Cell-free Massive MIMO and Radio Stripes

I wrote about "Distributed Massive MIMO using Ericsson Radio Stripes" after MWC 2019 here. I found it a very interesting concept and it will certainly take a few years before it becomes a reality.

Emil Björnson, Associate Professor at Linköping University have produced couple of videos on this topic. I am embedding both of them below for anyone who may be interested.

"A New Look at Cell-Free Massive MIMO" - based on technical paper from PIMRC 2019 on how to design Cell-free Massive MIMO systems that are both scalable and achieve high performance.



Worth noting the following about this video (based on video comments):

• There are some minor issues with the sudio
• Cell-free Massive MIMO is particularly for stadiums, streets, and places with many users or where it is hard to provide sufficient network quality with other methods.
• This concept is still 4-5 years away from being ready to be practically deployed. It should be ready for later part of 5G, probably 5.5G

"Reinventing the Wireless Network Architecture Towards 6G: Cell-free Massive MIMO and Radio Stripes" looks at the motivation behind Cell-free Massive MIMO and how it can be implemented in 6G using radio stripes.



Worth noting the following on this video (based on video comments):

• It may be possible that multiple frequency bands can be handled in the same radio stripe. If it is found to be possible then every other antenna  processing unit could manage a different band.
• In principle, you can make the stripe as long as you need. But you probably need to divide it into segments since the power is supplied from one end of a stripe and it will only reach a limited distance (roughly up to 1 km). There are many implementation ideas and it remains to be seen what works out well in practice.

I am looking forward to see it work as it can solve coverage issues in many tricky scenarios.

Related Posts:

• Distributed Massive MIMO using Ericsson Radio Stripes
• Antenna evolution: From 4G to 5G

New 3GPP Release-17 Study Item on NR-Lite (a.k.a. NR-Light)

3GPP TSG RAN#84 was held from June 3 – 6, 2019 at Newport Beach, California. Along with a lot of other interesting topics for discussion, one of the new ones for Release-17 was called NR-Lite (not 5G-lite). Here are some of the things that was being discussed for the Study item.

In RP-190831, Nokia proposed:

• NR-Lite should address new use cases with IoT-type of requirements that cannot be met by eMTC and NB-IoT:
• Higher data rate & reliability and lower latency than eMTC & NB-IoT
• Lower cost/complexity and longer battery life than NR eMBB
• Wider coverage than URLLC
• Requirements and use cases –
• Data rates up to 100 Mbps to support e.g. live video feed, visual production control, process automation
• Latency of around [10-30] ms to support e.g. remote drone operation, cooperative farm machinery, time-critical sensing and feedback, remote vehicle operation
• Module cost comparable to LTE
• Coverage enhancement of [10-15]dB compared to URLLC
• Battery life [2-4X] longer than eMBB
• Enable single network to serve all uses in industrial environment
• URLLC, MBB & positioning

The spider chart on the right shows the requirements for different categories of devices like NB-IoT, eMTC (LTE-M), NR-LITE, URLLC and eMBB.

The understanding in the industry is that over the next 5 years, a lot of 4G spectrum, in addition to 2G/3G spectrum, would have been re-farmed for 5G. By introducing NR-Lite, there would be no requirement to maintain multiple RATs. Also, NR-Lite can take advantage of 5G system architecture and features such as slicing, flow-based QoS, etc.

Qualcomm's views in RP-190844 were very similar to those of Nokia's. In their presentation, the existing 5G devices are billed as 'Premium 5G UEs' while NR-Lite devices are described as 'Low tier 5G UEs'. This category is sub-divided into Industrial sensors/video monitoring, Low-end wearables and Relaxed IoT.

The presentation provides more details on PDCCH Design, Co-existence of premium and Low Tier UEs, Peak Power and Battery Life Optimizations, Contention-Based UL for Small Data Transmission, Relaying for Wearable and Mesh for Relaxed IoT

Ericsson's presentation described NR-Lite for Industrial Sensors and Wearables in RP-191047. RP-191048 was submitted as New SID (Study Item Description) on NR-Lite for Industrial Sensors and Wearables. The SID provides the following details:

The usage scenarios that have been identified for 5G are enhanced mobile broadband (eMBB), massive machine-type communication (mMTC), and time critical machine-type communication (cMTC). In particular, mMTC and cMTC are associated with novel IoT use cases that are targeted in vertical industries. 

In the 3GPP study on “self-evaluation towards IMT-2020 submission” it was confirmed that NB IoT and LTE M fulfill the IMT-2020 requirements for mMTC and can be certified as 5G technologies. For cMTC support, URLLC was introduced in Release 15 for both LTE and NR, and NR URLLC is further enhanced in Release 16 within the enhanced URLLC (eURLLC) and Industrial IoT work items.

One important objective of 5G is to enable connected industries. 5G connectivity can serve as catalyst for next wave of industrial transformation and digitalization, which improve flexibility, enhance productivity and efficiency, and improve operational safety. The transformed, digitalized, and connected industry is often referred to as Industry 4.0. Industrial sensors and actuators are prevalently used in many industries, already today. Vast varieties of sensors and actuators are also used in automotive, transport, power grid, logistics, and manufacturing industries. They are deployed for analytics, diagnostics, monitoring, asset tracking, process control, regulatory control, supervisory control, safety control, etc. It is desirable to connect these sensors and actuators to 5G networks. 

The massive industrial wireless sensor network (IWSN) use cases and requirements described in TR 22.804, TS 22.104 and TS 22.261 do include not only cMTC services with very high requirements, but also relatively low-end services with the requirement of small device form factors, and/or being completely wireless with a battery life of several years. 

The most low-end services could already be met by NB-IoT and LTE-M but there are, excluding URLLC, more high-end services that would be challenging. In summary, many industrial sensor requirements fall in-between the well-defined performance objectives which have driven the design of eMBB, URLLC, and mMTC. Thus, many of the industrial sensors have connectivity requirements that are not yet best served by the existing 3GPP NR technology components. Some of the aforementioned requirements of IWSN use cases are also applicable to other wide-area use cases, such as wearables. For example, smart watches or heath-monitoring wearables require small device form factors and wireless operation with weeks, months, or years of battery life, while not requiring the most demanding latency or data rates. 

IWSN and wearable use cases therefore can motivate the introduction of an NR-based solution. Moreover, there are other reasons why it is motivated to introduce a native NR solution for this use case: 

• It is desired to have a unified NR based solution.
• An NR solution could provide better coexistence with NR URLLC, e.g., allowing TDD configurations with better URLLC performance than LTE.
• An NR solution could provide more efficient coexistence with NR URLLC since the same numerology (e.g., SCS) can be adopted for the mMTC part and the URLLC part.
• An NR solution addresses all IMT-2020 5G frequency bands, including higher bands and TDD bands (in FR1 and FR2).

The intention with this study item is to study a UE feature and parameter list with lower end capabilities, relative to Release 15 eMBB or URLLC NR, and identify the requirements which shall be fulfilled. E.g., requirements on UE battery life, latency, reliability, connection density, data rate, UE complexity and form factor, etc.  If not available, new potential NR features for meeting these requirements should further be studied.

There were other description of the SID from Samsung, ZTE, etc. but I am not detailing them here. The main idea is to provide an insight for people who may be curious about this feature.


Related Posts:

• 3G4G Training: Introduction to NR-Light a.k.a. NR-Lite
• The 3G4G Blog - 3GPP 5G Standardization Update post RAN#84 (July 2019)
• The 3G4G Blog - Ultra Reliability: 5x9s (99.999%) in 3GPP Release-15 vs 6x9s (99.9999%) in 3GPP Release-16
• The 3G4G Blog - 5G SpeedTests and Theoretical Max Speeds Calculations
• The 3G4G Blog - Updated 5G Terminology Presentation (Feb 2019)

Presentations from ETSI Security Week 2019 (#ETSISecurityWeek)

ETSI held their annual Security Week Seminar 17-21 June at their HQ in Sophia Antipolis, France. All the presentations are available here. Here are some I think the audience of this blog will like:

• ETSI Explainer: Overview of Quantum-Safe VPN Techniques
• ETSI Explainer: OneM2M security and Access Control (Rel.3)
• Toward a Safe Quantum Future - Michele Mosca, University of Waterloo
• Cybersecurity Challenges to Europe: Research, Policy and Standardization Effort - Fabio Di Franco, ETSI Cyber Security Landscape
• GSMA: Mobile Telecommunications Security Threat Landscape
• Hacked by Crypto - Bret Jordan, Symantec (Some good details regarding TLS, DNS, ESNI, QUIC, etc.)
• The Automotive Cyber-Threat: What the Future Will Bring Us? - Alain Baritault, iotaBEAM
• What is the Cyber Territory of a Country? - Silke Holtmanns, Nokia Bell Labs
• EU Cybersecurity Act - Martin Schaffer, SGS
• The Impact of ePrivacy Regulation to Cyber-Intelligence: Options to Consider - Ilias Chantzos, Symantec
• Applying AI to Protect 5G Control Traffic - Antonio Pastor, Telefonica I+D
• Applying AI to Detect and Hunt Advanced Attackers - Matt Walmsley, Vectra
• “Real World Adoption of AI in the Field” - Patrick Donegan, HardenStance
• 5G Providing the Secure Platform for Digitalization of Enterprises and Society - Mats Nilsson, Ericsson
• 3GPP 5G Security Vendor’s View - Marcus Wong, Futurewei Technologies (Huawei)
• 5G Security Challenges for Verticals - a Standards View - Ali Rezaki & Anja Jerichow, Nokia Bell Labs
• 5G and other stories: evolving security in an evolving world
• Challenges in Securing the IoT in a Post-Quantum World - Louis Parks, SecureRF
• SIMs, eSIMs and Secure Elements - Remy Cricco, SIMalliance
• Integrated SIMs: The next after Embedded SIM - Dr. Stephan Spitz, IAR Systems
• Deception for Continued Technical Assurance, Alex Tarter, Thales 

New abbreviation for private 5G networks - Non-Public Network (NPN) and security benefits to connected industries and automation cc @3g4gUK #EtsiSecurityWeek pic.twitter.com/Zias9e4XQ6

— Ravishankar Borgaonk (@raviborgaonkar) June 20, 2019

Looks like all presentations were not shared but the ones shared have lots of useful information.


Related Posts:

• Non-public networks (NPN) - Private Networks by another name
• 5G and IoT Security Update from ETSI Security Week 2018
• 5G Security Updates - July 2017
• Telcos: Security Is Not In Your DNA - Patrick Donegan, Principal Analyst, HardenStance

Distributed Massive MIMO using Ericsson Radio Stripes

One of the interesting things that caught my attention in MWC 2019 was the Ericsson Radio Stripes.

Emil Björnson explains it nicely in his blog as to how this works.

Distributed MIMO deployments combine the best of two worlds: The beamforming gain and spatial interference suppression capability of conventional Massive MIMO with co-located arrays, and the bigger chance of being physically close to a service antenna that small cells offer. Coherent transmission and reception from a distributed MIMO array is not a new concept but has been given many names over the years, including Distributed Antenna System and Network MIMO. Most recently, in the beyond-5G era, it has been called ubiquitous Cell-free Massive MIMO communications and been refined based on insights and methodology developed through the research into conventional Massive MIMO.

One of the showstoppers for distributed MIMO has always been the high cost of deploying a large number of distributed antennas. Since the antennas need to be phase-synchronized and have access to the same data, a lot of high-capacity cables need to be deployed, particularly if a star topology is used. 
...

For those who cannot attend MWC, further conceptual details can be found in a recent overview paper on Cell-free Massive MIMO. An even more detailed description of radio stripes can be found in Ericsson’s patent application from 2017.

The paper explains the Radio stripe system design and also lists the advantages of such a system:

The radio stripe system facilitates a flexible and cheap cell-free Massive MIMO deployment. Cheapness comes from many aspects: (i) deployment does not require highly qualified personnel. Theoretically, a radio stripe needs only one (plug and play) connection either to the front-haul network or directly to the CPU; (ii) a conventional distributed massive MIMO deployment requires a star topology, i.e., a separate cable between each APs and a CPU, which may be economically infeasible. Conversely, radio stripe installation complexity is unaffected by the number of antenna elements, thanks to its compute-and-forward architecture. Hence, cabling becomes much cheaper; (iii) maintenance costs are cut down as a radio stripe system offers increased robustness and resilience: highly distributed functionality offer limited overall impact on the network when few stripes being defected; (iv) low heat-dissipation makes cooling systems simpler and cheaper. While cellular APs are bulky, radio stripes enable invisible installation in existing construction elements as exemplified in Fig. below. Moreover, a radio stripe deployment may integrate for example temperature sensors, microphones/speakers, or vibration sensors, and provide additional features such as fire alarms, burglar alarms, earthquake warning, indoor positioning, and climate monitoring and control.

According to the Ericsson post:

One of the inventors and researchers behind the concept, Jan Hederén, Strategist at Ericsson 4G5G Development, says: 

"Although a large-scale installation of distributed MIMO can provide excellent performance, it can also become an impractical and costly "spaghetti-monster" of cables in case dedicated cables are used to connect the antenna elements.

To be easy to deploy, we need to connect and integrate the antenna elements inside a single cable. We call this solution the "radio stripe" which is an easy way to create a large scale distributed, serial, and integrated antenna system." Says, also inventors and researcher behind the concept."

This visionary concept is an extension of how to build and enhance the capability of current networks. The Radio Stripe systems offers, so to say, new colors and flavors in how we increase the performance of mobile networks.

The Radio Stripe vision is focused on improvements to the reach and quality of radio connectivity in the access part of the mobile network. It shares all other resources (transport, baseband, management, core) with current mobile solutions.

I am looking forward to reading a lot more about this kind of approach in the future and probably some deployment videos too.

Related post:

• Drones at Mobile World Congress 2019 and my upcoming webinar on 5G at #MWC19

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I am running a webinar this week looking at 5G @ MWC 2019 on behalf of Parallel Wireless (#PWTechTrain) . Along with antennas, I plan to talk about lot more things. Register here.

Some interesting April Fools' Day 2019 Technology Jokes

This year April Fools' Day wasn't as fun as the last one, even though it was on Monday. Many tech companies that make effort didn't make one this year. In fact Microsoft went even further and banned any public facing April Fools' pranks. Anyway, here are some of the jokes that I found interesting.

Parallel Wireless 7G Vision
This one was important for me as it features me (Yay!) and also enhanced my video editing skills. Grateful to CW (Cambridge Wireless) for being part of it too.

Parallel Wireless would today like to announces our 7G Vision (#7GVision) - https://t.co/Ffj63NX5F3 - Cambridge Wireless (@cambwireless) will form new Special Interest Group (SIG) to support the 7G Vision with @zahidtg joining the team too. pic.twitter.com/puz3cOoOGn

— Parallel Wireless (@Parallel_tw) April 1, 2019

Video is slightly long but funny hopefully



In short, the focus for the next few years will be do design a 7G logo that can explain the vision and connect with people. Did I mention 7GPPPPP?

"#7G Public Private Political Polling Partnership (7GPPPPP) with many different companies and organizations has also been formed to work on this vision."

Well played @Parallel_tw @cambwireless! ;)#AprilFools https://t.co/Lhxqk2Eifq

— Emanuel Kolta (@EmanuelKolta) April 1, 2019

Google Sssnakes on a map

Google temporarily added a version of the classic game Snakes into its Google Maps app for April Fools’ Day this year.

The company says that the game is rolling out now to iOS and Android users globally today, and that it’ll remain on the app for the rest of the week. It also launched a standalone site to play the game if you don’t have the app.

Jabra Ear bud(dy)

World’s first shared headphone - engineered for shared music moments. The website says:

The headphones come with an ultra-light headband that extends seamlessly to accommodate the perfect fit for every pair of buddies, so you’ll never have to enjoy another music moment alone. The Jabra Earbud(dy)™ comes with a unique Buddy mode that promises a shared music experience that is tailored to suit each person’s preferences. Fans of voice command will be thrilled to know that with just one touch, the Jabra Earbud(dy)™ can connect to dual voice assistant.


T-Mobile Phone BoothE

T-Mobile USA and their CEO John Legere never disappoints. They always come up with something interesting. Here is a video of the prank


From MacRumours:

T-Mobile is again fighting one of the so-called pain points of the wireless industry with the launch of the Phone BoothE, a completely sound-proof and high-tech phone booth that lets T-Mobile customers escape from noisy areas to make their phone calls. Inside the Phone BoothE you can charge your devices, connect to a smart screen called "Magenta Pages" to mirror your smartphone display, and adjust the lighting to take great selfies.

In regards to the name, T-Mobile is taking a shot at AT&T's misleading 5GE label: "The Phone BoothE is an evolution towards the new world of mobility. Like many in the tech and wireless industry today, we decided that by adding an "E" to the name, you would know it's a real technology evolution." 

Although this is an April Fools' Day joke, T-Mobile has actually built the Phone BoothE and deployed them in select locations around New York City, Seattle, and Washington, DC, where anyone will be able to use them. The company on Monday also revealed the T-Mobile Phone BoothE Mobile EditionE, which is more in line with a straightforward April Fools' Day hoax, as it's "literally a magenta cardboard box with a hole in it." 

While the actual site disappeared after April 1, the archived version can be seen here.

X-Ray vision Nokia 9 PureView

UPDATE: Getting ready for go-live! pic.twitter.com/ijsAXz8QhG

— Juho Sarvikas (@sarvikas) April 1, 2019

The Nokia 9 PureView has plenty of cameras on its back, but did you know that the black sensor isn’t a 3D ToF camera but rather an X-Ray sensor? Can be unlocked with the new Nokia X-Ray app in Play Store


"Digi-U" from Ericsson Digital

We announce a new innovation from our @EricssonDigital team - a Digi-ize yourself app called: "Digi-U". This app is available for download to your smart phone and within 10 minutes you will have transformed yourself into a mini-me hologram.

For more: #HappyAprilFoolsDay :-) pic.twitter.com/iCDiU1lHhj

— Ericsson Digital (@EricssonDigital) April 1, 2019

Parallel Wireless Adds AMPS (1G) Capabilities to Their Unified ALL G Architecture

From the press release:

Worlds First Fully Virtualized AMPS (vAMPS) to enable Modernization and Cost Savings

Parallel Wireless vAMPS is compatible with: Total Access Communications Systems (TACS) in the U.K.; Nordic Mobile Telephone (NMT) System in Scandinavia; C450 in Germany; and NTT System in Japan, among others, and will allow global operators to modernize their 1G infrastructure. The 1G vAMPS solution is also software upgradable to vD-AMPS, for operators who wish to follow that path.

Truphone foldable SIM (F-SIM) for Foldable Smartphones

From Truphone website:

F-SIM – the foldable SIM – designed especially for the new foldable smartphones and tablets demonstrated at this February’s MWC Barcelona, including Huawei’s Mate X and Samsung’s Galaxy Fold.

Widely tipped as the next generation in SIM technology, the foldable SIM works on minute hinges that allow it to fold smaller than any previous SIM form factor. Made specifically for foldable phones and other devices, Truphone’s latest innovation fulfils on its broader brand promise to engineer better connections between things, people and business—anywhere in the world.

The F-SIM comes in ‘steel grey’ and, for only £5 more, ‘hot pink’. Pricing structures vary depending on data, storage, roaming charges and device model.


Google Screen Cleaner in the Files app




Mother of All USB-C Hubs for Apple Macbook - HyperDrive Ultimate Ultimate Hub

The Mother of All USB-C Hubs for Apple Macbook - HyperDrive Ultimate Hub with built-in battery, speaker, 3.5" floppy disk drive, parallel, serial, PS/2, AT ports & 40 other ports from @Hyper - https://t.co/KpbZflRDcY #AprilFoolsDay #AprilFools2019 #AprilFools pic.twitter.com/xLIGXLcr8G

— 3G4G (@3g4gUK) April 2, 2019

Other funny April Fools jokes:

• Captain Marvel Universal Pager
• Polite Car Horn from Honda Canada
• Duolingo Push
• Shutterstock Announces Plans to Build World’s Largest Brick-and-Mortar Library
• Parody Apple Ad: "The Sound Gardener"
• Audible for Fish
• Logitech Hamsters
• Nissin/HyperX Limited Edition Cup Noodle Headphones
• Roku Press Paws Remote for Pets
• OnePlus Warp Car - Los Angeles to Las Vegas on a single 20 minute charge
• Google Tulip: Decoding the language of flowers
• Introducing Waymo Pet - a self-driving service for pets
• Nvidia R.O.N.: The world's first AI powered virtual gaming assistant.

One of the funniest jokes is Qualcomm's HandSolo that was released back in 1998. You may enjoy watching here.

Related posts:

• Some interesting April Fools' Day 2018 Technology Jokes
• Some interesting April Fools' Day 2017 Technology Jokes
• Some interesting April Fools' Day 2016 Technology Jokes
• Some interesting April Fools' Day 2015 Technology Jokes
• Some interesting April Fools' Day 2014 Technology Jokes

Update on UK's Emergency Services Network (ESN) from #BAPCO2019

I have discussed about the UK's Emergency Services Network (ESN) multiple times but I manged to hear about the progress first hand this week. Bryan Clark, ESN Programme Director, Home Office gave a keynote address at BAPCO on Day 2 and the title of his presentation was "2019: The year vision becomes reality"

British APCO or BAPCO Annual Conference and Exhibition 2019 was going to be a big launchpad for the ESN network. The ESN LinkedIn post said "Representatives from ESN and EE will be on hand to discuss coverage and ESN Assure. See an installation of the ESN Gateway solution within a police car, plus a live demonstration showing how ESN coverage can be extended from a vehicle into a building. We’ll also have a ‘Motorola Zone’ where you can watch demos of Kodiak and the ESN self-service portal – and a large touchscreen demo of the Samsung ESN Galaxy"

Bryan started by cracking a joke about people referring to 'ESN' as 'ES When' programme because it has been delayed multiple times. He said straight in the beginning that he going to talk about what the ESN programme is doing now and what comes next.

He started with this short video, embedded below but detailed info available on this LinkedIn post

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So here is a short summary of the talk:

• There are roughly 350,000 customers of this service
• There are 137 separate organizations that will take advantage of this new this new technology. 
• There are couple of vehicles in the display area (pic on the top and video below) and roughly 50,000 vehicles that need to have a kit
• Over 100 aircraft need to have an air network access that currently isn't there. 
• There are nearly 30 direct suppliers to the program and that doesn't include the whole supply chain through each of those suppliers.
• Looking at the coverage, there is a commitment to providing a signal along half a million (0.5 million) kilometers of roads in England, Scotland & Wales. It extends 12 nautical miles out to sea and 10,000 feet in the air right across England, Scotland & Wales.
• In London alone there are over 400 kilometres of tunnels that were actually almost finished cabling out.
• 300 masts are being built as part of the ESN programme to extend services into remote areas.
• EE has extended their network by adding 700 additional masts. 
• Thousands of special locations will need to have effective access to ESN network
• ESN is a large programme so it's hardly surprising that it's very late. It's Bryan's job over the past 10 months to work out how to get it back on track. 
• People are going through quite a detailed review of where ESN has got to in terms of next steps. 
• The programme now has a very clear and approved plan to complete the technical element of the work, most of it should be done by late summer next year.
• One of the first products, Assure, is a way of testing the effectiveness of the network in the field. 
• A demonstration of Push-To-Talk (PTT) on a 4G network will be demoed within 3 weeks.
• This is the first generation end-to-end solution
• Emergency services is critical national infrastructure so any new solution can only replace the legacy once we are absolutely confident that we've got an effective replacement
• Even though the technical piece is quite challenging, when you compare it to the business change that follows, the technical part looks pretty simple. 
• To ensure that everything works effectively operationally, plans are in place but more detailed plans are going to follow in the coming three to four months.
• Individual components are already being tested in the field
• Programme deployment should start by the end of 2019 in terms of having basically completed laying the core components and a clear plan will be in place for how to test in an operational context. 
• The ESN programme is not only responsible for the replacement solution but also for operations to date based on the Airwave contract with Motorola currently
• The number one priority is to provide critical voice communications of sufficient quality that people can rely on in the field and enable them to move away from the TETRA technology that served them so well. So we aren't going anywhere until we've got rock solid critical voice communications. It's our number one priority, simply because people's lives depend on it.

The following are various videos from the ESN demo area. The Gateway device (which is a mobile small cell) is supplied by Parallel Wireless*.



In case you missed BAPCO, Ken Rehbehn, a very well known Industry Analyst who works as a Principal Analyst at Critical Communications Insights and is also Montgomery County Firefighter/EMT, shared his observations and reflections from conference. Very grateful for his interview which is embedded below



Further Reading:

• Building a new critical communications network that keeps you safe - Bryan Clark, Programme Director, Emergency Services Network

Related posts:

• 3G4G Small Cells Blog: Meshing for BYOC (Bring Your Own Coverage)
• The 3G4G Blog: Quick tutorial on Mobile Network Sharing Options
• The 3G4G Blog: A practical use of MOCN in ESN
• The 3G4G Blog: EE's vision of Ultra-Reliable Emergency Network
• The 3G4G Blog: Update from 3GPP on LTE & 5G Mission Critical Communications

*Full Disclosure: I work for Parallel Wireless as a Senior Director in Strategic Marketing. This blog is maintained in my personal capacity and expresses my own views, not the views of my employer or anyone else. Anyone who knows me well would know this.

Multicast Operation on Demand (MooD) and Service Continuity for eMBMS

Many regular readers of this blog are aware that back in 2014 I wrote a post looking critically at LTE-Broadcast business case and suggested a few approaches to make it a success. Back in those days, 2014 was being billed as the year of LTE-Broadcast or eMBMS (see here and here for example). I was just cautioning people against jumping on the LTE-B bandwagon.

According to a recent GSA report 'LTE Broadcast (eMBMS) Market Update – March 2018':

• thirty-nine operators are known to have been investing in eMBMS demonstrations, trials, deployments or launches
• five operators have now deployed eMBMS or launched some sort of commercial service using eMBMS

Its good to see some operators now getting ready to deploy eMBMS for broadcast TV scenarios. eMBMS will also be used in Mission Critical Communications for the features described here.

In a recent news from the Australian operator Telstra:

Telstra is now streaming live sports content to a massive base of around 1.2 million devices each weekend and sports fans consume 37 million minutes of live content over our apps on any given weekend.

This increase brings new challenges to the way traffic on our mobile network is managed. Even though a large group of people might be streaming the same real-time content at the same time, we still need to ensure a high quality streaming experience for our customers.

This challenge makes our sporting apps a prime use case for LTE-Broadcast (LTE-B).

Earlier this year, we announced we would be turning on LTE-B functionality on the AFL Live Official app for Telstra customers with Samsung Galaxy S8 and Galaxy S9 devices. Following extensive testing, Telstra is the only operator in Australia – and one of the first in the world – to deploy LTE-B into its mobile network.

At a live demonstration in Sydney, over 100 Samsung Galaxy S8 and Galaxy S9 devices were on display showing simultaneous high definition content from the AFL Live Official app using LTE-B.

Its interesting to note here that the broadcast functionality (and probably intelligence) is built into the app.

According to another Telstra news item (emphasis mine):

The use of LTE-Broadcast technology changes the underlying efficiency of live video delivery as each cell can now support an unlimited number of users watching the same content with improved overall quality. To date though, LTE-B technology has required that a dedicated part of each cell’s capacity be set aside for broadcasting. This had made the LTE-B business case harder to prove in for lower streaming demand rates.

This has now changed as Telstra and our partners have enabled the world’s first implementation of the Multicast Operation on Demand (MooD) feature whereby cells in the network only need to configure for LTE-B when there are multiple users watching the same content.

This combined with the Service Continuity feature allows mobile users to move around the network seamlessly between cells configured for LTE-B and those which are not.

Earlier this year we announced our intention to enable LTE-Broadcast (LTE-B) across our entire mobile network in 2018. With MooD and service continuity we are one step closer to that goal as we head into another year of major growth in sporting content demand.

Supported by technology partners Ericsson and Qualcomm, Telstra has now delivered world first capability to ensure LTE-B can be delivered as efficiently as possible.

Service Continuity will allow devices to transition in and out of LTE-B coverage areas without interruption. For instance, you might be at a music festival streaming an event on your phone but need to leave the venue and make your way back home (where LTE-B is not in use). Service Continuity means you can continue to watch the stream and the transition will be seamless – even though you have the left the broadcast area.

Taking that a step further, MooD allows the network to determine how many LTE-B compatible devices in any given area are consuming the same content. MooD then intelligently activates or deactivates LTE-B, ensuring the mobile network is as efficient as possible in that location.

For example, if a die-hard football fan is streaming a match we will likely service that one user with unicast, as that is the most efficient way of delivering the content. However if more users in the same cell decide to watch the match, MooD makes the decision automatically as to whether it is more efficient to service those users by switching the stream to broadcasting instead of individual unicast streams.

Its good to see Ericsson & Qualcomm finally taking eMBMS to commercial deployment. Back in 2015, I added their videos from MWC that year. See post here.

I think the Telstra post already provides info on why MooD is needed but this picture from Qualcomm whitepaper above makes it much clearer. Back in 3G MBMS and early days or eMBMS, there used to be a feature called counting, MooD is effectively doing the same thing.

For Service Continuity, this paper 'Service Continuity for eMBMS in LTE/LTE-Advanced Network: Standard Analysis and Supplement' by Ngoc-Duy Nguyen and Christian Bonnet has interesting proposal on how it should be done. I cannot be sure if this is correct as per the latest specifications but its interesting to learn how this would be done when the user moves out of coverage area in Idle or connected mode.

Note that this Expway paper also refers to Service continuity as Session continuity.

Related posts:

• Telstra's LTE-B Push
• Reliance Jio getting ready for LTE-Broadcast (eMBMS) rollout

5G Synchronisation Requirements

5G will probably introduce tighter synchronization requirements than LTE. A recent presentation from Ericsson provides more details.

A nice presentation by Ericsson from #WSTS2018: Sync in 5G: What is really needed? - https://t.co/X3XIokELpe pic.twitter.com/6du5ezFfqE

— 3G4G (@3g4gUK) July 17, 2018

In frequencies below 6GHz (referred to as frequency range 1 or FR1 in standards), there is a probability to use both FDD and TDD bands, especially in case of re-farming of existing bands. In frequencies above 6GHz (referred to as frequency range 2 or FR2 in standards, even though FR2 starts from 24.25 GHz), it is expected that all bands would be TDD.

Interesting to see that the cell phase synchronization accuracy measured at BS antenna connectors is specified to be better than 3 μs in 3GPP TS 38 133. This translates into a network-wide requirements of +/-1.5 microseconds and is applicable to both FR1 and FR2, regardless of the cell size.

Frequency Error for NR specified in 3GPP TS 38.104 states that the base station (BS) shall be accurate to within the following accuracy range observed over 1 ms:
Wide Area BS → ±0.05 ppm
Medium Range BS → ±0.1 ppm
Local Area BS → ±0.1 ppm

The presentation specifies that based on request by some operators, studies in ITU-T on the feasibility of solutions targeting end-to-end time synchronization requirements on the order of +/-100 ns to +/-300 ns

There is also a challenge of how the sync information is transported within the network. The conclusion is that while the current LTE sync requirements would work in the short term, new solutions would be required in the longer term.

If this is an area of interest, you will also enjoy watching CW Heritage SIG talk by Prof. Andy Sutton, "The history of synchronisation in digital cellular networks". Its available here.

Terahertz and Beyond 100 GHz progress

There seems to be a good amount of research going on in higher frequencies to see how a lot more spectrum with a lot more bandwidth can be used in future radio communications. NTT recently released information about "Ultra high-speed IC capable of wireless transmission of 100 gigabits per second in a 300 GHz band". Before we discuss anything, lets look at what Terahertz means from this article.

Terahertz wave: Just as we use the phrase ‘kilo’ to mean 103 , so we use the term ‘giga’ to mean 109 and the term ‘tera’ to mean 1012 . “Hertz (Hz)” is a unit of a physical quantity called frequency. It indicates how many times alternating electric signals and electromagnetic waves change polarity (plus and minus) per second. That is, one terahertz (1 THz = 1,000 GHz) is the frequency of the electromagnetic wave changing the polarity by 1 × 1012 times per second. In general, a terahertz wave often indicates an electromagnetic wave of 0.3 THz to 3 THz.

While there are quite a few different numbers, this is the one that is most commonly being used. The following is the details of research NTT did.

In this research, we realized 100 Gbps wireless transmission with one wave (one carrier), so in the future, we can extend to multiple carriers by making use of the wide frequency band of 300 GHz band, and use spatial multiplexing technology such as MIMO and OAM. It is expected to be an ultra high-speed IC technology that enables high-capacity wireless transmission of 400 gigabits per second. This is about 400 times the current LTE and Wi-Fi, and 40 times 5G, the next-generation mobile communication technology. It is also expected to be a technology that opens up utilization of the unused terahertz wave frequency band in the communications field and non-communication fields.

Complete article and paper available here.

NTT Docomo has been doing 5G Field Testing of Ultra-high-speed, Long-distance Transmission Using mmWave in 28, 39 GHz in collaboration with @Huawei . Achieved high speed communication over distances exceeding 1 km with mmWave - https://t.co/a03SdqVhI7 pic.twitter.com/rlsqRAJ5YC

— 3G4G (@3g4gUK) July 2, 2018

Huawei has also been doing research in W (92 - 114.5 GHz) and D (130 - 174.5 GHz) bands.

A recent presentation by Debora Gentina, ETSI ISG mWT WI#8 Rapporteur at the UK Spectrum Policy Forum is embedded below.

This presentation can be downloaded from UK SPF site here. Another event on beyond 100GHz that took place last year has some interesting presentations too. Again, on UKSPF site here.

Ericsson has an interesting article in Technology Review, looking at beyond 100GHz from backhaul point of view. Its available here.

If 5G is going to start using the frequencies traditionally used by backhaul then backhaul will have to start looking at other options too.

Happy to listen to your thoughts and insights on this topic.

5G and IoT Security Update from ETSI Security Week 2018

ETSI Security Week 2018 (link) was held at ETSI's Headquarters in Sophia Antipolis, South of France last week. It covered wide variety of topics including 5G, IoT, Cybersecurity, Middlebox, Distributed Ledger Technology (DLT), etc. As 5G and IoT is of interest to the readers of this blog, I am providing links to the presentations so anyone interested can check them out at leisure.

Before we look at the presentations, what exactly was the point of looking at 5G Security? Here is an explanation from ETSI:

5G phase 1 specifications are now done, and the world is preparing for the arrival of 5G networks. A major design goal of 5G is a high degree of flexibility to better cater for specific needs of actors from outside the telecom sector (e.g. automotive industry, mission-critical organisations). During this workshop, we will review how well 5G networks can provide security for different trust models, security policies, and deployment scenarios – not least for ongoing threats in the IoT world. 5G provides higher flexibility than legacy networks by network slicing and virtualization of functions. The workshop aims to discuss how network slicing could help in fulfilling needs for different users of 5G networks.

5G will allow the use of different authentication methods. This raises many interesting questions. How are these authentication methods supported in devices via the new secure element defined in ETSI SCP, or vendor-specific concepts? How can mission-critical and low-cost IoT use cases coexist side-by-side on the same network?

The 5G promise of higher flexibility is also delivered via its Service-Based Architecture (SBA). SBA provides open 3rd party interfaces to support new business models which allow direct impact on network functions. Another consequence of SBA is a paradigm shift for inter-operator networks: modern APIs will replace legacy signaling protocols between networks. What are the relevant security measures to protect the SBA and all parties involved? What is the role of international carrier networks like IPX in 5G?

Event Objectives
The workshop intends to:

• Gather different actors involved in the development of 5G, not only telecom, and discuss together how all their views have shaped phase 1 of 5G, to understand how security requirements were met, and what challenges remain;
• Discuss slicing as a means to implement separate security policies and compartments for independent tenants on the same infrastructure;
• Give an update of what is happening in 3GPP 5G security;
• Explain to IoT players what 5G security can (and cannot) do for them, including risks and opportunities related to alternative access credentials;
• Understand stakeholders' (PMNs, carriers, GSMA, vendors) needs to make SBA both secure and successful. How can SBA tackle existing issues in interconnect networks like fraud, tracking, privacy breaches;
• Allow vendors to present interesting proposals for open security questions in 5G: secure credential store, firewalling SBA's RESTful APIs;
• Debate about hot topics such as: IoT security, Slicing security, Privacy, Secure storage and processing and Security of the interconnection network.

So here are the relevant presentations:

Session 1: Input to 5G: Views from Different Stakeholders
Session Chair: Bengt Sahlin, Ericsson

Hardening a Mission Critical Service Using 5G, Peter Haigh, NCSC

Security in the Automotive Electronics Area, Alexios Lekidis, SecurityMatters

Integrating the SIM (iUICC), Adrian Escott, QUALCOMM

Smart Secure Platform, Klaus Vedder, Giesecke & Devrient, ETSI SCP Chairman

Network Slicing, Anne-Marie Praden, Gemalto

Don't build on Sand: Validating the Security Requirements of NFV Infrastructure to Confidently Run Slices, Nicolas Thomas, Fortinet

5G Enhancements to Non-3GPP Access Security, Andreas Kunz, Lenovo

Security and Privacy of IoT in 5G, Marcus Wong, Huawei Technologies

ITU-T activities and Action Plan on 5G Security, Yang Xiaoya, ITU-T SG17

Wrap up: 5G Overview from 3GPP SA3 Perspective and What is There to Be Done for Phase 2, Sander Kievit, TNO


Session 2: Security in 5G Inter-Network Signalling
Session Chair: Stefan Schroeder, T-Systems

Presentation on SBA: Introduction of the Topic and Current Status in SA3, Stefan Schroeder, T-Systems

5G Inter-PLMN Security: The Trade-off Between Security and the Existing IPX Business Model, Ewout Pronk, KPN on behalf of GSMA Diameter End to End Security Subgroup

Secure Interworking Between Networks in 5G Service Based Architecture, Silke Holtmanns, Nokia Bell Labs

Security Best Practises using RESTful APIs, Sven Walther, CA Technologies

Identifying and Managing the Issues around 5G Interconnect Security, Stephen Buck, Evolved Intelligence

Zero Trust Security Posture in 5G Architecture, Galina Pildush, Palo Alto Networks (Missing)


Session 1 & 2 Workshop Wrap up: 5G Phase 1 Conclusions and Outlook Towards Phase 2 - Stefan Schroeder, T-Systems and Bengt Sahlin, Ericsson


Session 5: Benefits and Challenges of 5G and IoT From a Security Perspective
Session Chair: Arthur van der Wees, Arthur's Legal

Setting the Scene, Franck Boissière, European Commission

ENISA's View on Security Implications of IoT and 5G, Apostolos Malatras, ENISA

Smart City Aspects, Bram Reinders, Institute for Future of Living

The Network Operators Perspective on IoT Security, Ian Smith, GSMA


Related Links:

• Detecting false base stations in mobile networks - Ericsson Research Blog
• 5G Security Updates - March 2018 - 3G4G Blog
• Introduction to 3GPP Security in Mobile Cellular Networks - 3G4G Blog

Summary and Analysis of Ericsson Mobility Report 2018

Ericsson Mobility reports always make a fantastic reading. Its been a while since I wrote anything on this topic so I thought lets summarize it and also provide my personal analysis. Please feel free to disagree as this is just a blog post.

Before we start, the official site for the report is here. You can jump directly to the PDF here. Ericsson will also be holding a webinar on this topic on 19 June, you can register here.

A short summary of some of the highlights are in the table above but lets look at more in detail.

Mobile subscriptions 

• The total number of mobile subscriptions was around 7.9 billion in Q1 2018.
• There are now 5.5 billion mobile broadband subscriptions.
• Global subscription penetration in Q1 2018 was 104 percent.
• The number of LTE subscriptions increased by 210 million during the quarter to reach a total of 2.9 billion.
• Over the same period, GSM/EDGE-only subscriptions declined by 90 million. Other technologies declined by around 32 million.
• Subscriptions associated with smartphones now account for around 60 percent of all mobile phone subscriptions.

Many things to note above. There is still a big part of the world which is unconnected and most of the connectivity being talked about is population based coverage. While GSM/EDGE-only subscriptions are declining, many smartphone users are still camped on to GSM/EDGE for significant time.

While smartphones are growing, feature phones are not far behind. Surprisingly, Reliance Jio has become a leader of 4G feature phones.

My analysis from the developing world shows that many users are getting a GSM feature phone as a backup for when smartphone runs out of power.


Mobile subscriptions worldwide outlook

• 1 billion 5G subscriptions for enhanced mobile broadband by the end of 2023, accounting for 12 percent of all mobile subscriptions.
• LTE subscriptions continues to grow strongly and is forecast to reach 5.5 billion by the end of 2023
• In 2023, there will be 8.9 billion mobile subscriptions, 8.3 billion mobile broadband subscriptions and 6.1 billion unique mobile subscribers.
• The number of smartphone subscriptions is forecast to reach 7.2 billion in 2023.

The report describes "A 5G subscription is counted as such when associated with a device that supports NR as specified in 3GPP Release 15, connected to a 5G-enabled network." which is a good approach but does not talk about 5G availability. My old question (tweet below) on "How many 5G sites does an operator have to deploy so that they can say they have 5G?" is still waiting for an answer.

Question: How many 5G sites does an operator have to deploy so that they can say they have 5G?

— Zahid Ghadialy (@zahidtg) October 18, 2017

5G device outlook

• First 5G data-only devices are expected from the second half of 2018.
• The first 3GPP smartphones supporting 5G are expected in early 2019.
• From 2020, when third-generation chipsets will be introduced, large numbers of 5G devices are forecast.
• By 2023, 1 billion 5G devices for enhanced mobile broadband are expected to be connected worldwide.

Qualcomm has made a good progress (video) on this front and there are already test modems available for 5G. I wont be surprised with the launch. It would remain to be seen what will be the price point and demand for these 5G data-only devices. The Register put it quite bluntly about guinea pigs here. I am also worried about the misleading 5G claims (see here).


Voice over LTE (VoLTE) outlook

• At the end of 2017, VoLTE subscriptions exceeded 610 million.
• The number of VoLTE subscriptions is projected to reach 5.4 billion by the end of 2023.
• VoLTE technology will be the foundation for enabling 5G voice calls.
• New use cases in a 5G context are being explored, such as augmented reality (AR) and virtual reality (VR).

Back in 2011, I suggested the following (tweet below)

Soon = before 2015. Ideally, if its working then never, until forced - RT @Gabeuk: I suspect VoLTE adoption will pick-up briskly in 2013.

— Zahid Ghadialy (@zahidtg) July 13, 2011

Looks like things haven't changed significantly. There are still many low end devices that do not support VoLTE and many operators dont support VoLTE on BYOD. VoLTE has been much harder than everyone imagined it to be.


Mobile subscriptions worldwide by region

• Globally, mobile broadband subscriptions now make up 68 percent of all mobile subscriptions.
• 5G subscriptions will be available in all regions in 2023.
• In 2023, 48 percent of subscriptions in North America and 34 percent in North East Asia are expected to be for 5G.

I think that for some regions these predictions may be a bit optimistic. Many operators are struggling with finance and revenue, especially as the pricing going down due to intense competition. It would be interesting to see how these numbers hold up next year.

While China has been added to North-East Asia, it may be a useful exercise to separate it. Similarly Middle East should be separated from Africa as the speed of change is going to be significantly different.


Mobile data Traffic Growth and Outlook

• In Q1 2018, mobile data traffic grew around 54 percent year-on-year.
• The quarter-on-quarter growth was around 11 percent.
• In 2023, 20 percent of mobile data traffic will be carried by 5G networks.
• North America has the highest monthly usage of mobile data per smartphone at 7.2 gigabytes (GB), anticipated to increase to 49GB in 2023.
• Total mobile data traffic is expected to increase by nearly eight times by the end of 2023.
• In 2023, 95 percent of total mobile data traffic is expected to be generated by smartphones, increasing from 85 percent today.
• North East Asia has the largest share of mobile data traffic – set to reach 25EB per month in 2023.

This is one of the toughest areas of prediction as there are a large number of factors affecting this from pricing to devices and applications.

Quiz question: Do you remember which year did data traffic overtake voice traffic? Answer here (external link to avoid spoilers)


Mobile traffic by application category

• In 2023, video will account for around 73 percent of mobile data traffic.
• Traffic from social networking is also expected to rise – increasing by 31 percent annually over the next 6 years.
• The relative share of social networking traffic will decline over the same period, due to the stronger growth of video.
• Streaming videos in different resolutions can impact data traffic consumption to a high degree. Watching HD video (720p) rather than standard resolution video (480p) typically doubles the data traffic volume, while moving to full HD (1080p) doubles it yet again.
• Increased streaming of immersive video formats would also impact data traffic consumption.

It would have been interesting if games were a separate category. Not sure if it has been lumped with Video/Audio or in Other segments.


IoT connections outlook

• The number of cellular IoT connections is expected to reach 3.5 billion in 2023. This is almost double our last forecast, due to ongoing large-scale deployments in China.
• Of the 3.5 billion cellular IoT connections forecast for 2023, North East Asia is anticipated to account for 2.2 billion.
• New massive cellular IoT technologies, such as NB-IoT and Cat-M1, are taking off and driving growth in the number of cellular IoT connections.
• Mobile operators have commercially launched more than 60 cellular IoT networks worldwide using Cat-M1 and NB-IoT.

It is important to look at the following 2 definitions though.

Short-range IoT: Segment that largely consists of devices connected by unlicensed radio technologies, with a typical range of up to 100 meters, such as Wi-Fi, Bluetooth and Zigbee. This category also includes devices connected over fixed-line local area networks and powerline technologies

Wide-area IoT: Segment consisting of devices using cellular connections, as well as unlicensed low-power technologies, such as Sigfox and LoRa

The Wide-area IoT in the table above includes cellular IoT. If you are a regular reader of this blog, you will know that I think LoRa has a bright future and my belief is that this report ignores some of the reasons behind the popularity of LoRa and its growth story. 


Network coverage

• In 2023, more than 20 percent of the world’s population will be covered by 5G.
• 5G is expected to be deployed first in dense urban areas to support enhanced mobile broadband.
• Another early use case for 5G will be fixed wireless access.
• Today, 3GPP cellular networks cover around 95 percent of the world’s population.

A lot of work needs to be done in this area to improve coverage in rural and remote locations.

I will leave this post at this point. The report also contains details on Network Evolution, Network Performance, Smart Manufacturing, etc. You can read it from the report.