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:

• IET Lecture: 5G – Getting Closer to Answers?
• Possible 5G Network Architecture Evolution
• 5G and Evolution of the Inter-connected Network
• 5G, NFV and Network Slicing
• 'Mobile Edge Computing' (MEC) or 'Fog Computing' (fogging) and 5G & IoT

Some interesting April Fools' Day 2016 Technology Jokes

When I posted April Fools' jokes on the blog last couple of years (see 2014 & 2015) , they seem to be very popular so I thought its worth posting them this year too. If I missed any interesting ones, please add in comments.

The one I really liked best is the Samsung Internet of Trousers (IoT) featuring:

Wi-Fly: Gone are the days of unnoticed, unzipped trouser zippers upon exiting the restroom. Should your fly remain open for more than three minutes, the ZipARTIK module will send a series of notifications to your smartphone to save you from further embarrassment.

Get Up! Alert: Using pressure sensors, Samsung’s intelligent trousers detect prolonged periods of inactivity and send notifications to ‘get up off of that thing’ at least once an hour. Should you remain seated for more than three hours, devices embedded in each of the rear pockets send mild electrical shocks to provide extra motivation.

Keep-Your-Pants-On Mode: Sometimes it’s easy to get carried away with the moment. The Samsung Bio-Processor in your pants checks your bio-data including your heart rate and perspiration level. If these indicators get too high, Samsung’s trousers will send you subtle notifications as a reminder of the importance of keeping your cool.

Fridge Lock: If the tension around your waist gets too high, the embedded ARTIK chip module will send signals to your refrigerator to prevent you from overeating. The fridge door lock can then only be deactivated with consent from a designated person such as your mother or significant other.

Microsoft has an MS-DOS mobile in mind for this day. I wont be surprised if a real product like this does become popular with older generation. I personally wouldn't mind an MS-DOS app on my mobile. Here is a video:

It would have been strange if we didnt have a Robot for a joke. Domino's have introduced the Domimaker. Here's how it works:

T-Mobile USA is not shy pulling punches on its rivals with the Binge On data plan where it lets people view certain video channels without using up their data. Here is the video and more details on mashable.

Introducing the #ExoKinetic, a power generator for your smartphone that recharges itself. pic.twitter.com/rIABAk6tCL

— Samsung Exynos (@SamsungExynos) April 1, 2016

Samsung ExoKinetic helps your phone self-charge

Google had quite a few pranks as always. I will ignore 'mic drop' which backfired and caused them headache.

Google Express has a new delivery mechanism, just for the April Fool's day. (There has to be one drone idea)

Google Cardboard Plastic is an interesting one too. Here is the video:


Finally, its the Google Fiber Teleportation.

Other interesting ones:

• US Army scientists successfully 'teleport' Soldiers
• CNN: April Fools' Day 2016: Best and worst jokes
• Introducing BBC Store Video
• BMW invents revolutionary baby shoes that will stop your toddler from falling over
• TNW: The best and worst tech April Fools’ 2016 jokes
• 9To5Google: Roundup: Top April Fools’ products gags from Google, Samsung, and more
• GeekWire: What’s realer than real?
• BGR: April Fools’ roundup: All the best jokes from around the web
• Virgin America redesigns logo for April Fools' Day

Smartphones: It came, It saw, It conquered

Smartphones have replaced so many of our gadgets. The picture above is a witness to how all the gadgets have now been replaced by smartphones. To some extent hardware requirements have been transferred to software requirements (Apps). But the smartphones does a lot more than just hardware to software translation.

Most youngsters no longer have bookshelves or the encyclopedia collections. eBooks and Wikipedia have replaced them. We no longer need sticky notes and physical calendars, there are Apps for them.

Back in 2014, Benedict Evans posted his "Mobile is Eating the world" presentation. His presentation has received over 700K views. I know its not as much as Justin Bieber's songs views but its still a lot in the tech world. He has recently updated his presentation (embedded below) and its now called "Mobile ate the world".

We sometimes think of the shift to mobile as finished, or almost finished. It isn't. pic.twitter.com/l5gaiMlaoU

— Benedict Evans (@BenedictEvans) March 12, 2016

Quite rightly, the job is not done yet. There is still long way to go. The fact that this tweet has over 600 retweets is a witness to this fact. Here are some of the slides that I really liked (and links reltaed to them - opens in a new window).

While we can see how Smartphones are getting ever more popular and how other gadgets that its replacing is suffering, I know people who own a smartphone for everything except voice call and have a feature phone for voice calls. Other people (including myself) rely on OTT for calls as its guaranteed better quality most of the time (at least indoors).

Smartphones have already replaced a lot of gadgets and other day to day necessities but the fact is that it can do a lot more. Payments is one such thing. The fact that I still carry a physical wallet means that the environment around me hasn't transformed enough for it to be made redundant. If I look in my wallet, I have some cash, a credit and debit card, driving license, some store loyalty cards and my business cards. There is no reason why all of these cannot be digital and/or virtual.

A Connected Car is a Smartphone on/with wheels.

A connected drone can be considered as smartphone that flies.

The Smartphones today are more than just hardware/software. They are a complete ecosystem. We can argue if only 2 options for OSs is good or bad. From developers point of view, two is just about right.

Another very important point to remember that smartphones enable different platforms.

Old: all software expands until it includes messaging
New: all messaging expands until it includes software

— Benedict Evans (@BenedictEvans) March 13, 2015

While we may just have messaging apps that are acting as platforms, there is a potential for a lot more.

Here is the presentation, worth reflecting on each slide:

If you haven't heard Benedict Evans speak, you can refer to a recent video by him on this topic:



Related posts on the web:

• The Second Smartphone Revolution

5G Study Item (SI) for RAN Working Groups Approved

This is from a Linkedin post by Eiko Seidel.

Earlier this month (7-10 March 2016), 3GPP TSG RAN Plenary RAN Meeting #71 took place in Göteborg, Sweden. The first 5G study item for the working groups is was approved. It involves RAN1, RAN2, RAN3 and RAN4. For details please have a look at RP-160671. 

The study aims to develop an next generation radio access technology to meet a broad range of use cases including enhanced mobile broadband, massive MTC, critical MTC, and additional requirements defined during the RAN requirements study. 

The new RAT will consider frequency ranges up to 100 GHz. 

Detailed objectives of the study item is a single technical framework addressing all usage scenarios, requirements and deployment scenarios including Enhanced mobile broadband, Massive machine-type-communications and Ultra reliable and low latency communications. 

The new RAT shall be inherently forward compatible. It is assumed that the normative specification would occur in two phases: Phase I (to be completed in June 2018) and Phase II (to be completed in December 2019). 

The fundamental physical layer signal waveform will be based on OFDM, with potential support of non-orthogonal waveform and multiple access. Basic frame structure(s) and Channel coding scheme(s) will be developed. 

Architecture work is going to be interesting, with a study of different options of splitting the architecture into a “central unit” and a “distributed unit”, with potential interface in between, including transport, configuration and other required functional interactions between these nodes. Furthermore RAN-CN interface and functional split needs to be studied, the realization of Network Slicing, QoS support etc.


The proposed timeline for 5G was also presented in a presentation as follows:

State of LTE & Connectivity

There are some reports that have been recently published on connectivity and connection numbers. This post intends to provide this info.

Facebook released "State of connectivity 2015" report. As can be seen in the picture above, at the end of 2015, estimates showed that 3.2 billion people were online. This increase (up from 3 billion in 2014) is partly attributed to more affordable data and rising global incomes in 2014. Over the past 10 years, connectivity increased by approximately 200 to 300 million people per year.

While this is positive news in terms of growth, it also means that globally, 4.1 billion people were still not internet users in 2015.

The four key barriers to internet access include:

Availability: Proximity of the necessary infrastructure required for access.
Affordability: The cost of access relative to income.
Relevance: A reason for access, such as primary language content.
Readiness: The capacity to access, including skills, awareness and cultural acceptance.

The PDF version of report is available here.

The number of LTE users crossed 1 Billion, end of 2015 according to a report by GSA. OpenSignal has a summary blog post on this here.

Finally, Open Signal has published Global State of LTE Market report that provides coverage, speeds and a lot more information.

South Korea and Singapore have set themselves apart from the main body of global operators, providing both superior coverage and speed. The biggest standouts were South Korea’s Olleh and Singapore’s Singtel. Olleh excelled in coverage, but also provided one of the fastest connections speeds in our report, 34 Mbps. Meanwhile Singtel hit the 40 Mbps mark in speed while still maintaining a coverage rating of 86%. There are other notable country clusters in the upper right-hand quadrant as well, for instance operators from the Netherlands, Canada and Hungary.

Meanwhile, other countries have staked positions for themselves in specific regions of the plot. U.S. and Kuwaiti operators are tightly clustered in the lower right, meaning they offer excellent coverage but poor 4G speeds. Japan and Taiwan congregate in the middle far right with their exceptional coverage but only average speeds. Most of New Zealand and Romania’s operators hover at the center top of the chart, indicating impressive bandwidth but a general lack of availability.

Its makes interesting reading, PDF available here.

*** Added Later: 25/03/16:12.15 ***

A good breakdown of LTE subscriptions by countries by Ovum:

The role of satellites in 5G world

While many of us have been focussing purely on wireless and mobile / 5G, the coverage and capacity provided by satellites is increasing and is set to dramatically transform connectivity in hard to reach places, not only in land but also in air and sea.

In one of my roles, I get to see some of these developments happening in the satellite world. Here are some of the recent things that I have learned.

In a recent presentation by Intelsat (embedded below), they showed how we will have a truly high throughput global coverage with the help of GEO and LEO satellites. Depending on the applications, they can take advantage of either or both. Ubiquitously connected cars, planes, trains, ships and other vehicles will soon be a reality. See their presentation below:

Intelsat is not the only operator innovating and coming up with some amazing solutions.

Viasat is another operator who will be launching one of the highest capacity HTS (High Throughput Satellite). See their presentation here and here.

Eutelsat on the other hand is trying something that has not been done before. Their Quantum class satellites will be creating and modifying the beams dynamically to provide coverage whenever and wherever needed. See their presentation here.

These are just a few examples, there are many other operators I have not mentioned here. Most of them have some sort of ambitious plan which will be there before 2020.

So what role will these satellites play in the 5G world? We will look at this question in the Satellite Applications & Services Conference in October but I am interested in hearing your thoughts. 

The Internet of Me: It’s all about my screens - Bob Schukai

I had the pleasure of attending the IET Turing lecture last week and listening to Robert Schukai. He gave a brilliant talk on how Smartphones are changing the way we do things. Its a very interesting talk but its nearly 87 minutes long. Slides are not available but the video is embedded below.

Possible 5G Network Architecture Evolution

Came across this interesting Network Architecture evolution Roadmap by Netmanias. Its embedded below and available to download from the Netmanias website.

The Art of Disguising Cellular Antennas

When I did a blog post 'Disguising Small Cells in Rural areas' last year, many people were surprised to see these things. So here is another post showing how the antennas looks like and how they have to be disguised to blend in with the environment.

The above pictures shows fake date trees (with dates) near Koutoubia mosque, Marrakech, designed to blend in with the surroundings. In fact I have been told that these fake date trees are common in the Middle East and North African countries.

The above picture is from Dubai, showing similar palm tree. Source unknown.

The above picture, courtesy of Andy Sutton on Twitter shows a cell site near Blandford Forum. I hope you can spot the fake tree on top right.

Another one, courtesy of Andy Sutton on Twitter shows a cell site between motorway M56, J10 & 11 in Cheshire. Single operator but could be shared, single frequency band, x-pole with 3 cell sectors. Only two of the possible 3 cell sectors connected here. Pointing up and down motorway hence 4 feeders.

A multi-technology cell site blending in with lighting columns in the area #industrialarchaeology #urbanlife #4GLTE pic.twitter.com/GLeickD3Em

— Andy Sutton (@960sutton) January 23, 2016

A unique looking tower #cellular #microwave #radio industrial archaeology, documenting the communications revolution pic.twitter.com/HPuqQUhdSt

— Andy Sutton (@960sutton) December 18, 2015

This is the infrastructure that keeps our smartphones connected. pic.twitter.com/H1ZemnrgYL

— Nigel Linge (@NigelLinge) December 12, 2015

Another one courtesy of Andy Sutton on Twitter. Its been disguised to not look out of place unless someone is observing very carefully.

Three cellular tree sites, powering the 4th industrial revolution. #ruralbroadband #historyoftechnology #mobilephone pic.twitter.com/ApvCyqMdao

— Andy Sutton (@960sutton) August 31, 2015

All three are fake trees and each is a separate cellular installation. The location is Lancashire, off the A6 between Slyne and Bolton-le-Sands. They are all different operators, left to right, O2, T-Mobile, Orange - although two will become one as part of EE of course.

Modern Art and Cellular Antenna, courtesy of Andy Sutton on Twitter.

What will happen when we transition to 5G, where we will have a lot more antennas because of MIMO (massive or not). China Mobile is researching into Smart Tiles, which are antennas that can be hidden inside Chinese characters. See the following for example:

With more antennas becoming commonplace in the urban environment, operators and vendors will have to keep up coming with innovative ways to disguise the antennas and hope no one notices.

See Also:

• Cellular Mobile Communications Heritage - The Association for Industrial Archaeology
• Awkward Trees - CBS News

SDN & NFV lecture

I have been meaning to add this interesting lecture delivered by Dr. Yaakov Stein of RAD at IETF.

The video, which cannot be embedded, is available here. If you cant wait to get into the main presentation, jump to 19.40 on the time bar at the bottom.

The slides from the presentation are embedded below.

Assuming that you understand NFV and SDN well, have a look at another interesting whitepaper that was published by Signals Research group, "Bending Iron – Software Defined Networks & Virtualization for the Mobile Operator", available here.

IET Lecture: 5G – Getting Closer to Answers?

I was fortunate to be able to hear the IET Appleton lecture last week. The good thing about these lectures are that the speakers get plenty of time to talk about the subject of interest and as a result they can cover the topic in much greater depth.

Some interesting tweets from the evening:

Big Data analytics for Network Optimisation #5G #IETappleton pic.twitter.com/5aj9mVFQRe

— Zahid Ghadialy (@zahidtg) January 14, 2016

This is how to camouflage 5G massive MIMO antennas by Dr. Chih-Lin I, CMRI #IETappleton pic.twitter.com/kgISkmoXMH

— Zahid Ghadialy (@zahidtg) January 14, 2016

5G DSR Shock: rethink Shannon, rethink Ring&Young, rethink Control & Signaling #ietappleton pic.twitter.com/3lfgiZ4m6C

— Martin Jakl (@JaklMartin) January 14, 2016

Here is the video:



As I was sitting in the front, I managed to ask a question - "5G is going to be evolution and revolution. Will it be revolution first then evolution or vice versa". If you cant wait to hear the answer, you can jump to 1:21:30 in the video.

The answer also ties in nicely with my Linkedin post on '5G: Mine is bigger than yours'. 

Interesting gadgets from CES 2016

Here are some gadgets from the recently concluded Consumer Electronics Show (CES) 2016. These are all collected from the tweets and there is a Youtube video below if you are interested. There are just too many interesting things to list but do let me know which ones are your favourites.

5G Spectrum Discussions

While most people are looking at 5G from the point of new technologies, innovative use cases and even lumping everything under sun as part of 5G, many are unaware of the importance of spectrum and the recently concluded ITU World Radio Conference 2015 (WRC-15).

As can be seen in the picture above, quite a few bands above 24GHz were identified for 5G. Some of these bands have an already existing allocation for mobile service on primary basis. What this means is that mobile services can be deployed in these bands. For 3G and 4G, the spectrum used was in bands below 4GHz, with 1800MHz being the most popular band. Hence there was never a worry for those high frequency bands being used for mobile communication.

As these bands have now been selected for study by ITU, 5G in these bands cannot be deployed until after WRC-19, where the results of these studies will be presented. There is a small problem though. Some of the bands that were initially proposed for 5G, are not included in this list of bands to be studied. This means that there is a possibility that some of the proponent countries can go ahead and deploy 5G in those bands.

For three bands that do not already have mobile services as primary allocation, additional effort will be required to have mobile as primary allocation for them. This is assuming that no problems are identified as a result of studies going to be conducted for feasibility of these bands for 5G.

To see real benefits of 5G, an operator would need to use a combination of low and high frequency bands as can be seen in the picture above. Low frequencies for coverage and high frequencies for capacity and higher data rates.


As I mentioned in an earlier blog post, 5G will be coming in two phases. Phase 1 will be Rel-15 in H2, 2018 and Phase 2, Rel-16, in Dec. 2019. Phase 1 of 5G will generally consist of deployment in lower frequency bands as the higher frequency bands will probably get an approval after WRC-19. Once these new bands have been cleared for 5G deployment, Phase 2 of 5G would be ready for deployment of these high frequency bands.

This also brings us to the point that 5G phase 1 wont be significantly different from LTE-A Pro (or 4.5G). It may be slightly faster and maybe a little bit more efficient.

One thing I suspect that will happen is start of switching off of 3G networks. The most commonly used 3G (UMTS) frequency is 2100MHz (or 2.1GHz). If a network has to keep some 3G network running, it will generally be this frequency. This will also allow other international users to roam onto that network. All other 3G frequencies would soon start migrating to 4G or maybe even 5G phase 1.

Anyway, 2 interesting presentations on 5G access and Future of mmWave spectrum are embedded below. They are both available to download from the UK Spectrum Policy Forum (SPF) notes page here.

Further reading:

• WRC-2015 and the impossible task of achieving a delicate balance

End to end and top to bottom network design…

A good way to start 2016 is by a lecture delivered by Andy Sutton, EE at the IET conference 'Towards 5G Mobile Technology – Vision to Reality'. The slides and the video are both embedded below. The video also contains Q&A at the end which people may find useful.

Videos of all other presentations from the conference are available here for anyone interested.

Top 10 posts for 2015

Here are the top 10 posts for 2015:

1. Voice over WiFi (VoWiFi) technical details
2. LTE-Hetnet (LTE-H) a.k.a. LTE Wi-Fi Link Aggregation (LWA)
3. New LTE UE Categories: 11, 12, 13 and 14 in 3GPP Rel-12
4. LTE Category-0 low power M2M devices
5. VoLTE Roaming: LBO, S8HR or HBO
6. M2M embedded UICC (eSIM) Architecture and Use Cases
7. The path from 4.5G to 5G
8. Quick Summary of LTE Voice Summit 2015 (#LTEVoice)
9. 5G and Evolution of the Inter-connected Network
10. Cellular IoT (CIoT) or LoRa?

Its interesting to see that Voice (VoLTE, VoWiFi, etc.) and M2M dominated most of the searches followed by 5G

ADS-B to enable global flight tracking

One of the things that the World Radio Conference 2015 (WRC-15) enabled was to provide a universal spectrum allocation for flight tracking. What this means in simple terms is that once completely implemented, flights will hopefully no longer be lost, like MH370. It will now be possible to accurately track flights with satellites across nearly 100% of the globe, up from 30% today, by 2018.

To make you better understand this, see this video below:


Automatic Dependent Surveillance (ADS) is a surveillance technique in which aircraft automatically provide, via a data link, data derived from on-board navigation and position-fixing systems, including aircraft identification, four-dimensional position and additional data as appropriate. ADS data is displayed to the controller on a screen that replicates a radar screen. ICAO Doc 4444 PANS-ATM notes that air traffic control service, may be predicated on the use of ADS provided that identification of the aircraft involved is unambiguously established. Two main versions of ADS are currently in use:

• Automatic Dependent Surveillance-Broadcast (ADS-B) is a function on an aircraft or surface vehicle that broadcasts position, altitude, vector and other information for use by other aircraft, vehicles and by ground facilities. It has become the main application of the ADS principle.
• Automatic Dependent Surveillance-Contract (ADS-C) functions similarly to ADS-B but the data is transmitted based on an explicit contract between an ANSP and an aircraft. This contract may be a demand contract, a periodic contract, an event contract and/or an emergency contract. ADS-C is most often employed in the provision of ATS over transcontinental or transoceanic areas which see relatively low traffic levels. 

The ITU press release on this topic:

The frequency band 1087.7-1092.3 MHz has been allocated to the aeronautical mobile-satellite service (Earth-to-space) for reception by space stations of Automatic Dependent Surveillance-Broadcast (ADS-B) emissions from aircraft transmitters.

The frequency band 1087.7-1092.3 MHz is currently being utilized for the transmission of ADS-B signals from aircraft to terrestrial stations within line-of-sight. The World Radiocommunication Conference (WRC-15) has now allocated this frequency band in the Earth-to-space direction to enable transmissions from aircraft to satellites. This extends ADS-B signals beyond line-of-sight to facilitate reporting the position of aircraft equipped with ADS-B anywhere in the world, including oceanic, polar and other remote areas.

WRC-15 recognized that as the standards and recommended practices (SARP) for systems enabling position determination and tracking of aircraft are developed by the International Civil Aviation Organization (ICAO), the performance criteria for satellite reception of ADS-B signals will also need to be addressed by ICAO.

This agreement follows the disappearance and tragic loss of Malaysian Airlines Flight MH370 in March 2014 with 239 people on board, which spurred worldwide discussions on global flight tracking and the need for coordinated action by ITU and other relevant organizations.

For more details see: globalflightsafety.org

LTE-Advanced Pro (a.k.a. 4.5G)

3GPP announced back in October that the next evolution of the 3GPP LTE standards will be known as LTE-Advanced Pro. I am sure this will be shortened to LTE-AP in presentations and discussions but should not be confused with access points.

3GPP Approves LTE-Advanced Pro as New Marker for LTE Evolution System (4.5G) - https://t.co/J3H7lhqAeZ pic.twitter.com/rQmAeooQqd

— Zahid Ghadialy (@zahidtg) October 28, 2015

The 3GPP press release mentioned the following:

LTE-Advanced Pro will allow mobile standards users to associate various new features – from the Release’s freeze in March 2016 – with a distinctive marker that evolves the LTE and LTE-Advanced technology series.

The new term is intended to mark the point in time where the LTE platform has been dramatically enhanced to address new markets as well as adding functionality to improve efficiency.

The major advances achieved with the completion of Release 13 include: MTC enhancements, public safety features – such as D2D and ProSe - small cell dual-connectivity and architecture, carrier aggregation enhancements, interworking with Wi-Fi, licensed assisted access (at 5 GHz), 3D/FD-MIMO, indoor positioning, single cell-point to multi-point and work on latency reduction. Many of these features were started in previous Releases, but will become mature in Release 13.

LTE-evolution timelinea 350pxAs well as sign-posting the achievements to date, the introduction of this new marker confirms the need for LTE enhancements to continue along their distinctive development track, in parallel to the future proposals for the 5G era.

Some vendors have been exploring ways of differentiating the advanced features of Release-13 and have been using the term 4.5G. While 3GPP does not officially support 4.5G (or even 4G) terminology, a new term has been welcomed by operators and vendors alike.

I blogged about Release-13 before, here, which includes a 3GPP presentation and 4G Americas whitepaper. Recently Nokia (Networks) released a short and sweet video and a whitepaper. Both are embedded below:

The Nokia whitepaper (table of contents below) can be downloaded from here.

ITU Workshop on VoLTE and ViLTE Interoperability

ITU recently held a workshop on "Voice and Video Services Interoperability Over Fixed-Mobile Hybrid Environments,Including IMT-Advanced (LTE)" in Geneva, Switzerland on 1st December 2015.

The following is the summary of that workshop:

I also like this presentation by R&S:

All the presentations from the workshop are available online from ITU website here.

Mobility challenges in Future Cities

I got an opportunity this week to attend an interesting 'Sir Henry Royce Memorial Lecture 2015' organised by The IET. The topic of the presentation was "Mobility for the 21st Century".

Professor John Miles reflected upon the reasons why the car dominates our urban environments and explored the challenges of freeing our cities from the log-jam of traffic congestion and associated pollution which currently seems inevitable. He proposition that, to be successful, future public transport and shared ridership systems must simply represent a better journey option than taking the car. The question is, as engineers, how we might meet this challenge and deliver success in the coming decades?

Some reactions from twitter:

Doesn’t make sense to kick people out of cars but to offer public transport systems that are _simply the best_ – Prof John Miles #IETroyce

— Nico Macdonald (@Nico_Macdonald) December 1, 2015

Idle capacity is the reason why public transportation emissions are not much better than cars... #IETroyce pic.twitter.com/Apr5IJsi9i

— Maria Shiao (@mariashiao) December 1, 2015

This is the scalable bus : minimises parasitic mass! #IETroyce pic.twitter.com/k5hZ7dSAFu

— Maria Shiao (@mariashiao) December 1, 2015

Anyway, the video of the presentation is as follows:





Related news:

• Could Driverless cars be heading to Cambridge thanks to UK Autodrive project?

5G, NFV and Network Slicing

5G networks have multifaceted requirements where the network needs to be optimised for data rate, delay and connection numbers. While some industry analysts suspect that these requirements cannot be met by a single network, vendors suggest that Network Slicing will allow all these requirements to be met by a single network.

Ericsson's whitepaper provides a good definition of what network slicing means:

A logical instantiation of a network is often called a network slice. Network slices are possible to create with both legacy platforms and network functions, but virtualization technologies substantially lower barriers to using the technology, for example through increased flexibility and decreased costs.

...

Another aspect of management and network slicing is setting up separate management domains for different network slices. This may allow for completely separate management of different parts of the network that are used for different purposes. Examples of use cases include mobile virtual network operators (MVNOs) and enterprise solutions. This kind of network slice would, in current Evolved Packet Core (EPC) networks, only cover the PDN gateway (PGW) and the policy control resource function (PCRF). However, for machine type communication (MTC) and machine-tomachine (M2M) solutions, it is likely that it would also cover the Mobile Management Entities (MMEs) and Serving Gateways (SGWs).

NGMN came out with the 5G whitepaper which touched on this subject too: 

Figure above illustrates an example of multiple 5G slices concurrently operated on the same infrastructure. For example, a 5G slice for typical smartphone use can be realized by setting fully-fledged functions distributed across the network. Security, reliability and latency will be critical for a 5G slice supporting automotive use case. For such a slice, all the necessary (and potentially dedicated) functions can be instantiated at the cloud edge node, including the necessary vertical application due to latency constraints. To allow on-boarding of such a vertical application on a cloud node, sufficient open interfaces should be defined. For a 5G slice supporting massive machine type devices (e.g., sensors), some basic C-plane functions can be configured, omitting e.g., any mobility functions, with contentionbased resources for the access. There could be other dedicated slices operating in parallel, as well as a generic slice providing basic best-effort connectivity, to cope with unknown use cases and traffic. Irrespective of the slices to be supported by the network, the 5G network should contain functionality that ensures controlled and secure operation of the network end-to-end and at any circumstance.

Netmanias has a detailed article on this topic which is quite interesting too, its available here.

Recently, South Korean operator SK Telecom and Ericsson concluded a successful trial of this technology, see here. Ericsson is also working with NTT Docomo on 5G including network slicing, see here.