Tag Archives: fronthaul

Do you know the history of fronthaul?

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I am not sure how long you’ve been in the radio business, but the systems of old didn’t use CAT5 for the fronthaul connection. In fact, they didn’t think it could survive on a tower out in the weather. CAT5 was not known to be used outdoors, and everyone thought it would be a major problem. In some ways it was, but let’s cover some history first.

BF – Before Fronthaul;

Again, let’s go all the way back to the 80s, 90s, and 00s when we had mostly a simple connection from the transmitter to the antenna. Those were the days, all we had to do was put in a power meter and measure forward and reflected power to see what the VSWR would be. It wasn’t quite that simple, but almost.Small Cell Cover 4

The transmitter would transmit power to the antenna, and the receiver would receive the signal from either the same antenna through a diplexer, or it had its own antenna altogether. It was a simple system, relatively simple to work on but the alarming we not so nice. In fact, it was nearly impossible to know what was going at the site without going to the site and testing it. We used to have all kinds of gear to test, a service monitor, a power meter, meters, test cables, dummy loads, and various hand tools to get into the defective part. Yup, when you went to the site, you needed to know how to use the equipment, test, and troubleshoot. You didn’t know much going there expect it was down or not working properly. Chances are good you carried spares with you so you could repair the unit immediately. You could do all the work on the transmitter on the ground. You only climbed if the antenna was bad.

The dawn of fronthaul;

Then, in the 90s and 00s and on, they split the radios. The BBU was on the ground, and the transmitter was near the antenna. This made sense at the higher spectrum, 1GHz and up so that you could minimize cable loss. Not many companies liked this because you would need a tower climber to troubleshoot and repair a unit. It would take longer and add a lot of risks. I remember Verizon workers saying they would never go for that.

Microwave systems were the same, the controller was on the ground, and the transmitter was in the air and chances are good it would attach directly to the dish. Sound familiar? It’s how all systems are today. When I installed them, everyone said it would never catch on and that the transmitter would fail in the air. All those little companies that did that were laughed at, then driven out of business by the big bad OEMs after they started doing it.

I remember installing all IP systems up the east coast, and other radio technicians laughed at me saying we should have installed T1 and T3s, that we were wasting time on a technology that would not catch on. I wonder if they remember mocking me? Oh, if only I could see them today!

By the way, this was not the carriers doing anything like this. They were stubborn to keep things the same and not change. This was the wireless ISPs that lived on the edge using the ISM band to deploy. Yes, that beautiful spectrum we use for Wi-Fi, 2.4GHz, and 5.8GHz was being used for wireless connections everywhere. Because of that spectrum, we have many of the commercial advances being used today by the carriers. The same carriers that refused to support any of it back then.

That’s when the OEMs had to adopt the new split radio methods to move ahead. Once the carriers saw more value in putting a radio head on the tower top, then they got on board. This gave tower climbers more and more work, but it also added more danger to tower work. It was no longer running coax and antennas up the tower. Now it was a complete system on the tower top.

Think about it, when the ISPs were deploying, they had small radio heads, little or no coax, maybe a simple microwave backhaul with a light radio head. The carriers, by contrast, are putting hundreds of pounds of equipment on the tower tops. The tower owners had to run structural and wised up, charging for every box on the tower. More money is going into the wireless ecosystem from a physical change.official logo

The skills for a tower climber suddenly changed from the physical installation, coax connector termination, and grounding. Now they needed to test and terminate fibers. They were already testing coax runs. I did a lot of those for Nextel, making sure the cables didn’t have a kink or break in them affecting service. Now, the tower climbers had to learn to terminate fiber, which is a skill.

All of this was changing the landscape of deployment. Making harder and more dangerous, yet, this is one of the industries where the more you do, the more dangerous it is, the less money you make. Now climbers need more training than ever, but the pay rates are probably as low as they have ever been. What a shame. I get it; the carriers have to pay out larger dividends, but to screw the climbers? They need more training than ever, and they’re being watched closer than ever.Tower Safety for all your safety training!

The end of coax on the tower;

Today, everything is going on the tower. Even the hi-tech BTS brains are being pulled up when they can.

There were many versions; they were not all CAT5 in the beginning. Some connections between the controller and the transmitter were COAX, of some type, that would transmit at a lower frequency, and the transmitter would step it up to the higher frequency. It’s all because we could not get out of the mindset that coax was used at the tower.

Then, speed mattered. Coax, and CAT5 could not handle high data rates at long distances, like over 300 feet. In fact, CAT5 was getting to be a bottleneck. Flash forward to today, voila, fiber everywhere. The only copper on the tower in LTE systems is the power and possibly the coax jumpers form the radio head to the antenna.

Fiber was the fronthaul of choice; it had to be fiber to handle the bandwidth and eliminate any interference that copper may have on the tower. The connection of fiber, with light, was so much more efficient than any copper could do. It pains me because I grew up with copper everything, who didn’t love copper? It could do anything at one time. Now, it’s just for power at the tower.

What if coax was eliminated altogether? Well, welcome to massive MIMO. All fronthaul will go directly to an active antenna. Goodbye radio heads, hello active antennas. This means that fiber will connect directly to the antenna along with power. Fiber will control, pass data, and send data back to the BBU or controller.

They still need power, the gauge of copper that can handle 10 or more amps of current. They need even more fiber to pass the data required of them. In fact, they need more fiber than traditional systems, just like 5G is going to want.

Wi-Fi had this idea for years, probably well over a decade, but the commercial carriers were slow to follow suit. Sure, some of them had active antennas, but more to save space and cost on the towers.

Now, in the MIMO world, coax only gets in the way. It’s a fiber world out there. For backhaul, for jumpers, and for fronthaul. We all want and need fiber to get these systems working. When I design these systems and put the offers together, I see the massive changes made. Not many others do because most people my age left the industry, can you blame them? It’s not what it once was.

Working on towers today, you will run fiber for data and copper for power. The antennas will migrate to active antennas, and we will see the remote units, radio heads, go away. We will see coax disappear from the commercial systems. It’s a new world and one that required fronthaul to be all fiber.

The makeup of the tower has evolved over the last 40 years. It is way more efficient than it ever was, and it is being asked to do more than it ever did. There is a reason, so many smaller companies went out of business. Big carriers control the money, they have all the customer, and they have a sustainable business model. They prefer to do business with companies they have a relationship with and trust. They pay more for that, and as long as the companies don’t screw up, which they do more often than you know, they maintain that OEM as a partner.

Smaller companies could not maintain the level of effort that carriers demand. Today, they demand a 5G product, a massive MIMO product, and active antennas. It is not cheap or easy to install any of these. It costs money to develop and test them, even though most of the OEMs do all of that in China. Today the USA does very little because most engineering, development, and manufacturing is done in China. Most RF engineering is done in India, and most coordination is done in Mexico. Not that it’s a bad thing, but the US workers, like myself, have to figure out where we fit in. This

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economy is changing, but that is another discussion.

Fiber is key to these deployments, as is copper for power. It’s how the next 10 years or so will roll out. Fronthaul relies on fiber to make the connection and handle the data it needs for the end-user and for control.

So, when you look at a tower, think of the evolution that happened over the last 40 years, it’s amazing!Tower Safety for all your safety training!

What about carrier DAS?

That’s right; I almost forgot to talk about DAS. In the old days, say 10 years ago, we used a lot of copper for DAS to distribute RF everywhere. We were worried about cable loss and self-interference and PIM. It became very complicated to roll out the DAS systems with all of the coax. The design was quite complicated.

As with all evolution, DAS became more and more digital. We started distributing radio heads everywhere instead of antennas. We started using small cells where loading was not critical. The DAS system consisted of a BBU hotel in one location, and the radio heads were all around. They were connected by fiber.

In fact, carrier DAS is now more worried about the layout of the fiber layout in the building, cooling at the head end, and power requirements. Oh, let’s not forget about the backhaul, a key component which generally each carrier has their own. These systems are relying on the carrier to do a lot of work.

Public safety DAS is pretty much the same as it was 10 years ago. While FirstNet may change that, it will take a long time for them to upgrade and get away from the dedicated spectrum used in push to talk, PTT, systems. Copper is dominant in most public safety systems. They still distribute radios, but it is a much different design. Not a lot of radio heads broken out in that design.

The extension of fronthaul beyond the site:

Now, with CRAN, the fronthaul is not just for the site! It can have a BBU almost anywhere.

There are limitations today for the concentrated RAN, CRAN, but as we move closer to cRAN or C-RAN, which is Cloud RAN, we may be able to have the BBUs in a concentrated area in a region.

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CRAN allows you to have a BBU hotel in one location, which allows all the upgrades and changes to firmware, software, new cards, and so on all to be done in one location for sites all across the city. It makes a lot of sense. Also, when you concentrate your resources, they are more efficient in the handoffs, self-interference, and spectrum planning in general. The only downside is that there are time limitations, so the BBUs have to be within a certain distance to the radio heads.

C-RAN, the cloud, should take care of some of the distance limitations once it happens. The current hold up is how much specific processing takes place in the BBU. They do a lot of proprietary work that the cloud can’t do, yet. I think it will happen and I think that the one thing that will make a difference is the carriers pushing towards ORAN, Open RAN. This will help the carriers get away from the OEMs that won’t play with others and create a white box for RAN and BBU. While they want this to happen, think of the security issues it opens up. Someone would be able to hack into these boxes with ease. But hey, the carriers are saving money, that’s all that matters, right? That’s the end game! Better performance for less cost.

The fronthaul systems are making the RAN more and more efficient and opening up new doors for the carriers to deploy. When the fronthaul is remote, the spectrum use is more efficient. Instead of concentrating everything in a macro, the macro sector can be put at a location that uses the spectrum efficiently in that area. It’s a cost-effective way to deploy if it’s planned properly.

Think about it:

While we all love fiber today, there will soon be something new passing even more data. Keep your imagination open. Wireless is doing more and more. I talked about how we never thought we would get out of the T1 and T3 cycles. There was T1, E1, T3, SS7, and other formats out there that we thought would never go away. Then we use CAT5, CAT6, and now fiber. What’s next? You tell me!

Resources:

·       https://wade4wireless.com/2018/04/01/cell-backhaul-and-midhaul-and-fronthaul/

·       https://wade4wireless.com/2017/01/24/commercial-5g-ran-backhaul-and-fronthaul-overview/

·       https://wade4wireless.com/2015/07/27/small-cell-fronthaul-and-odas/

·       https://wade4wireless.com/2018/05/28/the-mobility-backhaul-report/

 

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Cell Backhaul and Midhaul and Fronthaul

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  • What is fronthaul?
  • What is midhaul?
  • How can they become cost-effective?
  • Is there more than fiber?

One of the significant barriers to rolling out wireless sites has been backhaul. You would think that fiber is everywhere, but when it comes to deploying fiber to a pole or remote location, it’s not cheap. If there is not existing fiber, it cost a lot of money. If the fiber at a

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location is maxed out, then it costs a lot of money. See the pattern?

Also, if you need a lot of bandwidth, fiber costs a lot of money each month.

Don’t get me wrong; fiber is incredible! We all love the fact it can handle so much bandwidth in a pair of fiber strands. Amazing! It put a dent in the wireless backhaul market because it is rolling out everywhere and quite flexible. We all love fiber. However, it’s not cheap to install or to pay the monthly reoccurring.

We loved wireless back in the day because we could pay $10K to get it running and it would be there for years. It took up tower space, but it was reliable and a “pay-once” type of deal. Well, it was hard to add bandwidth, if you could at all. Modern networks demanded more than the long-range wireless could supply. It’s too much for them to handle. So, now we get fiber, and we may use wireless as a backup, but the traditional 6GHz and 11GHz links just can provide the Gbps links we need today. The broadband requirements are growing, so the idea of putting in wireless links seems to limit growth.

What can we do? Well, the release of the fixed wireless spectrum may solve this problem. If this is something that can grow along with the needs of the end-user, then it is going to be the midhaul solution. This would be the link between a fixed radio head and the controller or core. See the illustration. We need to look at the fixed wireless as the midhaul and the fronthaul. We also need to look at fiber as more than the backhaul solution. It could be the link for the edge to get to the internet or the midhaul or the fronthaul.

All these connections need to be made. As we add hops, we also add latency. Think of how the small cell or remote radio head could connect to the core and to the internet simultaneously. There may be more than one link at a site.

If the small cell or remote radio head needs a direct connection to the internet, it may not need to be a fiber link. It could be just Get the Wireless Deployment Handbook today!something to offer low latency, so any type of internet connection may be just as good. The idea of that connection is to lower latency, so bandwidth may not be the issue. So, order accordingly, remember that we need to be cost conscious when planning.

Backhaul is the connection to the internet or the core. The core is the hub where all the mobile equipment lies.

Midhaul could be the link between the controller or the radio head that feeds the next link.

Fronthaul is generally the link between the controller and the radio head or small cell. It could be the link from the radio head to the UE device. Fronthaul should be the final link, but not the last 200 meters.

All the same, we look at the backhaul using all means necessary to make the connection to the final radio.  It could be a combination of several links that act as a chain to get the data from the end-user to the core and eventually it’s final destination. Each network will be responsible for moving data from point A to point B using any means necessary. It all works together to ensure that the end-user gets what they ask for.

Cost-effective solutions are what we want. It is not always fiber. It would be any combination of wireless and fiber. As long as it is reliable and allows for growth. Growth is critical in today’s world of expansion.5g-deployment-plan-front-cover-3k-pixels

Being cost-effective means that we need a balance between the payback, (number of subscribers) and the spend, (installation and monthly costs). That is only part of it. We need to know, what is available? If the fiber is not available, you may need wireless to get the site on the air. If wireless is not available, you may need to move the site to another location where something is available. Most times moving across the street can make all the difference. Availability is vital because if you need to run fiber across a street, it may involve trenching and permitting, a hefty cost for installation.

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Reliability is a crucial factor here. In the past, wireless would show errors during a rainstorm. This was a problem because the link would have hi bit errors. The rain was a problem. Fiber could get knocked down if it’s overhead, another issue that has caused problems in the past. Make sure your solution is reliable.

So, let’s look at backhaul, midhaul, and fronthaul as one. After all, it’s all the means to an end. They are all needed to get the data where it has to go, both ways. No matter what the link, it is part of the solution. It takes planning. All I am asking is that you need to be open-minded. We often look at fiber as the only solution, but there are more than one means to this end. We have options, and they are growing every day. Let’s take advantage of what we have and think outside the box. Fiber or wireless, it really doesn’t matter if it fills the needs we ask for. As long as it meets the criteria to connect the end-user to the core.

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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! 

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Commercial 5G RAN Backhaul and Fronthaul Overview

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When looking at the RAN you may not think of backhaul or fronthaul as a component, but it is a critical one. Think about it, without backhaul you have no connection to the core, and without fronthaul, you have no connection between the BBU and the radio.

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Let’s start with the backhaul. The backhaul is the connection between the BBU and the core, not a plug and play device just yet, although the small cell has that aspect of it. At the site, you need to have the components to make the connections happen.

First, let’s cover what the backhaul is. Today’s network will have an all-IP backhaul. What this means is that it will have an Ethernet connection to the router. The formats will all be IP-based for 4G and Tower Safety for all your safety training!5G connections. LTE is an all-IP format, as 5G will be. Remember that LTE is one of the building blocks of 5G.

In the days of CDMA and GSM, what we called 3G, they had traditional telco formats like T1 and DS3. These formats worked great at that time, and they were the foundation for what telco had to offer. However, they were over copper. They had limited bandwidth whereas today, with fiber, we can get more bandwidth. When building these systems, there is a need for more and more bandwidth. While DS3 could supply up to 155Mbps of bandwidth, it took more equipment to take it from IP to DS3 format and back again, so now Ethernet connections are the standard in most carrier backhaul systems.

What do you have in the backhaul and fronthaul components? You have the router at the RAN. Chances are the router will be Ethernet

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in and Ethernet out. 3G systems used T1 and DS3 formats for the connection to the internet, but now all connections are pretty much IP in and out.

The standard connections could be copper, fiber, or microwave. Fiber is the most common for macro sites because they can deliver speeds greater than 100Mbps, in fact, as we go to 5G, the carriers will expect 1Gbps and up. Microwave is trying to catch up. You can find backhaul that can do 1Gbps links, but the hops are very short and LOS. You also should worry about latency, which is a real issue with fronthaul. We’ll get into that later.

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Then, out of the router, you will have IP access which may go to a switch to distribute the data among the components in the BTS. While the primary purpose is to connect to the BBU for the backhaul, it also passes more information back to the core such as alarms and BTS status. There is also a control channel for the remote MME to manage the BTS. With the IP connection, there are so many things you can monitor and control Most OEMs already have most of this built into their alarming systems. They even look at temperature and open doors. Some carriers are running video back through the backhaul so that they can see what’s going on at the site when no one is supposed to be there. However, the data to the BBU is the top priority, and video is a convenience at best.

Fronthaul is a connection between the BBU and the radio. In the case of a macro site, you have a fiber run, generally in a hybrid cable, between the BBU and the radio head on or at the tower which could be a simple piece of fiber connecting the 2. The reason they call the cable a hybrid is that it will have 3 to 9 or more fiber strands running through it along with power for the radio heads. The power lines are W4W Cover 4swcopper lines for DC power up the tower. There can be AC power on these lines, but it would be low power, chances are DC or AC it will be 48V or less. Does it have to be big enough to carry the current to run 3, 6, or 9 radio heads on the tower? There is loss through the cable that, if the engineering is wrong then you could have problems. Radio heads need power to work.

Fronthaul at the tower is straightforward. However, in today’s world, we have small cells and remote radio heads that are part of CRAN, Concentrated RAN, systems, and we have radio heads that could be part of a cRAN, cloud RAN. The idea of these systems is that the controller, a BBU, will be at a remote location controlling several radio heads from that location. Generally, in CRAN they are called BBU hotels, making maintenance and control of multiple radio heads at remote locations a lot easier when the tech can go to the one location to make changes or upgrades.

So, fronthaul will have a router, and most of the time it is fiber. You could also have microwave. Copper is not too common because they want dedicated connections, fiber and microwave offer that. Copper does not.

The issue with fronthaul is that the latency must be very low, there are communication timing issues between the BBU and the Radio Head and the UE that are critical. You don’t want the packet to time out, so you have distance limitations with fiber and microwave. Fiber is clean and works very well. Some microwave systems have longer delays due to the conversion between the data and microwave which can be an issue when transmitting signals because if they time out, then it causes retransmissions which will cause problems in the network if there are too many.  Yes, there are delays through the microwave system usually from converting from IP to RF then from RF to IP on both sides. It takes processing power, and if there is a problem with the link, noise or interference, then the RF side will start data recovery and possibly retransmissions.

Let’s look at the backhaul connection. You can have fiber, copper, microwave, or other connections.

Fiber connections:

The most desired connection to the core. Fiber allows a huge amount of bandwidth. Over 1Gbps of bandwidth is available with the right equipment. You have limitations, but it works well.

What options do you have for fiber?

  • Dark Fiber – this is an unused dedicated fiber optic cable that to the customer’s purpose. In other words, you aren’t sharing it with anyone. A dedicated connection between the RAN and another site or the core or wherever you pay to have it sent. For dark fiber, the customer, you, will need to provide all the equipment to connect. You can get large amounts of bandwidth through dark fiber, 1Gbps, maybe more. Your limitation may be your gear. It is easy to scale dark fiber. If you run your dark fiber, it can be very expensive because you must get permits, right of ways, pay pole rents, maybe trench, and so on. It can get very expensive.
  • Lit fiber – this is a shared fiber, and you connect to the carrier’s equipment. The carrier could be a telco or fiber carrier or anyone who offer service. It is usually cheaper, but it is not a dedicated connection. It will still connect between 2 points, but the bandwidth may be limited because you are sharing the fiber. You may have a problem scaling up and need to coordinate with the carrier to make changes.

When is fiber used/not used?

  • Macro sites that require high-capacity could connect to the core or to another macro site to save on costs.
  • Fronthaul for low latency and high-capacity to connect the BBU to the remote radio head in a CRAN option.
  • Small cell sites when heavily loaded or no other option is available.
  • CRAN Hotel BBUs to connect to high-capacity backhaul and to connect to remote radio heads for fronthaul creating a situation where you would have several fiber runs.
  • In the case of C-RAN, Cloud RAN, it would be to connect the cell that is connected and controlled by a BBU in the cloud. New in 2016 and being tested in China and the USA.
  • Fiber is not available everywhere. There are issues connecting to fiber in some areas.
  • Fiber could be cost prohibitive to run to your specific site which has slowed the growth of small cell sites on remote poles. The cost of getting fiber to the pole may be more than the expense of the small cell and the installation of the small cell. That has been a problem that holds back the mass deployment of small cells.
  • In some cases, you have only one fiber provider to choose from, and their costs may be probative.

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Microwave Connections:

  • Point to Point, (PTP) is where you have a dedicated microwave shot between to end points.
  • Point to Multi Point, (PTMP) is where you have one control point connected to multiple endpoints.
  • Latency varies, and it is hard to capture in a band. Why? Let’s review this list:
    • Distance – just like fiber, the farther the data travels, the higher the latency. In microwave, the longer the link, the higher the latency.
    • Equipment – specifically the radio equipment in this case. The longer it holds on to a packet the longer the latency. The longer it takes to process the conversion from RF back to IP, the longer the latency. The longer error correction takes to complete the longer the latency.
  • Spectrum, microwave can be in many spectrums that serve many purposes. High-level explanations for the US market but they could apply to the world. These are the most common. Remember that the distance and dish size and engineering will affect throughput and latency.
    • 6GHz range – general for long-range shots. Point to Point LOS (Line of Site) microwave using larger dishes for longer shots. Licensed. Used early on, but the limitations in bandwidth and the large dish size have made them less attractive to modern sites. The dishes are over 6 feet and over. However, the FCC will allow 3-foot dishes in some situations. The limitations are the spectrum, licensing, and potential interference. The FCC did allow larger channels, but the current licenses in the US make it hard to get larger channels. Antenna size is an issue, but because the propagation of 6GHz is great, meaning it can travel far, it makes it hard to license without causing someone else problems. It was great with voice channels when they could travel great distances. Public safety in rural areas relies heavily on this because many of their sites are spread out.
    • 11GHz range – generally used for midrange shots. Point to point LOS microwave using mid-size dishes, around 4 foot or so, but the FCC will allow 2-foot dishes. Licensed. Used extensively I the past and is a good midrange solution. The FCC was going to allow smaller dishes, but this band usage is high and very dense in the USA. The throughput is just over 200Mbps if properly engineered.
    • 18GHz range – generally used for short to midrange shots. Point to point LOS microwave using 1 to 4-foot dishes. Licensed. These are an attractive solution with high bandwidth. Do the engineering because these links are heavily affected by weather, specifically, rain. Bandwidth through these links could be 100Mbps up to just over 300Mbps
    • 23GHzrange – generally for very short hops. Licensed. Point to point LOS microwave using smaller dishes, around 1 to 4 foot. High throughput, 100Mbps and up. Very prone to rain degradation. Very easy to license in the USA.
    • 24GHz range – generally used for short hops. Point to point LOS microwave using 1-foot dishes could go down to 8 inches. Not licensed, very easy to license. With a throughput of 100Mbps, some companies can get this band to over 700Mbps with proper engineering, but rain is a factor when it comes to engineering these links. Very limited on distance. Interference is usually low because of the propagation properties of this spectrum. This spectrum is good for short hops.
    • 2.4GHz and 5.8GHz range – the ISM band used for short hops, (although I have seen companies connect 15 to 20-mile links). Could be PTP or PTMP. Could be LOS or Near LOS or in some cases non-LOS. Not licensed. This sub 6GHz license free spectrum is a popular choice among non-carriers because the spectrum is free and the hardware is cost-effective using smaller dishes (or panels) which are easy to install and setup. No license makes it easy to deploy anywhere, and the low-cost equipment makes it affordable to deploy anywhere. A short hop solution but there are claims that are using the right size dishes that it can be a long-haul solution. The downside is that it’s prone to interference because anyone can put them up or any Wi-Fi hotspot may affect it. They are easy to deploy. Throughput varies on the engineering but generally, 10Mbps to 150Mbps. I have seen more throughput, but it takes the right design and engineering to get it.
    • E-band 71-76GHz and 81 – 86GHz range – generally for very short distances, prone to weather issues. Dishes are very small, under 2 foot. Point to point hops.  Licensed links, but light licensed, so getting the license is very easy in the US and Europe. These are a popular choice for short hops that could need up to 1Gbps of throughput. Very high throughput looks like a fiber connection.
    • 60GHz – generally for very short hops. Point to point, but there is talk of a multi-point product coming out. Dishes are 6 inches to 2 foot. Throughput is very high, over 1Gbps.

When is Microwave used/not used?

  • Microwave is a cost-effective alternative to fiber, but can only be used in specific cases. Your paying for the hardware, so CapEx is higher. The OpEx is lower because the only reoccupying cost is license renewal and tower rent if you’re paying it, and maintenance.
  • Microwave works for macro and small cells for backhaul or fronthaul.
  • Microwave does have its drawbacks because it is a limited solution, although a very cost-effective one if you’re looking at OpEx.

So, when looking at fronthaul or backhaul you have:

  • Router.
  • A connection from point a to point b, fiber, microwave, or copper.
  • Switch (if needed).

What is LTE UE backhaul?

It is backhaul that uses the carrier’s spectrum, just like the UE, User Equipment, your smartphone. If you have ever used your smartphone as a Wi-Fi hotspot, then you know the concept, using the carrier’s backhaul to create a new hotspot. Now imagine taking your usage and multiply by hundreds or thousands of megabits. The UE backhaul device in something that will use the carrier’s LTE spectrum for backhaul. This is something that is commonly used for internet access when there is no Wi-Fi available. The carriers all sell these units and many of today’s smartphones do something similar. However, they just use the standard signal. Using it for a tiny hotspot and for an eNodeB are 2 different things.

Let’s talk hotspot. Many vendors provide equipment that a user can add coverage quickly and easily. It is a quick Wi-Fi connection to the internet using the carrier’s LTE to connect to the internet. Everyone has Wi-Fi, and there are devices that create an instant hotspot. Verizon has the Mi-Fi, or you can use your smartphone as a hotspot. Every carrier has a wireless modem that you will provide a Wi-Fi hotspot. I think anyone who is reading this knows about the hotspots. I thought it would be a good example to get started.

What is a cell extender? There is a practice where many carriers will use a cell extender that will have a UE relay backhaul to extend the signal. This is also like a smartphone hotspot or a Mi-Fi unit because it was just to help a few customers but extends the carrier’s signal instead of Wi-Fi. This is a type of repeater to extend the macro’s signal, a cell extender. This is a way for the carrier to extend the coverage just a little bit farther. It’s a way to provide coverage someplace quickly and easily. These were common in 2G, 3G, and now LTE. It is a simple and quick way to install a repeater to extend carrier coverage down an ally. In the old days of DAS, this is what they did. They would take the signal where it was strong or use an antenna and amplifier to increase the strength to get it into a dead spot. People paid a lot of money for these systems.

It’s not a simple cell extender, and let me tell you why. Now you are talking about putting the small cell in an area where there is a loading issue. This goes beyond coverage. The data and spectrum usage could go through the roof! If you set it up like a cell extender with backhaul to the macro site, then guess what! You will see an overloaded macro sector! The macro not only has to deal with all its users but all the small cell or Mini macro users too. This sucks up all the spectrum and bandwidth for that sector.  What can be done? Read on!

I am bringing this up because now there is talk about using the UE backhaul for small cells, mini-macros, and macro cell sites. It’s making a more powerful cell extender. It sounds like a great idea on the surface. This is a cheap, quick and easy backhaul. However, what is the drawback? It’s not as easy as you think, the carrier needs to set up the donor site properly. I mentioned it earlier, and it is not something you just throw out there to feed a cell site. It draws a ton of data.  It sounds like a great idea on the surface. It looks like a cheap, quick and easy backhaul.

The donor site needs to break the bottleneck. You need to dedicate spectrum in the macro eNodeB that will be feeding the UE backhaul. This will alleviate the spectrum usage for the regular users on the macro sector. We don’t want them to get knocked off if the small cell US backhaul overloads the macro. This will make it so that the users on the macro don’t get shut knocked off if the small cell pulls the entire spectrum of its users. This will allow the small cell UE backhaul to have a dedicated pipe. It needs to have dedicated spectrum for this purpose. Then the small cell will know how much backhaul spectrum it has to available. By the way, not an easy change, changes in the eNodeB and possibly the core need to be considered as well as neighboring sites. This “dedicated backhaul spectrum” needs to be set aside for this sector and others too. It takes some planning and changes.

You could still have the data bottleneck at the macro’s backhaul. That’s another issue that needs planning.

So now you dedicated part of the band to the UE backhaul, which seems OK. Remember that the carrier paid a lot of money for that spectrum and now they are choosing to use it for backhaul. So the pipe is limited based on coverage and availability. It is a quick and easy to add UE backhaul, but is this the best use of the spectrum? Will you lose something in this backhaul? Yes, you have delay issues, timing issues, and neighbor issues. All of this is a problem when building a site for any type of real loading. Go to the links below to learn more.

However, what’s the real issue? Is it all the problems I mentioned above? They are all technical issues that good engineers will resolve. This appears to be a cheap and quick solution. But that’s not the real issue, is it? The carriers paid a crap ton of money for spectrum. Is backhaul a smart way to use this resource? Is that billion-dollar investment there to save some CapEx for the company? I thought it was for the customers! Backhaul could have been something in the unlicensed band for a lot less money. It could be a fiber link for more money. Is this an easy out or will it cause problems down the road because the spectrum is only going to get more and more valuable? Do investors want to see that spectrum used this way?  I don’t see the auctions being a cheap alternative to providing backhaul.

So just because it looks cheap and easy doesn’t mean it’s a good move strategically. Don’t get me wrong; the UE relays, the repeaters serve an important purpose for coverage and filling holes, I am just saying be strategic and think it through. For more information hit the links below to learn about these solutions.

If delays were lower, this would be a great technology for fronthaul, now that would be something!

Resources:

Be smart, be safe, and pay attention!

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Small Cell, CRAN, Fronthaul, and oDAS

We always talk about backhaul when it comes to sites. Wireless, fiber, cable, and copper are all solutions. So do many of you really know about fronthaul? This is what we use when we connect a BBU to the radio head. Is it different that backhaul? That depends where you are in the wireless ecosystem.

For this article we are talking about remote radio head small cells, not the all in one unit. These are very common indoors and outdoors in larger deployment scenarios. This is also something that will be more common when CRAN, Centralized Radio Access Networks, become more common place. Eventually, the RAN will be controlled by the cloud, for a vRAN, virtualized RAN. 

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So on Macro, think about when you run fiber up the tower from the BBU, this essentially is the fronthaul where it feeds from the BBU to the remote radio head, (RRH). The data in the BBU is sent out the radio head for transmission to the user equipment, (UE). So now imagine that the BBU is located miles away from the RRH. The RRH is located where coverage is needed. Most small cells are low power units. This is very similar to a small cell and would be deployed similar to a small cell. The BBU hotel is located in one area and the link from the BBU to the RRH. So the data will leave the BBU and go into a router or fiber box and then feed dark fiber or a radio link. Personally I am not a fan of this but they are very common in the market. I prefer a small cell that is standalone with all of the components in one unit just because it’s easy. However, there are many advantages to having one BBU controlling several RRHs.

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These systems do have their advantages because the control is all in one place and can do a better job of timing and synchronization and reducing interference. If you are designing a network, then it makes dog-tags_clearbackgronda lot of sense to have centralized control. Centralized control will be reducing self interference, which is huge and something that most field workers could care less about until it gets to the optimization and performance phase. Then it’s an issue. Interference has to be cleaned up to improve the performance. Remember that this is all about coverage and performance. In a Het Net system we would call this eICIC, enhanced Inter Cell Interference Coordination. This is one of the reasons the cells have neighbor lists, to avoid this situation. Learn more on eICIC here, http://arxiv.org/pdf/1302.3784.pdf

So, back to fronthaul In this case timing is critical, and by timing I mean latency between the BBU and the RRH. It needs to be a specific time, depending on OEM. The link must arrive in time to properly send the data and have the timing set up properly. If it is late, packets are lost, and then people complain or it has to be sent again causing congestion. This is critical in voice communications.

This is why many carriers like fiber for the front haul because it’s clean and fast. It is usually easy to predict the delays because they are predictable unless someone screwed up a fiber connection or put a sharp bend somewhere.

Wireless links are great because it is line of sight, normally, but the radios add delay, usually with the error correction. So the distances, from what I have seen is generally lower that fiber. This could all change tomorrow but as of this time they have limitations. There are several wireless link manufacturers like EBlink working to make the fronthaul wireless link better, http://e-blink.com/.

Now, if you are doing the installation, you just do what you’re told and make sure it’s a great installation. If you are doing the design, you need to be very aware of the latency and the link delays. They will add up. The fiber will have some delays, the router will have some delays, and the equipment will induce delays. This all adds up to either success or failure. Proper planning! If you are doing the optimization, the commissioning NOC should have a good understanding of the delays of the fronthaul. So if there is an issue it needs to be considered.

Did you ever work with a CRAN? If you have done work for Verizon Wireless on oDAS, (outdoor distributed antenna system), then you may have. You see the concept behind the oDAS when using a distributed RRH is basically that of CRAN. Get it? The hBBU is located in one place, centralized, and the RRHs are distributed around where the population is. 

Why do you care? Because you want to make sure you have a successful installation, commissioning, and integration. Then the commissioning should go well and everyone gets paid for the work. If there are problems, you all need to put more time into it, and chances are good that time will eat into your profit. Just think about the bottom line, proper planning and quality work adds up to a quality system and profitable work.

Be smart, be safe, and pay attention to the plan! Look for oversights and point them out.

I am putting a small cell handbook together, it should be out soon. It will be geared towards deployment but a good reference overall. It will have most of what I post but also some extra notes is it.  If your interested, feel free to sign up for my newsletter below. 

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