Sunday, 26 June 2016

Three Presentations on 5G Security


Here are three presentations from the 5G Huddle in April, looking at 5G security aspects. As I have repeatedly mentioned, 5G is in process of being defined so these presentations are just presenting the view from what we know about 5G today.



Friday, 17 June 2016

History: 30 years of the mobile phone in the UK


In January 1985 the UK launched its first mobile networks. Now, thirty years on, many people and companies in the UK have been celebrating this enormous achievements and advances that have been made since then and which have seen the mobile evolve from a humble telephone into the multimedia pocket computer which has become such an essential part of modern life. It was simply not possible in 1985 to envisage a country that would be able to boast more active mobile phones than people or to have along the way clocked up several world firsts, and be now leading on the deployment of 4G and shaping the future 5G technologies.

Below is a series of talks in an event organised by University of Salford,



The following talks are part of playlist:

1. Launch of Vodafone – Nigel Linge, on behalf of Vodafone
2. Launch of Cellnet - Mike Short, O2
3. The emergence of GSM - Stephen Temple, 5GIC
4. The launch of Mercury one2one and Orange - Graham Fisher, Bathcube Telecoms
5. From voice to data - Stuart Newstead, Ellare
6. Telepoint - Professor Nigel Linge, University of Salford
7. 3G - Erol Hepsaydir, 3 UK
8. Handset evolution and usage patterns - Julian Divett, EE
9. 4G and onwards to 5G – Professor Andy Sutton, EE  and University of Salford.

For anyone interested in reading about the history of mobile phones in UK, read this book below with more facts and figures


If you have any facts to share, please feel free to add in the comments below.

Sunday, 12 June 2016

AT&T's 5G Trials


There was a news recently that "AT&T 5G trials expand, break 10 Gbps throughput". The article said:

Austin, Texas, where RCR Wireless News and Industrial IoT 5G Insights is headquartered, is where AT&T worked with the Federal Communications Commission to get an experimental license to conduct 5G technology trials using spectrum in the 3.4-3.6 GHz, 3.7-4.2 GHz, 14.5-15.35 GHz and 27.5-28.5 GHz bands. The carrier said the testing would be used for “experimental equipment” in support of “potential (5G) multi-gigabyte per second applications for fixed and mobile wireless communication networks at higher transmission rates and lower latency than is currently available,” and supporting voice, video and data.
...
“We’ve seen great results in our 5G lab trials, including reaching speeds above 10 gigabits per second in early tests with Ericsson,” said Tom Keathley, SVP of wireless network architecture and design at AT&T. “Nokia is joining to help us test millimeter wave, which we expect to play a key role in 5G development and deployment. The work coming out of AT&T Labs will pave the way toward future international 5G standards and allow us to deliver these fast 5G speeds and network performance across the U.S.”

While I have seen speed records being set, this will not be of much help in the final standards. Some of you may remember my earlier post where Huawei achieved over 100Gbps in their labs. See here.

A video from recent AT&T mmWave trials is below:

Saturday, 4 June 2016

5G and Future Technologies from Johannesberg Summit

Johannesberg Summit is an annual forum to discuss how Wireless ICT is transforming business and society.  Interesting talks from industry leaders and leading academics are mixed with panel discussions with a broad perspective on technologies, services, business and policy models that may have an impact in the long-range evolution of society and various industries. Topics have over the years included future user behavior and requirements, novel services and applications, new business models as well as policy and regulation. These more general topics have been matched with visions on how wireless technologies and architectures can handle these needs.

The 2016 summit had 4 key topic areas:

  • The transformation of the transport industry
  • The transformation of the manufacturing industry (“Industry 4.0”)
  • Future key technologies
  • Update on 5G year


The best things is that they make all the presentations available online. Initially in the video form and later on the PDF's as well. I am embedding playlist of all video talks below but have a look at the program here.




You can also look at the 2015 program here that includes videos and PDFs of the presentations from last year.

Sunday, 29 May 2016

5G & 802.11ax


Samsung is one of the 5G pioneers who has been active in this area for quite a while, working in different technology areas but also making results and details available for others to appreciate and get an idea on what 5G is all about. 

I published a post back in 2014 from their trials going on then. Since then they have been improving on these results. They recently also published the 5G vision paper which is available here and here.



In the recent 5G Huddle, Raj Gawera from Samsung gave an excellent presentation (below) on the topic of "The future connected world". 



What we really liked is how closely 5G and 802.11ax can be considered aligned, not only in terms of requirements but also the roadmap.

Anyway, here is the presentation embedded below. Let me know what you think in the comments below.


Sunday, 22 May 2016

QCI Enhancements For Mission Critical Communications

Its been quite a while since I posted about QCI and end-to-end bearer QoS in EPC. In LTE Release-12 some new QCI values were added to handle mission critical communications.


This picture is taken from a new blog called Public Safety LTE. I have discussed about the Default and Dedicated bearers in an earlier post here (see comments in that post too). You will notice in the picture above that new QCI values 65, 66, 69 & 70 have been added. For mission critical group communications new default bearer 69 would be used for signalling and dedicated bearer 65 will be used for data. Mission critical data would also benefit by using QCI 70.


LTE for Public Safety that was published last year provides a good insight on this topic as follows:

The EPS provides IP connectivity between a UE and a packet data network external to the PLMN. This is referred to as PDN connectivity service. An EPS bearer uniquely identifies traffic flows that receive a common QoS treatment. It is the level of granularity for bearer level QoS control in the EPC/E-UTRAN. All traffic mapped to the same EPS bearer receives the same bearer level packet forwarding treatment. Providing different bearer level packet forwarding treatment requires separate EPS bearers.

An EPS bearer is referred to as a GBR bearer, if dedicated network resources related to a Guaranteed Bit Rate (GBR) are permanently allocated once the bearer is established or modified. Otherwise, an EPS bearer is referred to as a non-GBR bearer.

Each EPS bearer is associated with a QoS profile including the following data:
• QoS Class Identifier (QCI): A scalar pointing in the P-GW and eNodeB to node-specific parameters that control the bearer level packet forwarding treatment in this node.
• Allocation and Retention Priority (ARP): Contains information about the priority level, the pre-emption capability, and the pre-emption vulnerability. The primary purpose of the ARP is to decide whether a bearer establishment or modification request can be accepted or needs to be rejected due to resource limitations.
• GBR: The bit rate that can be expected to be provided by a GBR bearer.
• Maximum Bit Rate (MBR): Limits the bit rate that can be expected to be provided by a GBR bearer.

Following QoS parameters are applied to an aggregated set of EPS bearers and are part of user’s subscription data:
• APN Aggregate Maximum Bit Rate (APN-AMBR): Limits the aggregate bit rate that can be expected to be provided across all non-GBR bearers and across all PDN connections associated with the APN.
• UE Aggregate Maximum Bit Rate (UE-AMBR): Limits the aggregate bit rate that can be expected to be provided across all non-GBR bearers of a UE. The UE routes uplink packets to the different EPS bearers based on uplink packet filters assigned to the bearers while the P-GW routes downlink packets to the different EPS bearers based on downlink packet filters assigned to the bearers in the PDN connection.

Figure 1.5 above shows the nodes where QoS parameters are enforced in the EPS system.

Related links:



Saturday, 14 May 2016

4G / LTE by stealth


In the good old days when people used to have 2G phones, they were expensive but all people cared about is Voice & SMS.


The initial 3G phones were bulky/heavy with small battery life, not many apps and expensive. There was not much temptation to go and buy one of these, unless it was heavily subsidised by someone. Naturally it took a while before 3G adoption became common. In the meantime, people had to go out of their way to get a 3G phone.

With 4G, it was a different story. Once LTE was ready, the high end phones started adding 4G in their phones by default. What it meant was that if the operator enabled them to use 4G, these devices started using 4G rather than 3G. Other lower end devices soon followed suit. Nowadays, unless you are looking for a real cheap smartphone, your device will have basic LTE support, maybe not advanced featured like carrier aggregation.

The tweets below do not surprise me at all:



This is what I refer to as 4G or LTE by stealth.

Occasionally people show charts like these (just using this as a reference but not pin pointing anyone) to justify the 5G growth trajectory with 4G in mind. It will all depend on what 5G will mean, how the devices look like, what data models are on offer, what the device prices are like, etc.

I think its just too early to predict if there will be a 5G by stealth.

Monday, 2 May 2016

Does 5G need 'Next Generation' of Internet Protocols?

I have often heard Martin Geddes mention that the Internet is broken, the protocols (TCP/IP) are wrong and if we want to continue the way our data usage is going, we need to define new protocols (see here for example). It was good to find out last week at 5G Huddle that ETSI is already working on this.


The TCP/IP protocol suite has undoubtedly enabled the evolution of connected computing and many other developments since its invention during the 1970’s. Thanks to the development and ubiquity of this protocol stack, we have managed to build an Internet on which we are dependent as a communications tool, an information storage and distribution tool, a marketing channel and a sales and distribution platform, for consumers and for businesses large and small.

However, the industry has reached a point where forward leaps in the technology of the local access networks will not deliver their full potential unless, in parallel, the underlying protocol stacks used in core and access networks evolve. The development of future 5G systems presents a unique opportunity to address this issue, as a sub-optimal protocol architecture can negate the huge performance and capacity improvements planned for the radio access network.

ETSI has created an Industry Specification Group to work on Next Generation Protocols (NGP ISG), looking at evolving communications and networking protocols to provide the scale, security, mobility and ease of deployment required for the connected society of the 21st century.

The NGP ISG will identify the requirements for next generation protocols and network architectures, from all interested user and industry groups. Topics include:

  • Addressing
  • Security, Identity, Location, Authorization, Accounting/Auditing and Authentication
  • Mobility
  • Requirements from Internet of Things
  • Requirements from video and content distribution
  • Requirements from ultra‐low latency use cases from different sectors (i.e. automotive)
  • Requirements from network operators (e.g. challenges with E2E encrypted content)
  • Requirements from eCommerce
  • Requirements for increased energy efficiency within the global ICT sector.


This ISG is seen as a transitional group i.e. a vehicle for the 5G community (and others of interest) to first gather their thoughts and prepare the case for the Internet community’s engagement in a complementary and synchronised modernisation effort.

The ISG provides a forum for interested parties to contribute by sharing research and results from trials and developments in such a way that a wider audience can be informed. Other standards bodies will be involved so that parallel and concerted standardization action can take place as a further step in the most appropriate standards groups.

Andy Sutton, chair of the NGP recently gave the following presentation in 5G Huddle:



Please feel free to add your opinions in the comments.

Further reading:

**** Added 05/06/2016:20.00 ****
A whitepaper published by ETSI on this topic is available here and embedded below:


Saturday, 23 April 2016

5G & Accident Free Driving


ETSI recently held a workshop titled "5G: From Myth to Reality". There were some interesting presentations and discussions, hopefully I will get a chance to write a bit more about it.

One interesting presentation was how 5G will make accident free driving a reality. While the current approach is to use the 802.11p standards that uses the license exempt 5.9GHz band, there is a possibility of enhancements based on 5G


As the final 2 slides say, What could be the use cases for 5G in vehicles? The answer suggested:

  • Map update for highly automatic driving - Instantly update the map of vehicle's surrounding. The challenge of this use case is that the vehicle is currently in the tile that needs to be updated, hence a very quick update is required. 
  • Precise Positioning high speed, no GPS, support for vehicles without high precision location tracking like cars 
  • Audio / Video Streaming (Entertainment) 
  • Online Gaming - side jobs 
  • Sensor- and State Map Sharing (Sensor Raw Data) - Transmit raw sensor data such that others can use their own classifiers to infer decisions
  • Camera and Radar sharing to improve visibility, including See-Through Share sensor information to augment ego vehicle's view. Allows for better visibility in presence of obstructing vehicles, heavy rain / fog, etc. 
  • Short-Term Sensor sharing for crash mitigation - Mitigate crash between multiple vehicle by last-minute traffic exchange 
  • Traffic forwarding using cars as relays Extend coverage or improve efficiency by using the car as a relay 
  • Teleoperated Driving "Let car be controlled by off-site driver / car operator e.g. car sharing, taxi operator, …“ 
  • Augemented Reality, e.g. Daytime-Visibility at night)

Here is the complete presentation, let me know what you think:



Sunday, 17 April 2016

NTT Docomo's 5G Treasure Trove


NTT Docomo's recent technical journal has quite a few interesting 5G articles. While it is well known that 5G will be present in Japan in some or the other shape by 2020, for the summer Olympics, NTT Docomo started studying technologies for 5G in 2010. Some of these have probably ended in 4.5G, a.k.a. LTE-Advanced Pro.

While there are some interesting applications and services envisioned for 5G, I still think some of these can be met with LTE-A and some of them may not work with the initial versions of 5G

As far as 5G timetable is concerned, I recently posted a blog post on this topic here. Initial versions of 5G will have either little or no millimetre wave (mmWave) bands. This is because most of these would be finalised in 2019 after WRC-19 has concluded. It may be a touch challenge to move all the existing incumbents out of these bands or agree of a proper sharing mechanism.

'5G+' or '5G phase 3' will make extensive use of these higher frequency bands extensively in addition to the low and mid frequency bands. For anyone not familiar with different 5G phases, please see this earlier post here.

Enhanced LTE (or eLTE) is probably the same as LTE-Advanced Pro. Docomo believes that the initial 5G deployment would include new RAT but existing 4G core network which would be enhanced later for 5G+. Some of this new RAT technologies are discussed as well.

Core Network evolution is another interesting area. We looked at a possible architecture evolution here. To quote from the magazine:

The vision for future networks is shown in Figure 3. A future network will incorporate multiple radio technologies including LTE/LTE-Advanced, 5G New Radio Access Technology (RAT), and Wi-Fi, and be able to use them according to the characteristics of each service.

Utilizing virtualization technologies, network slices optimized for service requirements such as high efficiency or low delay can be created. Common physical devices such as general-purpose servers and Software Defined Network (SDN) transport switches will be used, and these networks will be provided to service providers. Network slices can be used either on a one service per network basis to increase network independence for originality or security, or with multiple services on one slice to increase statistical multiplexing gain and provide services more economically.

The specific functional architecture and the network topology for each network slice are issues to be studied in the future, but in the case of a network slice accommodating low latency services, for example, GateWay (GW) functions would need to be relatively close to radio access, service processing would be close to terminals, and routing control capable of finding the shortest route between terminals would be necessary to reduce latency. On the other hand, a network slice providing low volume communications to large numbers of terminals, such as with smart meters, would need functionality able to transmit that sort of data efficiently, and such terminals are fixed, so the mobility function can be omitted. In this way, by providing network slices optimized according to the requirements of each service, requirements can be satisfied while still reducing operating costs.

The magazine is embedded below and available to download from here:





See Also: