Friday, 2 September 2016

Some more thoughts on 5G

5G is often seen as a panacea for everything that is imperfect in mobile technology. Any issues with coverage, capacity, connectivity and speed are all expected to be solved with the arrival of 5G. While I don’t think we will be able to solve all the issues on the table, 5G will hopefully resolve quite a few of them.

Back in June I did an interview with the organizers of 5G World Series where I expressed my views for the questions that were posed to me. You can see this interview below.


Now that I have had time to think about the questions, here are a bit more detailed thoughts. As always, feedback, comments & suggestions welcome


Q: What will network architecture look like in the 5G era?

I have long argued that 5G will not be a single technology but a combination of multiple old and new technologies. You will often find various terms like Multi-stream Aggregation (MSA), Opportunistic Aggregation and Multi-connectivity being used to explain this. Not only will 2G, 3G and 4G have a role to play, Wi-Fi and other unlicensed technologies would be a part of 5G too.

I have had many discussions on this topic with respected analysts and many of them agree.
One of the approaches being proposed for the initial version of 5G is the non-standalone version of 5G which will use LTE as the control plane anchor and new 5G radio for user plane. Not only will this be easier to deploy along with the existing LTE network, it would be faster and hopefully less costly.

Q: To what extent is 5G dependent on virtualization?

Networks and Network Functions are progressively being virtualized, independently of 5G. Having said that, virtualization will play a big role in achieving the 5G architecture. Mobile operators can’t be expected to keep paying for proprietary hardware; virtualization would help with cost reduction and quick deployments.

Network slicing for instance will help partition the network for different requirements, on the fly depending on what is going on at any particular time.

Related post: 5G, NFV and Network Slicing


Q: What is your view on the interplay between standards and open-source developments?

Standards enable cost reduction by achieving economy of scale whereas open-source development enable innovation and quick deployment. They are both needed and they will willingly or unwillingly co-exist.


Q: What do you see as the 3 greatest technical uncertainties or challenges on route to 5G?

While there are many known and unknown challenges with 5G, some obvious ones that we can see are:

  • Spectrum identification and harmonization.
  • Getting to the right architecture which is backward compatible and future proof, without making it too complex
  • SON – Once you have everything in place you have to make many different parts of the network work together with different kinds of loads and traffic. SON will play a crucial role here.


Q: What would 5G actually mean for consumers, business and IoT? / What will 5G allow me to do that I can’t right now with 4G?

There are a lot of interesting use cases being discussed like remote operations and remote controlled cars but most of them do not represent the general consumers and some of them are just gimmicks.

NGMN - 5G Use case families and related examples

I really like the NGMN whitepaper that laid out some simple use cases.

If done properly, 5G will allow:

  • Simplification of the network resulting in low latency – this means that your content will load faster and the delay between requests and responses are small. 
  • Reasonable speed broadband everywhere - This will also depend on the operators’ rollouts plan but different technologies in 5G network would (should) enable a good speed reliable broadband not just in the middle of the cell but also on the edges. In fact, the concept of edges should be looked at in 5G and a solution to avoid data rates falling off should be found.
  • Connectivity on the move – Whether we are talking about connectivity in trains/buses or from public safety point of view, it is important to define group connectivity, direct communications, etc.


Q: What will set companies apart in the development of 5G?

The days of vendor lock-ins are over. What will set companies apart is their willingness to be open to working with other companies by having open API’s and interfaces. Operator networks will include solutions from many different vendors. For them to be quick to bring innovative solutions to the market, they need vendors to work together rather than against each other.


Q: There is a lot of talk about the vision for 2020. What do you think the world will look like in terms of connectivity in 2030?

It would be fair to say that by 2030, connectivity would have reached a completely new dimension. One of the big areas of development that is being ignored by mainstream mobile community is the development of satellite communications. There are many low earth orbit (LEO) constellations and high-throughput satellites (HTS) being developed. These LEO and HTS combination can provide high speed connectivity with 4G like latency and high throughputs for planes/ships which cannot be served by ground based mobile technology. Broadband access everywhere will only become a reality with satellite technology complementing mobile technology.

Related Post: The role of satellites in 5G world

Disclaimer: This blog is maintained in my personal capacity and this post expresses my own personal views, not the views of my employer or anyone else. 

Saturday, 27 August 2016

Dedicated Core Networks (DCN) for different traffic types

Looking at a paper (embedded below) from NTT Docomo technical journal where they talk about Dedicated Core Network (DCN) for handling different traffic type (M2M/IoT for example). Note that this approach is different from NFV based network sliced architecture. For the latter, the network functions should have been virtualized.


There will be some signalling overhead in the core network to handle the new core and reroute the traffic according destined for the new dedicated core. I would still hope that this would be minuscule in the grand scheme of things. Anyway, let me know what you think about the paper below.



Wednesday, 24 August 2016

Connected and Autonomous vehicles: Beyond Infotainment and Telematics

An interesting presentation from the recent Cambridge Wireless Future of Wireless International Conference 2016, delivered by David Wong of SMMT. The presentation and video of this talk is embedded below.





You can view many presentations from #FWIC16 at Cambridge Wireless page here and videos here.

Sunday, 14 August 2016

3GPP Release-14 & Release-15 update

3GPP is on track for 5G as per a news item on the 3GPP website. In 5G World in London in June, Erik Guttman, 3GPP TSG SA Chairman, and Consultant for Samsung Electronics spoke about progress on Release-14 and Release-15. Here is his presentation.



According to 3GPP:

The latest plenary meeting of the 3GPP Technical Specifications Groups (TSG#72) has agreed on a detailed workplan for Release-15, the first release of 5G specifications.
The plan includes a set of intermediate tasks and check-points (see graphic below) to guide the ongoing studies in the Working Groups. These will get 3GPP in a position to make the next major round of workplan decisions when transitioning from the ongoing studies to the normative phase of the work in December 2016:- the start of SA2 normative work on Next Generation (NexGen) architecture and in March 2017:- the beginning of the RAN Working Group’s specification of the 5G New Radio (NR).
3GPP TSG RAN further agreed that the target NR scope for Release 15 includes support of the following:
  • ■ Standalone and Non-Standalone NR operation (with work for both starting in conjunction and running together)
    • ■ Non-standalone NR in this context implies using LTE as control plane anchor. Standalone NR implies full control plane capability for NR.
    • ■ Some potential architecture configuration options are shown in RP-161266 for information and will be analyzed further during the study
  • ■ Target usecases: Enhanced Mobile Broadband (eMBB), as well as Low Latency and High Reliability to enable some Ultra-Reliable and Low Latency Communications (URLCC) usecases
  • ■ Frequency ranges below 6GHz and above 6GHz
During the discussion at TSG#72 the importance of forward compatibility - in both radio and protocol design - was stressed, as this will be key for phasing-in the necessary features, enabling all identified usecases, in subsequent releases of the 5G specification.


Telecom TV has posted a video interview with Erik Guttman which is embedded below:



Related posts:



Wednesday, 10 August 2016

New whitepaper on Narrowband Internet of Things

Rohde & Schwarz has just published a new whitepaper on Narrowband Internet of Things (NB-IoT).

NB-IoT has been introduced as part of 3GPP Rel-13 where 3GPP has specified a new radio interface. NBIoT is optimized for machine type traffic and is kept as simple as possible in order to reduce device costs and to minimize battery consumption. In addition, it is also adapted to work in difficult radio conditions, which is a frequent operational area for certain machine type communication devices. Although NB-IoT is an independent radio interface, it is tightly connected with LTE, which also shows up in its integration in the current LTE specifications.
The paper contains the necessary technical details including the new channels, new frame and slot structure, new signalling messages including the system information messages, etc. It's a good read.

Its embedded below and can be downloaded from here:



Related posts:

Monday, 1 August 2016

Antenna evolution: From 4G to 5G


I came across this simple Introduction to Antenna Design videos that many will find useful (including myself) for the basics of Antenna. Its embedded below:


In the recently concluded 5G World 2016, Maximilian Göttl, Senior Director, Research & Development, Mobile Communication Systems, Kathrein gave an interesting presentation on Antenna Evolution, from 4G to 5G. The presentation is embedded below.

Please share your thoughts in this area in the comments section below.



Thursday, 21 July 2016

Next Generation SON for 5G

There were quite a few interesting presentations in the recently concluded 5G World conference. One that caught my attention was this presentation by Huawei. SON is often something that is overlooked and is expected to be a part of deployment. The problem is that it is often vendor proprietary and does not work as expected when there is equipment from multiple vendors.

While the 4G SON in theory solves the issues that network face today, 5G SON will have to go much further and work with SDN/NFV and the sliced networks. Its going to be a big challenge and will take many years to get it right.

Here is the Huawei presentation from 5G World:



You may also be interested in:
Feel free to let me know your thoughts as comments.

Sunday, 17 July 2016

Two VoLTE Deployment Case Studies

Back in 2011, I was right in predicting that we will not see VoLTE as early as everyone had predicted. Looking through my twitter archive, I would say I was about right.



The big issue with VoLTE has always been the complexity. In a post last year I provided a quote from China Mobile group vice-president Mr.Liu Aili, "VoLTE network deployment is the one of the most difficult project ever, the implementation complexity and workload is unparalleled in history".



From a recent information published by IHS, there will only be 310 million subscribers by end of 2016 and 2020 is when 1 billion subscribers can make use of VoLTE. I think the number will probably be much higher as we will have VoLTE by stealth.


Below are couple of case studies, one from SK Telecom, presented by Chloe(Go-Eun) Lee and other from Henry Wong, CTO Mobile Engineering, Hong Kong Telecom (HKT). Hope you find them informative and useful.






Wednesday, 13 July 2016

Feasibility Study on New Services and Markets Technology Enablers for 5G

3GPP SA1 (see tutorial about 3GPP if you dont know) recently released four new Technical Reports outlining the New Services and Markets Technology Enablers (SMARTER) for next generation mobile telecommunications.

3GPP TR 22.891 has already identified over 70 different which are into different groups as can be seen in the picture above. These groups are massive Internet of Things (MTC), Critical Communications, enhanced Mobile Broadband, Network Operation and Enhancement of Vehicle-to-Everything (eV2X).

The first 4 items have their own technical reports (see below) but work on the last item has only recently started and does not yet have a TR to show to the outside world. It is foreseen that when there are results from the eV2X study these will be taken on board in the Smarter work. (thanks to Toon Norp for this info)

The four Technical Reports (TR) are:
  • TR 22.861, FS_SMARTER – massive Internet of Things (MTC): Massive Internet of Things focuses on use cases with massive number of devices (e.g., sensors and wearables). This group of use cases is particularly relevant to the new vertical services, such as smart home and city, smart utilities, e-Health, and smart wearables.
  • TR 22.862, FS_SMARTER – Critical Communications: The main areas where improvements are needed for Critical Communications are latency, reliability, and availability to enable, for example, industrial control applications and tactile Internet. These requirements can be met with an improved radio interface, optimized architecture, and dedicated core and radio resources.
  • TR 22.863, FS_SMARTER – enhanced Mobile Broadband: Enhanced Mobile Broadband includes a number of different use case families related to higher data rates, higher density, deployment and coverage, higher user mobility, devices with highly variable user data rates, fixed mobile convergence, and small-cell deployments.
  • TR 22.864, FS_SMARTER – Network Operation: The use case group Network Operation addresses the functional system requirements, including aspects such as: flexible functions and capabilities, new value creation, migration and interworking, optimizations and enhancements, and security.
Embedded below is 3GPP TR 22.891 which has a lot of interesting use cases and makes a useful reading.




Friday, 1 July 2016

EE's vision of Ultra-Reliable Emergency Network


Many of my readers would be aware that UK is probably the first country to have decided to move its emergency services network from an existing TETRA network to a commercial LTE network operated by EE.

While some people have hailed this as a very bold move in the right direction, there is no shortage of critics. Around 300,000 emergency services users will share the same infrastructure used by over 30 million general users.

The following is from an article in Wireless Magazine:

Steve Whatson, deputy director Delivery, Emergency Services Mobile Communications Programme (ESMCP) – the organisation within the UK Home Office procuring ESN – assured delegates that ESN will match the existing dedicated Airwave emergency services communication network in terms of coverage for roads, outdoor hand portable devices and marine coverage. Air to ground (A2G) will extend its reach from 6,000ft to 12,000ft.

Whatson also pointed out that coverage is not one single piece, but will comprise a number of different elements, which all need to mesh into one seamless network run by the ESN Lot 3 Mobile Services (main 4G network) provider – EE.

This includes: EE’s main commercial 4G network; Extended Area Services (hard-to-reach areas of the UK where new passive sites are to be built under a separate contract and then equipped with EE base stations); air-to-ground; London Underground; Crossrail; marine coverage (to 12 nautical miles); and special coverage solutions.

EE is currently rolling out new 4G sites – it will eventually have some 19,500 sites – and is upgrading others with 800MHz spectrum, which propagates over longer distances and is better at penetrating buildings than its other 4G spectrum holdings. Crucially for ESN, it is also switching on a Voice over LTE (VoLTE) capability, starting with the UK’s main cities.
...
Mission critical networks must be always available and have levels of resilience far in excess of commercial networks. Speaking exclusively to Wireless in early May, Tom Bennett, group director Technology Services, Architecture & Devices at EE, said: ‘We already achieve a very high availability level, but what the Home Office was asking for effectively was about a 0.3% increase against our existing commercial availability levels.

‘Now for every 0.1% increase in availability there is a significant investment because you are at the extreme top end of the curve where it is harder and harder to make a noticeable difference.’

There are very specific requirements for coverage and availability of the ESN network for the UK road system. Bennett says: ‘Mobile is based on a probability of service. No more than 1% of any constabulary’s roads are allowed to be below 75% availability, and on major roads it is 96% availability. A coverage gap in this context is no more than 1km.’

The current Airwave network has approximately 4,000 sites, many with back-up generators on site with fuel for seven days of autonomous running if the main power is cut, along with a range of resilient backhaul solutions.

Bennett says that out of EE’s 18,500 sites it has about the same number of unique coverage sites (ie. no overlapping coverage) – around 4,000. ‘As part of our investment programme, those unique coverage sites will need a significant investment in the causes of unavailability – ie. resilient backhaul and back-up batteries.’

He explains that EE has undertaken a lot of analysis of what causes outages on its network, and it has combined that data with the Home Office’s data on where the natural disasters in the UK have occurred over the past 10 years.

From this, EE is able to make a reasonable assessment of which sites are likely to be out of action due to flooding or other disasters for more than three or four days. ‘For those sites – and it is less than 4,000 – you need generators too, because you may not be able to physically access the sites for some days,’ says Bennett.

For obvious reasons, the unique coverage sites are mostly in rural areas. But as Bennett points out, the majority of cases where the emergency services are involved is where people are – suburban and urban areas.

‘In these areas EE has overlapping coverage from multiple sites to meet the capacity requirements, so if a site goes down, in the majority of cases we have compensation coverage. A device can often see up to five tower sites in London, for example,’ he says.

Having adequate backhaul capacity – and resilient backhaul at that – is vital in any network. Bennett says EE is installing extra backhaul, largely microwave and fibre, but other solutions will also be used including satellite and LTE relay from base station to base station – daisy chaining. On 9 May 2016, EE announced a deal with satellite provider Avanti to provide satellite backhaul in some areas of the UK.

Additional coverage and resilience will be offered by RRVs (rapid response vehicles), which EE already has in its commercial network today, for example, to provide extra capacity in Ascot during the racing season.

‘We would use similar, although not exactly the same technology for disaster recovery and site/service recovery, but with all the backhaul solutions,’ says Bennett. ‘Let’s say we planned some maintenance or upgrade work that involved taking the base station out for a while.

‘We’d talk to the chief inspector before the work commences. If he says, there’s no chance of doing that tonight, we can put the RRV there, and provided we maintain coverage, we can carry out the work. RRVs are a very good tool for doing a lot of things.’

At the British APCO event, Mansoor Hanif, director of Radio Access Networks at EE said it was looking at the possibility of using ‘airmasts’ to provide additional coverage. Meshed small cells, network in a box and repeater solutions are becoming available for these ‘airmasts’, which will provide coverage from balloons, or UAVs – tethered drones with power cables and optical fibre connected to them.

Mansoor Hanif, Director of RAN at EE gave a presentation on this at Critical Communications World 2016 and has also given an interview. Both are embedded below.






Feel free to let me know if you believe this will work or not and why.