5G for Content Acquisition and Distribution

The Cambridge Wireless (CW) Content Production & Delivery group recently delivered a two part webinar series exploring ‘5G for content acquisition and distribution’ These online events introduced participants to the state of play with 5G for content distribution and production and the path to delivering the benefits 5G.

Aspirational discussion of benefits of 5G for content production and distribution needs to be turned into operational reality. 5G will enhance what is possible to be achieved with current mobile systems and the advantages to distribution and consumption are obvious through bigger pipes and enhanced agility to support ever evolving content and application platforms. The possibilities for content production and acquisition are also exiting but may be less obvious. 5G will allow service and capacity to be delivered where required through use of small cell and potentially highly localised private 5G networks, edge computing and support of a wide range of equipment and applications (not just those use cases directly involved in content acquisition).

The first session on 24 Nov 2020 in the series considers the role of 5G for content distribution and security. It covers the role of 5G for the creation of a more varied and vibrant ecosystem for content and the desire of some content creators for greater focus on security.

Henry Johnson, Director, Plum Consulting, '5G opportunities in the provision of content distribution' - 5G services promise to provide connectivity performance in terms of bandwidth and latency which have hitherto been possible only with fixed network connectivity. This session will look into the capabilities and potential limitations of 5G services once deployed and what that might mean for content delivery to consumers. [PPT presentation]

Malcolm Brew, University of Strathclyde, ‘5G-enabled remote broadcast’ - Malcolm will share some Strathclyde’s insights over the last 10 years in working with BBC and Ofcom on ‘Spectrum Sharing’ and how this has recently been lead to working in an IBC Accelerator Program ‘5G In Remote Production’ [PDF] 

For limited time, the recording is available here.

The 3G4G Blog: LTE / 5G Broadcast Evolution - https://t.co/nMM6VvxGbg via @5Gxcast #3G4G5G #IEEE5G #5GIEEE #eMBMS #LTEBroadcast #MissionCriticalComms pic.twitter.com/aSxdsFkX9A

— 3G4G (@3g4gUK) August 29, 2019

The following is the description from session 2, on 2nd Dec 2020:

Join the CW Content Production and Delivery Group’s aspirational discussion of benefits of 5G for content production and distribution needs to be turned into operational reality.

There is no doubt 5G will enhance what is possible to be achieved with current mobile systems and the advantages to distribution and consumption are obvious through bigger pipes and enhanced agility to support ever evolving content and application platforms.

The possibilities for content production and acquisition are also exciting, but may be less obvious. 5G will allow service and capacity to be delivered where required through use of small cell and potentially highly localised private 5G networks, edge computing and support of a wide range of equipment and applications (not just those use cases directly involved in content acquisition).

Ian Wagdin, Senior Technology Transfer Manager, BBC R&D, '5G in Content Production, work in standards and deployments' - A look at what’s here and what’s coming and how 5G may impact broadcast workflows. [PDF]

Paola Sunna, Technology and Innovation Department, EBU, '5G for Content Production' - EBU perspective on 5G for professional content production and challenges/ambitions in the Horizon 2020 project 5G-RECORDS. [PDF] 

For limited time, the recording is available here.

A nice talk looking at 5G and Broadcast - 'BBC, 5G and me' by Ed King, Principal Architect, BBC at @TheIET #5GUnleashed 2020 conference - https://t.co/RtTIxZnvN4#Free5GTraining #eMBMS #5Gbroadcast pic.twitter.com/j0d6r7Xqeq

— 5G Training (@5Gtraining) March 6, 2020

Other Recent News / Articles / Videos on 4G/5G Broadcast:

• SoftBank Corp. Showcases 5G-powered Entertainment and Advanced Technologies at Pop Culture Complex (link)
• 5G TODAY: BAVARIA’S BROADCAST TRIALS (link)
• Webinar: The role of broadcast and multicast in 5G-TOURS: High-quality video services distribution (link)
• Delivering Media with 5G Technology: FeMBMS, 5G-Xcast and beyond (link)
• 5G TODAY: 5G Broadcast trial using FeMBMS (link)
• 5G Today: On the Road to 5G Broadcast (link)

Related Posts:

• The 3G4G Blog: LTE / 5G Broadcast Evolution
• The 3G4G Blog: 5G Dynamic Spectrum Sharing (DSS)
• The 3G4G Blog: Multicast Operation on Demand (MooD) and Service Continuity for eMBMS 

Top Videos on 3G4G YouTube Channel

We made quite a few videos last year for our YouTube channel. In fact we crossed over 10K subscribers last year. Here are couple of playlists, one for the Top 5 videos of 2020 and other is Top 10 videos of all time. Hopefully you like them and subscribe to our channel

Top 5 3G4G videos from 2020

Top 10 3G4G videos from all time

 Let us know which ones are your favourite.

Related Posts:

• The 3G4G Blog: Top 10 Posts for 2020 and Top 5 Videos
• Connectivity Technology Blog: Top 5 Posts for 2020
• Operator Watch Blog: Top 5 Posts for 2020
• Telecoms Infrastructure Blog: Top 5 Posts for 2020 

Top 10 Posts for 2020 and Top 5 Videos

Here are the posts, from most popular to the tenth most popular, in descending order of popularity 

1. 5G Dynamic Spectrum Sharing (DSS), May 2020

2. EPS Fallback in 5G Standalone Deployments, Feb 2020

3. How MOCN RAN-Sharing Works, Jan 2020

4. Prof. Andy Sutton: Backhauling the 5G Experience, Jan 2020

5. Key Technology Aspects of 5G Security by Rohde & Schwarz, July 2020

6. Positioning Techniques for 5G NR in 3GPP Release-16, Oct 2020

7. 5G Private and Non-Public Network (NPN), March 2020

8. A Look into 5G Virtual/Open RAN - Part 1, March 2020

9. Interfacing HSS and UDM in 5GS with UDICOM (a.k.a NU1 / Nhss), Sep 2020

10. NTT Docomo's Vision on 5G Evolution and 6G, Jan 2020

There was another post, in the top 5 but I have listed it below. It was an announcement about the Free 5G Training site we launched early this year.

Bonus post*: Free 5G Training, Jan 2020

In addition to the above, we have a very popular and active YouTube channel, here are the top 5 videos that we posted in 2020. 

1. Advanced: Private Networks & 5G Non-Public Networks

2. Intermediate: Vehicle to Everything (V2X) Introduction

3. Beginners: UICC & SIM

4. Part 6: Standalone and Non-Standalone 5G - 5G for Absolute Beginners

5. Beginners: Industry 4.0 & 5G

Related Posts:

• Connectivity Technology Blog: Top 5 Posts for 2020
• Operator Watch Blog: Top 5 Posts for 2020
• Telecoms Infrastructure Blog: Top 5 Posts for 2020 
• The 3G4G Blog: Top 10 posts for 2019
• The 3G4G Blog: Top 10 posts for 2018
• The 3G4G Blog: Top 10 posts for 2017 and some other 3G4G info 

Challenges and Future Perspectives of Industrial 5G

Andreas Mueller, Head of communication and network technology at Bosch Corporate Research and Chair of 5G ACIA recently spoke at 'What Next for Wireless Infrastructure Summit' by TelecomTV about Industrial 5G. The following is paraphrased from his presentation 'Industrial 5G: Remaining challenges and future perspectives' which is embedded below: 

5G has the potential to become the central nervous system of the factory of the future, enabling unprecedented levels of flexibility, efficiency, productivity and also ease of use.  At the same time it's also a very special application domain so in many cases there are very demanding QoS requirements. 

Industrial applications have multi-faceted requirements where one case may require very low latencies and high reliabilities for instance, while for others we may need very high data rates (for example HD cameras). There is no single use case with a single set of requirements but many different use cases with very diverse requirements which also have to be supported in many cases at the very same time. 

As we need only a local network with local connectivity, this performance is required only in a very controlled environment; inside a factory, inside a plant. This allows for specific optimizations and makes certain things easier but we also always have brownfields deployments in many cases that means we have to live what we have in place today so that's typically wired communication in some cases it's wi-fi and similar wireless solutions and we have to be able to smoothly integrate a 5G network into this existing infrastructure

The developments towards Industrial 5G started about three years ago i would say and in the meantime it really has become a hot topic everybody is talking about industrial 5G. It has become a focused topic in standardization in 3GPP and some key capabilities already have been standardized which have been briefly outlined in the presentation. 

Good progress has also been made in the ecosystem development so we've established the 5G Alliance for Connected Industries and Automation two and a half years ago which serves as a global forum for bringing all relevant stakeholders together and for driving industrial 5G and we have 76 members today which includes major players from the telco industry but also from the industrial domain and also of course some universities and so on. We have seen the advent of non-public networks (NPN) so for the first time it will be possible for a manufacturers to deploy and operate such non-public networks inside a factory which are to some extent decoupled from the public networks.

If we look at the standardization timeline this is what you get. The first version of 5G release 15 of 3GPP was approved mid last year and it still had a very strong focus on consumer application and enhanced mobile broadband. If you buy 5G today, this is what you get then. Release-16 has for the first time had a very strong focus on industrial applications this has been approved in June this year and it includes features like ultra reliable low latency communication, non-public networks, time-sensitive communication. It means support for time-sensitive networking 5G and also native layer 2 transport so that we don't necessarily need internet protocol but we can directly transmit ethernet frames over a 5G network which again is very important especially for the industrial domain.

Last week’s TSG Plenary meetings have approved a firm Release-17 timeline. https://t.co/DoHTBQo5ZV pic.twitter.com/MSW8nnZgEA

— 3GPP Live (@3GPPLive) December 14, 2020

Release 17 is currently underway and it will come along with several enhancements of these features. It also has a stronger focus on positioning which is again very important in manufacturing because knowing where things are is a very valuable information and it will be in this new transmission mode called NR RedCap which is somewhere somewhere in between this high-end mobile broadband mode and also this low-end a massive machine type communication and this might be especially suitable for industrial sensors for example and then of course the journey will continue with Release 18 which is still being defined but with a high probability i would say it will more focus on massive iot applications that means tiny little sensors for example which have to be connected using very low energy and low costs and not just the natural next step.

5G NR-RedCap (New Radio Reduced Capability Device) is now the official name of NR-Light (or NR-Lite before that). Assuming this was also being discussed in 3GPP as NR-RedCom (New Radio Reduced Complexity Device) earlier. Can anyone confirm 🤔 pic.twitter.com/WZUaJSgQ8s

— 3G4G (@3g4gUK) December 20, 2020

So many things have been done already towards supporting these industrial applications but if you look at factories today there are only very few of them which already make use of 5g and that's because there are still some challenges to be overcome some of them are listed here first of all having the features in the standard is nice but they also have to be implemented in the chipsets and infrastructure components and that still say test takes some time especially if we consider that really 16 is the first release which really has many of the features that make a difference to the industrial domain

Here is a list of the features that can be prioritised for future 5G releases or even for 6G. As Release-17 has just been delayed slightly, quite possible that some of the features expected in 5G may get pushed on to Beyond 5G and even 6G.

Here is the embedded talk

An interview by Dr. Andreas Müller regarding Bosch 5G activities is available here (in German)

Related Posts:

• The 3G4G Blog: 5G and Industry 4.0
• The 3G4G Blog: What is Industrial IoT (IIoT) and how is it different from IoT?
• Free 6G Training: 6G Localization and Sensing – Technologies, Opportunities and Challenges
• The 3G4G Blog - Ultra Reliability: 5x9s (99.999%) in 3GPP Release-15 vs 6x9s (99.9999%) in 3GPP Release-16
• The 3G4G Blog: 5G Private and Non-Public Network (NPN)
• The 3G4G Blog: Real-life 5G Use Cases for Verticals from China
• The 3G4G Blog: Positioning Techniques for 5G NR in 3GPP Release-16 
• 3G4G: Introduction to NR-Light a.k.a. NR-Lite 

Conditional Handover (Rel. 16) Explained

Although a couple of SON mobility robustness features have been introduced in LTE radio networks it is still a common problem in some network areas that a high number of handover failures leads to higher drop rates and large numbers of RRC Re-Establishments.

Often these problems occur due to quickly changing radio conditions in the handover preparation phase or after handover execution attempt. 

SON algorithms cannot cope with these dynamic changes of the environment, but improvement is possible if the UE itself is enabled to constantly monitor the radio quality during the handover procedure and finally select the best possible target cell from a list of candidate neighbors. This new feature defined in 3GPP Release 16 for both, NG RAN (5G SA NR) as well as E-UTRAN (LTE), is called "Conditional Handover". The figure below illustrates how it works.

(click on the picture to enlarge)

Step 1 is the RRC Measurement Report indicating that handover to a neighbor cell is required. However, this message contains a list of candidate neighbor cells.

In the figure it is assumed that each of these candidate cells is controlled by a different gNB. Hence, 3 XnAP Handover Preparation procedures are performed and each potential target gNB allocates radio resources for the UE and provides a handover command (NR RRC Reconfiguration message) that is sent back to the source gNB (step 2).

In step 3 the source gNB builds the conditional handover command, which is a NR RRC Reconfiguration message that contains a list of conditional reconfiguration options plus additional RRC measurement configurations that enable the UE to find out which of the possible target cells is the best fit. 

In step 4 the UE makes its handover decision and moves to the cell controlled by target gNB 1.

Here it sends in step 5 the NR RRC Reconfiguration Complete message. 

The target gNB 1 detects the handover completion based on the reception of the NR RRC Reconfiguration Complete message, performs NGAP Path Switch procedure (not shown in figure) and triggers the release of the UE context in source gNB on behalf of sending the XnAP UE Context Release message (step 6).

With this information the source gNB also detects the successful handover completion and orders in step 7 the release of the radio resources provided by target gNB 2 and 3 to which it sends the new XnAP Conditional Handover Cancel message.

As mentioned before the conditional handover is also possible for LTE radio connections. In this case X2AP is used instead of XnAP and LTE RRC instead of NR RRC.

The conditional handover can be performed for all kind of intra-eNB/gNB handover and X2/Xn handover. However, S1/N2 (NG-C) conditional handover is not allowed.

Huawei's Power Digitalization 2025 Summit

Back in October, Huawei held Better World Summit 2020 (a.k.a. "Win-Win Future" Global Online Summit). The theme of this online summit was "Power Digitalization 2025”. Experts and operators shared their ideas, vision and challenges. The following summary was shared by Huawei:

Today, how should global operators respond to opportunities and challenges brought by changes in the digital world, under the rapid development of digital technology and digital economy.

“Energy, as the foundation of the digital world, has become a key part and an important point of competitiveness in the digital economy.” Zhou Taoyuan, President of Digital Power Product Line, Huawei, pointed out that “The entire industry needs to attach greater importance to energy”

With the rapid development of emerging technologies such as 5G, cloud, AI, big data, and the IoT, a digital transformation has kicked off, opening the digital age where things are sensing, connected, and intelligent, "ubiquitous Connected, omnipresent intelligence" is becoming a reality. This has thrown the development of 5G and big data centers into the spotlight. But at the same time, the large-scale and rapid construction of 5G and data centers have brought huge challenges to energy infrastructure, such as increasing energy consumption, long construction periods, and high operation and maintenance costs.

“Pay-as-you-go model is becoming more popular in many countries, as data center owners are looking to a decrease their investment and turn their Capex into Opex. And that goes also for a number of other services as part of running and maintaining data center.” Lilia Severina，Global Major Accounts Director of Uptime Institute，talked about the insights into data center trends at the meeting. “Existing site energy facility cannot meet the power demands of 5G sites. There is a pressing need for reform and innovation in this area.Digitization，intelligent and integrated 5G power system enable faster, more affordable, and simpler 5G network deployment.” Liu Baochang, Deputy Director of Information Energy Department, China Mobile Group Design Institute Co., Ltd, expressed his opinion on the development trend and insights of site power in the 5G era.

Violaine Petit, Sales and Marketing VP of CRT Informatique, shared an interesting case about building data centers of CRT in a castle.“CRT did not just want to build something regular. We wanted to be different. We also wanted to invest in a meaningful project. Based on our business development and rejuvenating the castle, CRT successfully deployed two data centers in the castle to meet the dynamic digital development requirements of government and enterprise users. It can be said that the castle data center not only expands CRT's business boundary, but also can protects the country's cultural heritage, can be said to be two birds with one stone.”

Today, people lead a convenient life because of development of science and technology, while they also worry about the environment. How do we transit towards a net-zero carbon economy? Alberto Carrillo Pineda, Director of Science Based Targets, CDP, has his own view. “This includes changes in policies, technologies, economic structures and patterns of production and consumption, but the most important thing is that we change the way we live today. One of the changes is energy transition. Transitioning from fossil-based to clean and renewable energy and phasing out CO2 emissions in other parts of our economy.”

Zhou Taoyuan said, “Huawei integrates traditional power technologies and digital technologies to achieve power digitalization. In this way, we can use ‘Bit to manage Watt’, and provide simple, green, smart, and reliable digital power solutions to solve challenges faced by traditional power industry. ”

Fang Liangzhou, the Chief Marketing Officer of Huawei Digital Power Product Line, Huawei, said“Huawei uses a target network architecture to guide the planning, construction, O&M, and operation of digital power infrastructure, driving the rapid development of the digital economy. Concerning site power, Huawei proposes implementing 5G without increasing site power-related OPEX, and aims to reduce costs from three aspects as well as tapping into new sources. As for data centers, Huawei proposes a simple, green, smart, and reliable next-generation data center facility that uses the "four reconstructions" initiative to tackle issues such as long data center construction period, high energy consumption, and challenging O&M.”

In the future, Huawei will keep cooperating with global operators to face the challenges and seize the opportunities brought by the digital world. Huawei aims to inject green power into operators and help them grow business sustainably in the future. 

#Huawei’s #BWS Power Digitalization 2025 is streaming live now. Join us to learn more about “Leading Power Digitalization for a Smart and Sustainable World”: https://t.co/3TZUKlh2M1 #BWS #Huawei
https://t.co/bUFPRCnwM3

— Huawei Carrier Business (@HuaweiCarrier) October 30, 2020

Surprisingly the only video I could find is on Periscope, embedded in the tweet above. You can jump on to the relevant sessions using the timestamps as follows

0:01:20 1. Opening Speech - Zhou Taoyuan, President of Digital Power Product Line, Huawei

@acarrillopineda : we need to transition to a net-zero carbon economy #5GBetterWorld #tmt #telecom #telecoms #5G pic.twitter.com/0WJWxIvCa8

— Roberto Kompany (@RobertoKompany) October 30, 2020

0:07:14 2. Building a Net-zero Emissions Economy - Alberto Carrillo Pineda, Director of Science Based Targets, CDP

Intelligent means are required to reduce power consumption in 5G era, says Liu Baochang from China Mobile. #5GBetterWorld #tmt #telecom #telecoms #5G pic.twitter.com/qasGS9knXx

— Roberto Kompany (@RobertoKompany) October 30, 2020

0:17:18 3. Trend and Insight of Site Power Facility in 5G era - Liu Baochang, Deputy Director of Information Energy Department, China Mobile Group Design Institute Co., Ltd

0:31:30 4. Perspective and Practice of Lithium Battery Application - José Pedro Nascimento, Network Director, Altice Portugal

4 planned steps to reduce mobile site power consumption and increase efficiency says Li Yao Deputy Director of NOC, China Mobile Pakistan#5GBetterWorld #tmt #telecom #telecoms #5G #5gnetworks pic.twitter.com/pFx6YP8Xfw

— Roberto Kompany (@RobertoKompany) October 30, 2020

0:40:10 5. Network Energy-Efficient Operation in EM Market - Li Yao, Deputy Director of NOC, China Mobile Pakistan

Data center outage causes by Lilia Severina @UptimeInstitute #5GBetterWorld #tmt #telecom #telecoms #5G pic.twitter.com/V1Djpee82D

— Roberto Kompany (@RobertoKompany) October 30, 2020

0:51:40 6. Trend and Insight of Data Center Facility - Lilia Severina, Global Major Accounts Director of Uptime Institute

1:10:30 7. Prefabricated Modular Data Center Case Sharing - Operator customers

1:16:20 8. Partnering To Power The Digital Datacenter - Violaine Petit, Sales and Marketing VP of CRT Informatique

Traditional data centers cannot meet demands in cloud era says Dr. Fang Liangzhou CMO of Digital Power Product Line, Huawei. #5GBetterWorld #tmt #telecom #telecoms #5G pic.twitter.com/kp3tv6GIVD

— Roberto Kompany (@RobertoKompany) October 30, 2020

1:25:10 9. New Era, New Power. PowerX 2025 Target Network - Dr. Fang Liangzhou, CMO of Digital Power Product Line, Huawei

Let me know what you think.

Nokia Lectures in Collaboration with Bangalore University

Nokia recently delivered some lectures virtually to Bangalore University students. The talks covered a variety of talks from LTE to 5G, Security & IMS. The playlist from Nokia is embedded below. The video contains following topics:

Part 1: 5G - General Introduction and IoT Specific Features
Part 2: 5G Overview
Part 3: Network Security Practices and Principles
Part 4: LTE Network Architecture - Interface and Protocols
Part 5: IMS - IP Multimedia Subsystem

Related Posts:

• The 3G4G Blog: 5G Evolution with Matthew Baker, Nokia
• 3G4G: Ultra Reliable Low Latency Communication for 5G New Radio
• Telecoms Infrastructure Blog: Nokia's 5G Small Cells in Limelight
• Telecoms Infrastructure Blog: Nokia's AirScale indoor Radio (ASiR) Small Cells
• Telecoms Infrastructure Blog: LuxTurrim5G smart light pole concept
• Connectivity Technology Blog: Verizon and Nokia Put Small Cell in the Air at #OCR2019
• Connectivity Technology Blog: Paris Metro is now 100% covered with LTE
• Connectivity Technology Blog: Air-to-Ground (A2G) Network for Emergency Communications
• The 3G4G Blog: 5G Dynamic Spectrum Sharing (DSS)
• 3G4G: Introduction to NR-Light a.k.a. NR-Lite

Three New Standards to Accelerate 5G Wireless Wireline Convergence (WWC)

It's been just over a year since I wrote a detailed post on what I called '5G and Fixed-Mobile Convergence (FMC)'. The technical term being used in the industry for this feature is Wireless Wireline Convergence (WWC). 

BBF (@Broadband_Forum) has published 3 new standards to accelerate global 5G adoption - https://t.co/ufoHRfK3BE - Wireless Wireline Convergence (#WWC) allows Wi-Fi and other wireline technologies to be part of 5G#Free5Gtraining #5G #5GNetworks #5GTechnology #FMC #5GConvergence pic.twitter.com/OcCyLYix2b

— 5G Training (@5Gtraining) November 26, 2020

Broadband Forum, the communications industry’s leading open standards development organization focused on accelerating broadband innovation, standards, and ecosystem development has just announced the publication of three new standards to accelerate global 5G adoption. The press release said:

Building on the Forum’s mission to drive a future consolidated approach to 5G, the standards will reduce development time, as well as capex and opex, from the traditional disparate fixed broadband and 5G networks. Ultimately, they will deliver a common and managed broadband experience to the end-user whatever the final connectivity technology.

There are three major sets of technical specifications that have been finalized, including 5G Wireless Wireline Convergence Architecture (TR-470), Access Gateway Function (AGF) Functional Requirements (TR-456) and Device Data Model (TR-181). Together, these documents provide functions and interfaces for Fixed Mobile Convergence (FMC), the AGF, and customer premises equipment (CPE) such as 5G-enabled routers.

TR-470 – produced in conjunction with 3GPP – describes the 5G FMC architecture, providing a high-level guide for network architects and planners and enabling fixed and mobile functions to coexist over a shared infrastructure. This will facilitate multi-access connectivity and give consumers a seamless, access-independent service experience.

For operators, the network functions required to operate their infrastructure will be streamlined and common technology, on-boarding, training, services and subscriber management between fixed and mobile divisions can be achieved. Furthermore, additional revenue streams will be created, with FMC extending the geographical reach of 5G core networks and the service offering of fixed networks.

TR-456 describes the functional requirements of the AGF. The AGF resides between fixed access networks and the 5G core network to support 5G and wireline Residential Gateways, creating a truly converged deployment. Alongside this, Broadband Forum’s Device: 2 data model (TR-181 Issue 2 Amendment 14), which is used by User Services Platform (USP), has been extended to address 5G Residential Gateways. The Device: 2 data model applies to all types of TR-069 or USP-enabled devices, including end devices, Residential Gateways, and other network infrastructure devices

In addition, the Functional Requirements for Broadband Residential Gateway Devices (TR-124) specification is expected to be finalized in Q4 2020. Moving from the network into the home, TR-124 has been extended to add requirements related to the 5G Residential Gateway extending the 5G control plane to the premises to open up new service opportunities with real time fulfillment.

In the video below, David Allan, Work Area Director for Wireless-Wireline Convergence at Broadband Forum and Christele Bouchat, Innovation Group Director at Broadband Forum discuss what is coming up in the next phase of 5G work and what opportunities this has opened up for the industry

WWC has a great potential to allow wireline and trusted/untrusted Wi-Fi to work with 5G so I am hopeful that operators will adopt this sooner, rather than later.

Follow the links below to learn more about this feature.

Related Posts:

• Connectivity Technology Blog: 5G Wireline Access Architecture
• The 3G4G Blog: 5G and Fixed-Mobile Convergence (FMC)
• The 3G4G Blog: Introduction to 5G ATSSS - Access Traffic Steering, Switching and Splitting
• The 3G4G Blog: Exploring Network Convergence of Mobile, Broadband and Wi-Fi
• Operator Watch Blog: BT's Converged Core to Launch in 2023
• Operator Watch Blog: Jio Makes Another Set of Extremely Bold Announcements 

Radio Design Webinar: Optimising Your 700 MHz Deployments

 

Radio Design, the award-winning market leader in the provision of wireless infrastructure sharing solutions and RF filter systems, hosted a webinar last week focused on the deployment of the 700 MHz frequency band. This new 700 MHz spectrum is in great demand across the world, mainly due to its long anticipated use as low band 5G spectrum. The webinar explores the potential of this band, as well as how to prepare for potential challenges when deploying.

For people who are familiar with our trainings, we divide the spectrum into three layers, the coverage layer, the capacity layer and the high-throughput layer. 700 MHz is the most popular coverage layer spectrum worldwide.

The slide above from the webinar talks of the recent Austrian 5G Spectrum auction that we blogged about. See tweet below for details

Operator Watch Blog: Austria Gets New 5G Spectrum - https://t.co/jN3sdIeci8 featuring tweets from @JimStLeger @tefficient #3G4G5G #OperatorWatch #Spectrum #4G #5G #Austria #Europe #RTR #H3A #Drei #TMobile #TMA #A1 pic.twitter.com/FAPAZsIGnl

— 3G4G (@3g4gUK) October 3, 2020

In the webinar, slides and video embedded below, Radio Design’s founder – Eric Hawthorn – kicks things off by analysing the benefits of deploying the 700 MHz band in the real world, before passing over to Global Engineering Director – Steve Shaw – who explores some of the technical problems which can arise, as well as some of the solutions. Last but not least, COO and co-owner of Keima – Iris Barcia – provides her insight into the benefits of deploying the 700 MHz band.

Radio Design Webinar: Optimising Your 700 MHz Deployments from 3G4G

Related Posts:

• Operator Watch Blog: Hungary Allocates 5G Spectrum in 700 MHz, 2.1 GHz and 3.6 GHz
• Operator Watch Blog: Austria Gets New 5G Spectrum
• Operator Watch Blog: Finland now has Ideal 5G Spectrum Allocation
• Operator Watch Blog: Italy's 5G Spectrum Auction Controversy
• Operator Watch Blog: Bhutan improving 2G, 3G & 4G coverage while preparing for arrival of 5G in 2022
• Operator Watch Blog: Malaysia Decides on Innovative Approach for 5G Spectrum
• The 3G4G Blog: Automated 4G / 5G HetNet Design
• The 3G4G Blog: 700 MHz Spectrum - Google: Loser or Winner? 

Business Role Models for Network Slicing and iRAT Mobility for Cellular Internet of Things (CIoT) in Release 16

 3GPP Release 16 describes business role models for network slicing and in TR 21.916 I found the figures below that I have pimped a little bit to illustrate an asset tracking use case for goods transported with a truck from Factory A to Factory B. 

Factory B is equipped with a 5G Non-Public Network (NPN) that broadcasts an NPN-ID or - if the network infrastructure is deployed by an operator - a Cell Access Group ID (CAG ID).

I would like to assume that in case of the scenario shown in 3GPP Figure 2-2 the asset tracking CIoT devices are able to access any necessary PLMN, Network Slice and NPN. This can be achieved e.g. by using an eSIM. 

So while the truck is at the location of Factory A the asset tracking "things" will connect to the private slice of Factory A provided by the operator of PLMN 1. Factory A is a tenant of this operator. This means: Factory A rented a virtual part of PLMN1 for private use and technically this rented virtual network part is realized by a NW slice. 

When the truck leaves Factory A and drives on the road (maybe a long distance) to Factory B the asset tracking data must be transmitted over public mobile network infrastructure. Depending on rural coverage this service can be offered by PLMN 2 (as in case of 3GPP figure 2-2) or by PLMN 1 (as in case of 3GPP figure 2-3).

In case of 3GPP figure 2-4 the operator of PLMN 1 is even able to provide the private slice along the road, which allows Factory A to stretch the coverage of their virtual private network (slice) over a very long distance.

Looking further into the Cellular IoT enhancements defined by 3GPP in Release 16 it turns out that actually there is no need for a nation-wide 5G coverage to realize at least the role models shown in the 3GPP figures 2-2 and 2-3.

Because Release 16 also defines co-existence and inter-RAT mobility between 5G CIoT traffic and 4G NB-IoT the operators of PLMN 1 and PLMN 2 may offer NB-IoT coverage along the road while the factories are covered with 5G NR frequency cells - as shown in my second figure below.  

It illustrates the great improved flexibility that Release 16 standards are offering for customized business solutions and monitoring the service quality is not a trivial task under these circumstances.  

Related Posts:

• The 3G4G Blog: 5G Private and Non-Public Network (NPN)
• The 3G4G Blog: Network Slicing Tutorials and Other Resources