Top 5 3G4G Small Cells Blog Posts for 2015

Here are the top 5 posts for 2015:

1. Small Cells in the Lamp posts
2. Couple of Satellite Backhaul Presentations
3. Summary of Small Cell Forum Champions day
4. Wi-Fi: Future Roadmap and LTE
5. Flying Small Cells for Rural Coverage using Drones and Balloons

Small Cells in the Lamp posts

This lamp post does look a bit weird and ugly but it could be the future. 'SmartPoles', developed by Philips in conjunction with Ericsson delivers LED lights and LTE powered mobile broadband. According to the official press release:

With cellular data traffic expected to grow 9 times by 2020, according to the Ericsson Mobility Report, and current telecoms infrastructure struggling to respond to this demand, Philips SmartPoles are enabling seamless mobile wireless 4G/LTE connectivity, with the small cell technology from Ericsson housed in the poles to enable increased data capacity in the telecoms network.  Philips SmartPoles were specifically designed and tested to accept FCC licensed wireless mobile network operator equipment. This enables an alternative deployment methodology for 4G LTE broadband services which will connect each pole through a fiber link to its core network.

Back in February TTP in partnership with IP.Access, Quortus and Freescale demoed another concept of small cell on the lamp post. The case study on Freescale's website says:

TTP’s new eNodeB based on the QorIQ Qonverge® BSC9131 addresses these challenges. It fits into a photocell socket of a standard lamp post, providing the quickest possible installation without any modification to the lighting column or its power supply. The solution incorporates LTE Access Point software from ip.access and has been demonstrated with the Quortus ECX Core evolved packet core. It is targeted at 50 metre cells, supporting up to 32 active users at downlink rates of up to 100 Mbps.

TTP have also made an interesting video on this:

This conceptual lamppost above was conceived as a part of Oakland Innovation Project in 2013. While its good, its not ambitious enough as it talks about just WiFi for connectivity.

On the other hand, V-Pole (Vancouver Pole) concept by Canadian writer and artist Douglas Coupland shows what may be possible in the distant future. It is a wireless data, electrical vehicle charging, neighbourhood bulletin board post that is also an LED lamp post that could eliminate some of that clutter. I think it will still take quite a few years before technology can make this possible. Press release from 2012 available here.

I look forward to the day when street lights and lamp posts can do more than simply provide lighting and be a hub for providing connectivity and much more.

Related posts:

• Small Cells on the Lamp posts and other street furniture
• Huawei's Lampsite

Rural & Remote: 2 case studies

Some good case studies posted by the Small Cell Forum about Rural & Remote small cells. The first one is from Softbank, Japan as follows:

The second is a presentation by Parallel Wireless

as follows:

Interference cancellation in high density small cells deployment

I looked at some 3GPP Release-12 small cells enhancements in an earlier blog post here. David Chambers, ThinkSmallCell has also published a post on 3GPP small cells enhancements in Release-12 and Release-13 which is available here.

In a recent NTT Docomo technical journal, there is an article that focuses on Interference suppression and cancellation techniques that have been introduced as part of 3GPP Release-12. These techniques can be used in conjunction with high density small cells Hetnet deployment. The article is embedded below.

Summary of Small Cell Forum Champions day

Small Cell forum held its champions day in Rome this month. There were some interesting case studies and presentations (details below). I have embedded some presentations and provided links to others. Interested people, feel free to explore further.

The Small Cell Forum has identified six key work items where they will be focusing their energies. These are:

• Small cells in Enterprise
• License Exempt Spectrum
• HetNet & SON
• Virtualization of small cells
• Multi operator support
• The role of small cells in 5G, IOT & M2M

Spidercloud did a presentation on Enterprise small cells. They were also one of the sponsors for a study by analyst firm iGR that showed strong demand among Enterprises for Managed Services based on Small Cells.

Cisco shared a case study from a university campus deployment where existing WI-FI APs were ‘upgraded’ to add a small cell capability.

Quortus demonstrated the range of architectures possible with virtualized small cell core networks including the on site MEC server supporting small cells across an enterprise and mission critical small cells supporting public safety applications. See presentation below:

iBwave showed how deployment within the enterprise had improved, with a case study which reduced indoor small cell planning down to one site visit.

MVNO TalkTalk outlined their plans to add LTE small cells to their home routers enriching customer experience as well increasing traffic offload from the macro network. The residential 4G small cells use a dedicated 3.3MHz carrier frequency already compatible with existing 4G handsets to provide good coverage indoors and in the surrounding streets.

Nokia demonstrated the importance of 3D thinking when planning small cell HetNets in dense urban indoor and outdoor environments due to building and user topography.

Qualcomm described how their SON technology provides zero touch integration for both the small cells and the macros, optimizing handovers in both directions.

Huawei shared their vision for small cell evolution, incorporating emerging technologies which leverage license exempt spectrum. Their demonstration of LAA mobility with Vodafone notching up 600Mbps peak rates clearly showing the potential of a joined-up approach to spectrum.

Airspan trials with SoftBank demonstrated an early nFAPI implementation working in a virtualized small cell / macro HetNet. The small cells filled in coverage gaps, and their densification increased capacity. Centralised CoMP and eICIC were demonstrated over a pre-standard nFAPI which works over commonly available packet based transport with significantly less stringent performance requirements than required with CPRI based C-RAN.

The role of Wi-Fi in evolving mobile ecosystem

Came across this old presentation from the Cambridge Wireless FWIC 2015 by Plum consulting. I have written many posts on these topics but this is going to be a hot area for discussion for the coming months and year(s). In fact you might be seeing more on these topics in the next few months on this blog.

Here is the presentation from Plum embedded below.

You can read more about the Cambridge Wireless Future of Wireless international conference in a blog post by ThinkSmallCell here.

Case Study: Deploying small cell backhaul in China

Came across this old presentation (embedded below) by CCS (Cambridge Communication Systems Limited) of small cell backhaul deployment in China. Having looked at their website they do have regular updates for different deployment. Here is one with China Mobile and here is another one from China Telecom. Interested readers can also read their regular updates here.

Here is their presentation from Small Cells World Summit (Backhaul Summit) from last year:

Small Cells on the Train - A 2 hop solution

An Ericsson blog post some time back talked about the 2 hop solution for trains. Thinking about it, I quite like the idea. The post talks about 3 main challenges on high speed trains:

There are mainly three reasons communication services on high-speed trains is challenging:

First, large penetration loss via the shield of the train. This penetration loss is expected to be 20 to 30 dB.

Second, large numbers of handovers in very short time. This is due to hundreds or thousands of users needing handover from one site to another concurrently/sequentially. This phenomenon affects system stability and eats up capacity.

Third, high power consumption of user equipment (UE). This is because UE-s on the train need higher power to overcome the large penetration loss in uplink as well.

A common currently adopted solution for high speed trains is to densify the network along the railway to combat the large penetration loss. However, this will make the second issue more severe, as handover frequency is increased due to smaller site- to-site distance. Another way is to increase the transmission power of the base stations, which helps to solve the large penetration loss as well. However this cannot solve the third issue. And neither of these solutions are cost-effective.

Another solution I have discussed before is the Mobile Relay Node which was designed with avoiding multiple handovers when the vehicle moves between different macro cells. Not sure about its status in the standardisation process right now.

Anyway, coming back to the Ericsson post on Small cells on the train, while the Macro cells provide the TD-LTE backhaul outside, Radio Over Fiber (ROF) is used inside the tunnels to provide the same coverage.

Within the train Small cells (I guess multiple small cells will be needed in practical deployments, one for each carriage) can provide good coverage to the users and avoid the need for handovers.

Embedded is the video from Ericsson Taiwan that provides more details about this trial

Disguising Small Cells in Rural areas

We all want good mobile coverage but we do not want the cell towers in our backyard. The main reason being that somehow this can affect our health and maybe cause cancer. There is absolutely no link between cellphone radiation and cancer as I have discussed in an earlier post here. With more studies having been done, any possible links between cellphone tower and existence of cancer seems to diminish. On the WHO list, exposure to radio emissions is now category 2b (possible carcinogens), along with coffee, talcum powder and many other substances to which we all expose ourselves.

As a result, the mobile operators have started disguising cell phone towers. A cellphone tower inside the bell tower, rear right, is seen over the Resurrection Lutheran Church in Ankeny, Iowa. In rural areas disguising also doesn't affect the scenery.



The cactus cell tower in Arizona is another great example of coverage by stealth.

Small cells on the other hand is a whole new ball game. We are so used to seeing WiFi routers that people will probably not bat an eyelid with the small cell above by Vodafone in Cranborne.

Another disguise is the bird box cell booster, also by Vodafone. It picks up the mobile signal from the nearest network mast, and boosts it to provide better coverage in the surrounding area. This would definitely fit with the surrounding but getting power can sometimes be tricky.

Do you know of any disguised small cells, please let us know.

Wi-Fi: Future Roadmap and LTE

At the WBA Wi-Fi Global Congress, Intel provided a good summary of the way things are progressing in the WiFi world, including the standards updates that are going on. Luckily I found a video by the same author in from an IEEE conference which is also embedded below.

Wi-Fi is becoming important and a useful rule of thumb is that the spectrum in 5GHz is roughly around 10 times that of 2.4GHz and the spectrum is 60GHz is roughly around 10 times that of 5GHz. (not all spectrum is available everywhere so just use this as a rough guide).


As I mentioned in a presentation I gave this week, there are three different approaches being proposed at the radio level; LTE-U, LAA and LWA. I wrote a post on LWA not long back on the 3G4G blog here.



Dave Wright from Ruckus Wireless has kindly shared a recent presentation on different proposals for LTE operation in unlicensed spectrum. The timeline above shows how quickly things are moving. Here is a the presentation

It would be important from Wi-Fi vendors point of view that LTE-WiFI Link Aggregation is standardised as part of Release-13 as there would be an option which would be agreeable to everyone.

Couple of Satellite Backhaul Presentations

After publishing the emergency communication options last week, I was made aware of couple of recent presentations on Satellite backhaul options. The first one is from Richard Deasington of iDirect at MWC 2015:

The other one is from Vince Onuigbo of Hughes. As can be seen above, the biggest issue with Satellites is the latency which is 600ms for the geostationary satellites. Anyway, here is their presentation:

Emergency communication options in times of disaster

The Nepal disaster is another reminder that we need to be prepared in case of natural (or man-made) disasters and in times of emergencies.

ITU said that it has deployed emergency telecommunication equipment in Nepal following the 7.8 magnitude earthquake that hit the country on 25 April 2015. The emergency equipment includes 35 satellite mobile phones and 10 satellite Broadband Global Area Network terminals along with solar panels and laptops to support relief coordination efforts.

Satellite phones have been getting better with higher speeds. Thuraya Telecom has some interesting videos on Youtube, here is one that shows how to get good these phones have become:


Satellites can also be used to provide backhaul for small cells and can be installed relatively quickly.

Thaicom recently announced that they have sent equipment and engineers to help reconnect the region quickly. From a picture posted on their website, it looks like they are backhauling the small cells but I dont have any more details.

A similar approach is being done by another satellite operator SES, in conjunction with emergency.lu.

Drones (UAVs) and Baloons are another option for use in these scenarios but they need (expensive) receivers to be installed, which may be an issue.

One of the lessons learned after the Japanese twin disasters of earthquake and tsunami was the need to deploy more small cells.

According to Akiyoshi Ishiwata, a principal research analyst at Gartner in Tokyo covering Japan's mobile networks, 'each of the operators are actively installing small cells and picocells in buildings, subways and indoor areas'. These miniature basestations improve indoor coverage, and improve a network's resilience by using more diverse power supplies and backhaul connections. Ishiwata said operators are considering using femtocells as the basis of a national machine-to-machine communications network that could also include earthquake sensors.

According to The Register, DoCoMo has tested blackout-proof hydrogen cell base station in Japan, ready for the next tsunami (see picture above).

Finally, I saw this tweet about Vodafone's emergency 'network in a back pack'

Vodafone prepares to launch emergency ‘network in a backpack’ in Nepal - 11kg mobile network which can be set up in just 10 minutes

— Rory Cellan-Jones (@BBCRoryCJ) April 29, 2015

Its not the first time Vodafone is helping out with a Small cell in a backpack. According to WSJ:

Vodafone Group said Monday its philanthropic division has created a mobile network in a backpack that can be deployed in 10 minutes, enabling aid workers to carry out their work in disaster zones. 

The Instant Network Mini, which can be taken as hand luggage on commercial flights, can provide up to five concurrent calls within a radius of about 330 feet and enable text messages to be sent to thousands of people. 

The 24-pound backpack is an innovation that follows on from the company’s original Instant Network—a portable network in a larger form that can be transported in four suitcases weighing 220 pounds. It offers a much wider operating radius of up to 3 miles.

Two original Instant Network kits were used in the Philippines during Typhoon Haiyan in November 2013, enabling 1.4 million text messages and 443,288 calls in 29 days, Vodafone says. 

The backpack, developed by Vodafone’s Spanish business, as well as Chinese telecommunications giant Huawei Technologies and nongovernment organization Télécoms Sans Frontières, provides a secure 2G GSM network, with a GSM base transceiver station connecting to a host network over a satellite connection. 

A 2G (short for second-generation) network can support voice calls and text messages but can’t easily handle Web surfing or video, unlike the 3G and 4G networks in wide consumer use.

In African countries, having a network allows people to use services like M-Pesa, for instant money transfers to friends and family. Vodafone has also donated £100,000 to support relief efforts following Nepal earthquake that killed more than 3,300 people.

Do let me know if I have missed anything.

Additional reading:

• How mobile tech is improving global disaster relief - BBC
• Part 1: How Satellite Made a Difference in Nepal - Via Satellite Magazine
• Part 2: How Satellite Made a Difference in Nepal - Via Satellite Magazine

Rural and Remote coverage back in spotlight

The Small Cell Forum recently launched its Release 5: Rural & Remote to address the growing concern of especially rural coverage that is plaguing many developed nations.


The release contains 16 new and updated documents ranging from case studies of small cells already used in a range of rural and remote settings, through to those covering backhaul, deployment challenges, architectures and the services that can be enabled by small cells.

From my point of view, backhaul is one of the biggest challenge for the rural and remote coverage. As I have discussed in an earlier post here, satellites are a good option for rural small cells. The main issue with satellites is latency which could be around 0.5 seconds which may make them unsuitable for voice and other real time applications. Another option being trialled are Balloons and Drones as I have discussed in another post here.

The Australian operator Telstra is rolling out small cells in around 50 rural areas. While the small cells would be good for 4G data, they wouldnt be available for voice. While I do not have the details on what backhaul they are using and the voice issues could be more of VoLTE support on handsets, I am sure the users would appreciate the data coverage. If latency is not an issue then they could use OTT services like Skype, Whatsapp, Viber for voice.

The UK operator EE has been working with Parallel Wireless to use innovative mesh backhauling. Part of the licensed spectrum (20MHz chunk of EE‘s 1800MHz LTE spectrum) could be used for backhaul which would be different from the access network for the end users. The meshing allows in theory for the small cell to macro connection, with a couple of hops, be as much as 30km.

As I have mentioned in a post earlier, Vodafone UK has its own Rural Sure Signal program. Vodafone claims to have received hundreds of applications from communities across the length and breadth of the UK. Following a trial covering 12 towns and villages, it has now announced the first 30 communities selected to join the programme, which it is hoped will enhance everyday life for consumers and make it easier to do business in rural areas. There is a plan to continue this program for the rest of this year.

ThinkSmallCell has an interesting article where it asks if the drive towards the rural coverage is operator driven or regulator mandated. While it is a combination of both is most developed countries, in some developing nations it can just be that people are desperate and will find their own way. One example is people in remote villages in Mexico that are installing open source base stations from NuRAN to provide coverage to their villages. Another example is Nepal, where villagers are banding together to provide WiFi coverage to rural areas.

Opensource is another concept argues ThinkSmallCell that may also be an opportunity to connect some of the most remote and unserved communities which commercial organisations haven't been able to reach. It may also be useful for experiments and for colleges and universities with limited budgets. PA consultants have shown how to create a 2G base station using Raspberry-Pi. I have a feeling that we will see more projects like these soon.

10 million small cells and growing?

There were some good news that was announced in MWC 2015. Here are some interesting points from Total Telecom:

• Operators around the globe have purchased more than 10 million small cells
• In excess of 75 operators worldwide are using small cells in their networks
• The majority of these to date have been deployed in residential scenarios, but we have also seen a significant step upward in the enterprise and urban sectors.
• 17,000 small cells have been deployed in rural or remote applications

While this all sounds good, Small Cells are facing many challenges. The biggest among them being WiFi. With the introduction of VoWiFi, many operators are starting to play a waiting game rather than deploy more small cells.

I blogged back in 2013 that AT&T planned to deploy 40,000 small cells by 2015 but it looks like they have now abandoned their goal. The reason being cited is that they acquired another small operator (Leap Wireless) which gave them additional macro sites, hence removing the need for small cells.

As per a report by the analyst firm ThinkSmallCell, TalkTalk, a UK based "thick" MVNO is trying to deploy an "Inside-out" Femtocell network. They have also been experimenting with 3MHz bandwidth in LTE and surprisingly, it works fine on most devices.


Another option could be to have LTE-LAA/LTE-U along with this and they could provide good speeds not only to the people indoor but also outdoor.

In any case, we will have to wait and see if operators continue rolling out small cells and if they do why, how, where and in which situations.

Flying Small Cells for Rural Coverage using Drones and Balloons

Image: Google Loon Balloon

"We will begin exploring 'Air Masts'," EE CEO Olaf Swantee wrote. These are "essentially aerial small cells positioned in the sky above a hard-to-reach area, using either tethered balloons or unmanned craft, bridging the UK's transmission gap.

While this would be interesting and challenging, it wouldn't be the first time. Google has been trying something similar with its 'Loon' project. In fact its partnered with the Australian operator Telstra to bring connectivity in hard to reach places.

Kind of Flying LTE small cells, fascinating! #d2 @BellLabsOpenDay #ODays13 pic.twitter.com/NFsNveoCHK
— Andre MECHALY (@A_Mecly) June 19, 2013

Another possible approach is to have small cells via drones. A prototype can be seen above in the embedded tweet. In fact one of the articles have been nicely worded "EE Plots Drones to Blanket UK for 4G"

Daily mail has a picture of the drone as well.

Back in 2012, Daily Wireless ran an article on Unmanned Aerial Vehicles (UAVs) to be used as 'Flying Cell Towers'.

The main challenge for these deployments is the backhaul. One approach is to have satellite backhaul which may be possible for balloons but may not be easy. For the drones, they would have to create a mesh network among themselves with at least one of them receiving signal from the ground.

This nice conceptual diagram from Inmarsat shows how backhaul is provided to the planes. Using a combination of satellite and complemented by a fully integrated air-to-ground network. I am assuming a similar approach for the balloons/drones.

Anyway, we will hopefully learn a lot more in the coming months and years.

LTE-LAA updates - Jan 2015

There has been quite a few updates on LTE LAA in the past month. First, there is this good video from Ericsson explaining what it is:

The 3GPP chairman recently presented a status update about developments on unlicensed spectrum at an IEEE 802 meeting last month. His presentation is embedded below:

3GPP & unlicensed spectrum from Zahid Ghadialy

IEEE 802 group have their own presentation on the co-existence lessons learned. This is embedded below:

Ericsson has also got a recent presentation on this topic. As can be seen, they expect a solution to be available in 2016-17. Presentation embedded below (download link here)

Finally, if you watched the video by Ericsson, they mention that one of the key milestones of 5G is to be able to combine licensed and unlicensed technology. One of the technologies being proposed in 5G is called Multi-Stream Aggregation (MSA). MSA allows multiple access technologies over licensed and unlicensed bands effectively. The picture above shows how it would work in theory. It may be more difficult in practise though. 

In-Building Options: Facts, fiction, Architecture and Solutions

In-building solutions are still a big topic of discussion. While there are neutral solutions like Wi-Fi will become more common, does it mean that cellular is no longer a necessity? To answer these questions and to make everyone familiar with the options here are a couple of videos of recent webinars.

The first one is from Alcatel-Lucent titled "Fact vs. Fiction – The Debate on In-Building Architecture Options". It discussed the three architectures (as seen in the picture above) DAS, Distributed Radio Systems (DRS) and Small Cell. Here is the video:


The other webinar (actually 2) is from ThinkSmallCell.

"Choosing the right In-Building Cellular Solutions" is a high level webinar that discusses the needs and available solutions. It also shows the decision process in selecting the right solution. The video is embedded at the end of the slides below but can also be seen directly from Youtube here.

The other older webinar and presentation by ThinkSmallCell that goes more in-depth of these In-building solutions has already been covered in an earlier blog post here.

Case study of WLAN and Small Cells by China Unicom

China is a huge and most populated country. Many people do not realise that the number of mobiles in China is more than combined USA and Europe. There are challenges that come along with this huge subscriber base. That is why its not enough to have just cellular connectivity. Small cells and WiFi has a big role to play. A news article last year boldly stated that 'Wi-Fi to be new battleground in China's internet sector'.

According to this article by ThinkSmallCell last year, China Unicom is the second largest operator in China with 251 million subscribers and $21 Billion in revenues. They have only 40MHz available for 4G cellular as compared to 130MHz for the leader China Mobile.

This presentation from Small Cells World Summit 2014 is a good case study of how China Unicom is working on deploying Wi-Fi hotspots and Small cells to meet their customers needs. The complete presentation is below and available from Slideshare.

Progress on WLAN and Small Cellin China Unicom from Zahid Ghadialy

Small Cells Backhaul & Coordination

An interesting presentation from the Small Cells Backhaul Summit in June 2014. Time synchronization between Macro and Small cells are becoming very important for new features like eICIC, CoMP, etc. This presentation provides some insights into this.

MEF: LTE/LTE-A Small Cell Backhaul from Zahid Ghadialy