind. They should look at history, like paging, 2-way paging, and the Tom-Tom GPS, all replaced by the smartphone. Those carriers are smart to erode other businesses, so they can have more of other market shares. I can already use my cell phone as a Wi-Fi hotspot.

Why cable companies should pay attention.

I would heed what John Legere says about cable companies, even though Comcast’s approval rating is up. T-Mobile already proved they could change the stubborn wireless industry. He singlehandedly destroyed contracts and lowered costs and built a following for unlimited data plans. I believe that he could do the same for cable subscribers, mainly because millennials rely more on their devices than ever.

Personal story, my son was living in Ann Arbor Michigan, in a program at the University of Michigan. When he was there, he didn’t have a cable subscription. He did have an internet connection to them and Wi-Fi, but he complained about it all the time. As a young single man, he relied on his laptop for all his video viewing, movies, and YouTube. He didn’t watch TV on cable; he watches it on his TV with his iMac feeding the TV. He didn’t rely on any cable box or anything, just Netflix and YouTube. My point here is that millennials look at broadcast utterly different. They know that all you need is the internet, then you can watch whatever you want. He didn’t care how it got to his apartment if he had Wi-Fi inside and it was fast. He would have been just as happy getting it from his iPhone instead of Comcast, but AT&T was too slow and didn’t have the best coverage in that area. So, he got Comcast, and it worked fine.

The moral of that story is that the new generations could care less how they get internet access. All they want is a connection. They rely on apps to do the rest. Whether it’s entertainment or voice, it’s an app. They use Skype like we used to use a phone. It’s an app that matters.

What about you? What do you rely on? I know one thing, in the next 5 years you will rely on beamforming and not even know it. Like massive MIMO, and carrier aggregation, you will use it all, but not be aware of any of it.

What about the industry?

Let me tell you something; beamforming will be part of the new massive MIMO systems coming out. The carriers are hoping this is the last time they need to replace equipment at the site. The new equipment is getting smaller and lighter. Not to mention energy-efficient. This means that future expansions are going to be made with software as often as possible.

This will be part of the massive MIMO deployment, which means for the next 4 or 5 years, tower crews will be ramping up to get the massive MIMO systems out there. We need active antennas to see this work properly.

Carriers don’t want to pay deployment teams anymore, they have already eroded the cost to the point where many companies have run out of the industry. The industry has changed, the carriers want to reduce cost, the first place they usually hit is deployment, everyone but Verizon. Verizon is #1 in coverage for a reason; they invest where it matters. Field deployments should be scaling down after 2022, and the OEM licensing and software should be scaling up.

Side note for the field work. As training requirements went up, costs went down. To prove this point, someone compared it to a diesel mechanic that gets over $120/hour to work on an engine. That guy needs tools and training and works in his own garage. The tower climbers need their tools, a warehouse, safety training, skills training, and more tools and trucks. The only thing is, the chances of the diesel mechanic getting paid is much better than the tower crew without the travel and putting your life at risk daily. Who wouldn’t take that trade? Nuff said!

Backhaul and fronthaul are going to increase which is good news for fiber and fiber deployment. Its usage gets heavier, just like I said for massive MIMO, https://wade4wireless.com/2017/11/27/what-is-massive-mimo/. Same deal.

Fiber companies always win in something like this, why wouldn’t they?

Wireless OEMs are hoping they can build something that could be out there for over 10 years, something they can sell a license to for scaling. Can this happen, I doubt it. If they can build something that will be out there for over 5 years that can be improved remotely through software, then the carriers will be in love, until they get the reoccurring bill for the licenses they must pay. It’s still cheaper than deployment.

Antenna companies will move into this market quickly, as will their distributors. They will do all they can to make the perfect antenna. I see CommScope ramping up to meet demand along with Kathrein.

As for the carriers, they will all try to gain bragging rights. They all will try to be faster, better, and cost competitive. I would say “most reliable, but I think we all know that Sprint with their latest advertising campaign of, “Sure, they’re better, but we’re cheaper” pretty much diffuses that argument. It’s like saying; we’re #4, why try harder. Trust me, I know people that work at Sprint, and they work really hard and put in long hours. Personally, I don’t know why management would belittle the workers with that campaign, (again, my opinion).

Learn more:

 

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Be smart, be safe, and pay attention!

See Ya!

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The foundations below do beautiful work, helping families in their time of need. Climbers often get seriously injured or die on the job. The foundations below support those families in their time of greatest need! 

official logo

Hubble Foundation helps the families of climbers in a time of need and beyond with financial support and counseling!

tower-family-foundation-e1447069656192

Tower Family Foundation supports the families of tower climbers at the time of crisis when a climber falls with financial assistance and more.