Reliance Jio to sign $1.5 billion 5G network equipment deal with Nokia (“Home grown 5G” never happened)

Whatever happened to Jio’s claim of “home grown 5G“?  Answer: It was a big bold faced lie!  Almost 3 years ago, Jio Chairman Mukesh Ambani said his company had developed its own 5G solution “from scratch.” He said at the time, “Jio plans to launch “a world-class 5G service in India…using 100% home grown technologies and solutions,” he said in a statement at the Reliance Industries annual shareholders meeting.  “Once Jio’s 5G solution is proven at India-scale, Jio Platforms would be well-positioned to be an exporter of 5G solutions to other telecom operators globally, as a complete managed service,” he added.

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Fast forward to today.  Jio, India’s largest telecoms operator, is set to sign a contract  at Nokia’s Headquarters in Helsinki, Finland, according to sources speaking to the Economic Times 

The purchase will be financed by several global banks, including HSBC, Citigroup, and JP Morgan, whose combined loans will total around $4 billion. Finnish state-owned export credit agency Finnvera is set to issue guarantees to the lenders. Representatives from the banks are likely to be present at the signing, as well as Senior Executives from Reliance Group. 

At the time, financial details of the deals were not disclosed; however, media reports have since suggested that the deal with Ericsson was worth $2.1 billion.  Now, this deal with Nokia will see the total 5G investment reach roughly $3.6 billion. 

Earlier this year, Jio’s president Mathew Oommen said the company aimed to become “the largest 5G SA (standalone) only network operator in the world in the second half of 2023”, with the company targeting nationwide coverage by the end of the year.  

In October 2022, Jio signed 5G equipment contracts with both Nokia and Ericsson.  

In related news, earlier this week, Reliance Industries announced the launch of a budget 4G phone, (costing $12), aiming to convert the 250 million 2G users in India to 4G. The company says its goal is to pass the benefits of the internet-capable mobile technology to every Indian.

References:

https://economictimes.indiatimes.com/industry/telecom/telecom-news/jio-likely-to-sign-5g-gear-deal-with-nokia-for-1-7-billion/articleshow/101527984.cms

https://totaltele.com/indias-jio-to-sign-1-5-billion-5g-equipment-deal-with-nokia/

Reliance Jio’s “Home Grown” 5G? Ericsson and Nokia in multi-year deals with Jio to build a mega 5G network

Reliance Jio claim: Complete 5G solution from scratch with 100% home grown technologies

 

Do ITU Radio Regulations Matter? China allocates 6 GHz spectrum for 5G and 6G services prior to WRC 23; CTIA objects!

China’s regulators allocated spectrum in the 6 GHz frequency band for 5G and 6G services, asserting it was the first country to reserve the resource expected by the mobile industry to enable future connectivity. In a translated statement, the country’s Ministry of Industry and Information Technology (MIIT) highlighted the band was the only one with sufficiently-large bandwidth in the mid-range frequency band.

In a blog published on the opening day of MWC 2023 Shanghai, GSMA head of spectrum Luciana Camargos highlighted China had identified the upper part of the band for International Mobile Telecommunications (IMT) systems:

“China’s efforts towards the 6GHz band don’t come as a surprise,” Camargos wrote, adding. “Conducive spectrum policies for the mid-bands, especially the 2.6GHz and 3.5GHz, have helped China to deploy the world’s largest 5G networks with over 2.7 million 5G base stations by the end of April 2023 and to be on track to become the first country to reach 1 billion 5G connections in 2025.”

Note:  The GSMA has been pushing the case for the use of 6 GHz by the mobile industry ahead of the ITU World Radiocommunication Conference 2023 (IRC 23) in Dubai, UAE in November 2023.  WRC 19 did not authorize use of the 6 GHz band for IMT and so it is not in ITU-R M.1036 revision 6Frequency arrangements for implementation of the terrestrial component of International Mobile Telecommunications in the bands identified for IMT in the Radio Regulations” which specifies all terrestrial IMT frequencies.

During the Ajit Pai administration, the FCC allocated virtually the entire 6 GHz band – 1,200 megahertz stretching across 5.925 GHz–7.125 GHz – for unlicensed uses, primarily Wi-Fi rather than IMT which uses licensed spectrum.

–>Please refer to References below.

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The CTIA was alarmed by China’s decision and posted this on Twitter:

BREAKING NEWS: China announces plans to free up far more #5G spectrum than the United States. Congress must restore @FCC auction authority and identify new spectrum to secure our leadership of the industries and innovations of the future.

“We risk having Chinese networks that are materially better at enabling the industries of the future,” wrote Doug Brake, a policy official at CTIA, the U.S. wireless industry’s main trade association. “If a mobile video platform like TikTok is a national security threat, why should we surrender advantage in a technology like 5G that enables transformation throughout the economy?”

“We need a breakthrough on spectrum policy that prioritizes full-power, licensed, midband spectrum for 5G to secure our industries of the future in the face of increasingly capable Chinese networks and the market dominance of Chinese vendors. This requires a coordinated effort, starting with Congress establishing an auction pipeline, NTIA identifying at least 1500 megahertz of licensed midband spectrum for 5G as part of the National Spectrum Strategy,” Brake wrote.

The NTIA plans to release a U.S. spectrum strategy this November.

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A number of countries in North and South America, and in Asia, have already allocated the 6GHz band for unlicensed uses, according to Dean Bubley of Disruptive Analysis.

Others countries haven’t yet decided what to do with the band. For example, officials in the UK just this week opened an investigation into the possibility of sharing the 6GHz band between Wi-Fi and 5G users.

“Rather than choosing between the two, we believe an alternative approach is possible. We are exploring options that would enable the use of both Wi-Fi and mobile in the band. We are calling this ‘hybrid sharing,'” wrote regulator Ofcom in a post.

According to Disruptive Wireless analyst Bubley, Ofcom’s proposal isn’t that simple. “This would need new technical mechanisms for networks, devices and databases / sensing, and how to manage and enforce any prioritisations,” he wrote in a new LinkedIn post. “There are various options for automation, dynamic vs. fixed sharing and so on. There may be constraints on power or ‘polite’ protocols. Ideally these would be internationally standardized – perhaps just in Europe, but more broad adoption would obviously be preferable.”

Meanwhile, others continue to urge global regulators to allocate the 6GHz band for 5G. For example, the GSMA – the world’s biggest 5G trade association – recently reiterated its position that 6GHz will be necessary for 5G networks to keep pace with demand.

According to Bubley, the debate will likely come to a head later this year at the ITU-R’s 2023 World Radiocommunications Conference (WRC-23) in Dubai, United Arab Emirates (UAE). That’s where global telecom regulators  work to harmonize their plans in order to score global economies of scale among equipment suppliers. The result is a set of Radio Regulations which are approved frequencies to be used for IMT and other wireless services.

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References:

China claims world-first 6GHz allocation for 5G, 6G

https://www.lightreading.com/broadband/american-5g-proponents-sweat-over-chinas-new-6ghz-push/d/d-id/785577?

https://www.linkedin.com/posts/deanbubley_6ghz-wrc23-cept6gworkshop-activity-7082715053635817472-vFwh/

6 GHz band proposed for WiFi/5G in Asia Pacific region, but it’s not in ITU-R M.1036

CTIA commissioned study: U.S. running out of licensed spectrum; 5G FWA to be impacted first by network overloads

GMSA vs ITU-R, FCC & U.S. Tech Companies on use of 6GHz band: Licensed 5G or Unlicensed WiFi?

Broadcom, Cisco and Facebook Launch TIP Group for open source software on 6 GHz Wi-Fi

FCC to open up 6 GHz band for unlicensed use – boon for WiFi 6 (IEEE 802.11ax)

FCC to vote April 23rd to open up 1200 MHz of 6 GHz spectrum for WiFi

U.S. Launches National Spectrum Strategy and Industry Reacts

5G SA networks (real 5G) remain conspicuous by their absence

According to a May 2023 report from the Global mobile Suppliers Association (GSA), just 35 network operators in 24 countries and territories “are now understood to have launched or deployed public 5G SA networks.” That’s out of approximately 240 service providers which have now launched commercial 5G services, as per the recent Ericsson Mobility Report.

Dell’Oro’s Dave Bolan said, “Currently we count 43 live 5G SA networks for eMMB [enhanced mobile broadband]. For 2023, four [mobile network operators] have launched 5G SA networks,” he added.  It should be noted that Dell’Oro doesn’t factor in fixed wireless access (FWA) or private 5G networks in its SA totals.

In Europe, Vodafone UK and Telefónica Spain join what remains a small set of network operators that have launched 5G SA, including Orange Spain and Vodafone Germany. Spain should provide an interesting study of what happens when two rival operators launch 5G SA service.

There are some glimmers of hope that 5G SA launches will accelerate soon.  GSA (aka GSMA) has identified at least 1,063 announced devices with declared support for standalone 5G in sub-6GHz bands, 864 of which are commercially available. Furthermore, it said 116 operators in 53 countries and territories are now investing in 5G SA, including those that have actually deployed a public network. “This equates to 22.1% of the 524 operators known to be investing in 5G licenses, trials or deployments of any type,” the GSA said.

Separately, analysts say that 5G SA branding by network operators is quite confusing (we agree). Vodafone UK’s decision to use 5G Ultra for its 5G SA branding vs Telefonica using 5G+ are examples of that.

Gabriel Brown of Heavy Reading said, “customers don’t really know what it means, other than it denotes some form of technical advance.”  He points out that 5G SA “requires a lot of investment and deep engineering expertise; this makes it a useful proxy for network quality. Operators need to take all the technical marketing opportunities they can get.”

“What happens when BT launches? Are they going to call it 5G+ or 5G Super Ultra or something like that? That’s going to make it even more confusing,” said Kester Mann, an analyst with CCS Insight. At the same time, he agrees that 5G standalone is a significant network upgrade and it makes sense that operators would want to gain a marketing edge over rivals that have yet to launch the service.

Notably, neither Vodafone nor Telefónica is charging extra for the more advanced 5G service, and both have focused on the improved speeds and reliability it will bring. They also emphasize eco-friendly aspects, such as lower energy consumption.  However, Mann questioned Vodafone’s claim that customers with an eligible 5G Ultra device can expect up to 25% longer battery life.  “Twenty-five percent faster than what?” he asked. “It’s a bit unclear.” However, such a claim would certainly be welcome news to consumers. “In a lot of our consumer research, battery life comes out as one of the common bugbears among people using mobile phones,” said Mann.

In the U.S., T-Mobile is the only network operator that’s deployed a 5G SA network.  AT&T and Verizon have been talking about it for years, but the time frame for deployment has been pushed back several times.

Deloitte Global said it expects the number of mobile network operators investing in 5G SA networks via trials, planned deployments or rollouts to grow from more than 100 operators in 2022 to at least 200 by the end of this year.

One reason why there are relatively few 5G SA networks deployed is there are no implementation standards3GPP 5G Architecture specs, rubber stamped by ETSI,  provide several options to realize a 5G cloud-native core network which leads to different implementations.  3GPP decided NOT to liaise their 5G non-radio aspects specs (including 5G Architecture and 5G Security) to ITU-T.

Here are the key 3GPP 5G system specs:

  • TS 22.261, “Service requirements for the 5G system”
  • TS 23.501, “System architecture for the 5G System (5GS)”
  • TS 23.502 “Procedures for the 5G System (5GS)”
  • TS 32.240 “Charging management; Charging architecture and principles”
  • TS 24.501 “Non-Access-Stratum (NAS) protocol for 5G System (5GS); Stage 3”

The latest 3GPP 5G Architecture spec is System architecture for the 5G System (5GS) (3GPP TS 23.501 version 17.9.0 Release 17), published by ETSI on July 5, 2023.

Source:  3GPP

Hence, the ITU JCA on IMT2020 and Beyond is dependent on other organizations for inputs to their roadmap.  “The scope of JCA-IMT2020 is coordination of the ITU-T IMT-2020 standardization work with focus on non-radio aspects and beyond IMT2020 within ITU-T and coordination of the communication with standards development organizations, consortia and forums also working on IMT2020 and beyong IMT-2020 related standards.”

References:

https://www.lightreading.com/5g-and-beyond/plus-or-ultra-5g-sa-adds-more-brands-to-mix/d/d-id/785524?

Telefónica launches 5G SA in >700 towns and cities in Spain

https://www.silverliningsinfo.com/5g/5g-sa-springs-action

ABI Research: Expansion of 5G SA Core Networks key to 5G subscription growth

Orange-Spain deploys 5G SA network (“5G+”) in Madrid, Barcelona, Valencia and Seville

Counterpoint Research: Ericsson and Nokia lead in 5G SA Core Network Deployments

Tech Mahindra and Microsoft partner to bring cloud-native 5G SA core network to global telcos

Omdia and Ericsson on telco transitioning to cloud native network functions (CNFs) and 5G SA core networks

https://urgentcomm.com/2023/01/19/standalone-5g-progress-remains-a-disappointment/

https://www.3gpp.org/technologies/5g-system-overview

https://www.itu.int/en/ITU-T/jca/imt2020/Pages/ToR.aspx

 

Telstra partners with Starlink for home phone service and LEO satellite broadband services

Telstra, Australia’s #1 telco, will partner with SpaceX’s Starlink to provide phone and broadband services to rural Australia using Low Earth Orbit (LEO) satellites.  Telstra said it planned to offer the new services before year’s end according to a blog post.  It also promises higher download speeds compared to copper-based ADSL internet access.

Starlink, operated by Elon Musk’s SpaceX (private company). has built a fast-growing network of more than 3,500 satellites in Low-Earth Orbit that can provide connectivity in remote areas.

“Telstra will be able to provide home phone service and Starlink broadband services to Aussies as a bundle offer, as well as local tech support and the option of professional installation,” the telco said in the same blogpost.  “This agreement also provides connectivity options for our business customers, with a higher bandwidth business option available in areas without fixed and mobile connectivity. The business offer will be available to purchase from Telstra both locally and in select countries overseas.”

Using LEO satellites will bring new capabilities to commercial satellite services in Australia, including faster communications. Signal distances travelled are shorter, as LEO satellites are vastly closer to earth compared to geostationary satellites at around 35,000 km above earth.  It requires less power for an earthbound device to transmit to a satellite and there’s a reduced latency (delay) in transmission time.

Telstra said in its blog post:

One of the benefits of LEO satellites are that they are much closer than geostationary satellites to Earth with multiple satellites that are a part of a “constellation”, allowing them to send and receive signals much faster. As well as offering great data throughput, the proximity of these satellites reduces latency making them a great and more consistent option for services that need low latency, like voice and video calls.

The latency, download speeds and general experience in most circumstances will be far superior to copper-based ADSL and be better suited for most modern connectivity needs. Our team has been testing out in the field Starlink’s service and how we can best offer it to customers, including evolving our own modem specifically to support Starlink connectivity and Aussie households. We’re extremely excited to show you what this looks like later in the year.

Partnerships between telcos and LEO satellite providers will allow consumers to make satellite-connected calls using their regular smartphone from almost anywhere on the planet, whether there is a local cellular network or not. In Australia, mobile calls and even video calls will be possible on regular smartphones operating in remote and rural regions of Australia.

At Mobile World Congress held in Barcelona in March 2023, Telstra told ChannelNews it was working on adding LEO satellite audio and video calls to its network. Taiwanese chip designer MediaTek demonstrated the chips that phones would use for LEO satellite communications at the same conference.

UK phone maker Bullitt Group announced it was working with Motorola to bring satellite texting to regular phones in Australia this year, with video calling via LEO satellites to come within another two years. Their texting service has already rolled out in Europe and the US.

Telstra’s move is in line with emerging partnerships between telcos and satellite providers in the US, with T-Mobile forging a deal with Starlink and AT&T with AST SpaceMobile. T-Mobile and Starlink began testing their service in March.

Optus is yet to announce any service involving LEO satellite services locally, although it has been conducting tests. In November last year, Optus demonstrated satellite direct-to-mobile calls in partnership with LEO satellite provider Lynk.

Vodafone meanwhile has launched LEO satellite trials in Turkey with local operator partner SatCo.

It is a major coup for Telstra to be first among Australia-based Telcos to announce a specific service, however longer term, LEO satellites will allow Optus and Vodafone to be more formidable competition in rural and regional Australia, as LEO satellites will give them a reach that they don’t enjoy due to their lack of ground-based cellular infrastructure compared to Telstra.

Further, the Australian telco market will be opening up to increased international competition if offshore telcos want to join in. In March, ChannelNews reported that Amazon was gearing to take on the NBN with a fast satellite-based internet service.

Nevertheless LEO satellites are a fillip for Telstra in light of the Australian Competition and Consumer Commission’s (ACCC) decision late last year to veto a deal between Telstra and TPG Telecom to consolidate their presence in rural and fringe areas of the country through an infrastructure and service swap.

The coming of LEO satellite services also will be a test for the ACCC. To what extent does its jurisdiction cover LEO-satellite-based communications, particularly when it involves telecommunication services provided by foreign companies from space?

References:

We’re working with Starlink to connect more people in remote Australia

Telstra to partner with Elon Musk’s Starlink for satellite calls and broadband

https://www.reuters.com/business/media-telecom/telstra-partners-with-elon-musks-starlink-internet-remote-australia-2023-07-03/

Telefónica launches 5G SA in >700 towns and cities in Spain

Telefónica has followed Orange with the official launch of a 5G standalone (SA) network in more than 700 towns and cities throughout Spain. The service is branded Movistar 5G+ even though it is just 3GPP defined real 5G (with its own core network , rather than 5G NSA which uses LTE core network).  The  new Telefónica 5G SA network uses Ericsson and Nokia network equipment.  Huawei has been excluded from it because the European Commission wants to ban Huawei in the EU for its alleged espionage work for the Chinese government.

Telefonica said its 5G NSA service in the 700 MHz band is currently available to around 85 percent of the Spanish population across 2,200 municipalities. The Spanish operator also uses the 3.5 GHz band for 5G and invested EUR 20 million to secure the maximum possible 1 GHz of spectrum in the 2.6 GHz band.

“Movistar customers will be able to enjoy 5G+ automatically and at no additional cost both in large cities and in small municipalities thanks to a highly capillarity deployment that will allow ultra-fast speeds and very low latency to be obtained in practically all of Spain,” the company explained in a statement.

The launch of 5G+, which offers greater coverage and browsing speeds of up to 1,600 megabits per second (Mbps), will take place within the scope of Movistar’s deployment in the 3,500 MHz band. In practice, 5G+ translates into better mobile experience in content downloads at the speed of fiber optics, streaming High quality and uninterrupted gaming. It also offers greater coverage in crowded spaces such as a sporting event or a music concert, according to Telefónica.

Movistar currently covers a total of 11 cities with 5G SA: Madrid, Barcelona, ​​Malaga, Seville, Palma de Mallorca, Las Palmas de Gran Canaria, Ávila, Segovia, Castellón, El Ferrol and Vigo. The goal for the end of the year is to have “extensive 5G SA coverage in most cities with more than 250,000 inhabitants,” as well as in smaller towns, so that the capillarity of the service continues to be consolidated. However, in order to enjoy this service it is necessary to have a mobile that supports 5G SA. For the moment, Movistar has the new Xiaomi terminals to which new brands will be added.

Gabriel Brown, principal analyst at Heavy Reading, notes that Movistar operates the biggest network in Spain and has the largest number of live 3.5GHz sites, according to the independent AntenasMoviles website.

Said deployment is completed with the coverage in the 700 MHz band that Movistar has been offering since last year and currently reaches more than 2,200 municipalities, with advantages such as improved indoor coverage. The so-called low band is complemented in 5G with that of 3,500 MHz, ideal for services that require a user experience at a very high transmission speed, both for rural areas and large urban centers. In this way, Movistar already offers 5G coverage to more than 85% of the population, reports the company.–

Orange leads 5G SA coverage as it already reaches more than twenty cities that cover 30% of the population in Spain. In the case of Vodafone and MásMóvil, 5G SA is expected to be available before March 2024.

Heavy Reading’s Brown said, “It will be interesting to see if this gives it an edge in SA. Orange Spain, meanwhile, says it will launch network slicing before the end of the year.”

References:

https://euro.eseuro.com/business/572316.html

https://www.lightreading.com/5g-and-beyond/plus-or-ultra-5g-sa-adds-more-brands-to-mix/d/d-id/785524?

Telefonica’s 5G network reaches 82% of Spanish population

Telefónica – Nokia alliance for private mobile networks to accelerate digital transformation for enterprises in Latin America

Orange-Spain deploys 5G SA network (“5G+”) in Madrid, Barcelona, Valencia and Seville

 

 

NTT DOCOMO OREX brand offers a pre-integrated solution for Open RAN

NTT DOCOMO is leveraging its expertise to support the Open RAN efforts of network operators worldwide.  Earlier in 2023, DOCOMO adopted the OREX (Open RAN Ecosystem Experience) brand to strengthen the support scheme for international telecom operators in delivering the Open RAN system.

“OREX provides the Open RAN solution, creating a new network experience that is truly open to the world,” explains Sadayuki Abeta, NTT DOCOMO’s Global Head of Open RAN and OREX Evangelist. “OREX is committed to making 2023 the defining year for Open RAN. Our ultimate goal is to eliminate global communication gaps through the OREX initiative.”

NTT DOCOMO is the number one mobile operator in Japan. Having launched its first-generation service in 1979, since then the company has pioneered new technologies.

Today DOCOMO has three business segments: enterprise, smart life, and telecommunications. It has 87m subscribers, with 20m subscribers enjoying its 5G Open RAN services, with a total revenue of around US$44bn.

An expert in the mobile industry for more than 25 years, Abeta’s career at NTT DOCOMO started as a researcher for 4G in 1997.

“My career at NTT DOCOMO started as a researcher for 4G in 1997,” he explains. “Then, we brought our ideas to 3GPP and I participated in 3GPP standardisation from 2005.

“With 3GPP, I served as the Vice Chair of 3GPP RAN1 and the rapporteur of LTE and LTE-A. After the completion of the LTE standard specification, I led the development of eNB and gNB commercial products and network optimization in the commercial network as the General Manager of the Radio Access Network Development department.”

In 1997 the second-generation mobile system was introduced in Japan. Instead of GSM, Japan utilised the Personal Digital Cellular (PDC) system. “During this time, data services over the mobile network were initiated, but the data rate was incredibly low, starting at only 2.4kbps,” Abeta explains. “It’s hard to imagine today, but at that time, only small text messages could be transferred over the mobile network. Eventually, the data rate increased to 28.8kbps.

“In 1999, we launched the i-mode service, marking the beginning of internet services over the mobile network.”

In 2000, 3G was introduced, with DOCOMO playing a significant role in contributing to the 3GPP standard specification work. “We led technical discussions and managed the discussions as one of the officials, serving as the Chair. We were the first operator to deploy 3G networks nationwide and provided rich content via the 3G network. However, the data rate was still limited to 64Kbps or 384kbps. Later, HSPA technology was introduced, enabling much higher throughput.

“Moving forward, we proposed LTE together with our partners and launched 4G services in 2010,” Abeta describes. “Our 4G radio access network (RAN) was fully multi-vendor interoperable. We defined interfaces that were not initially defined by 3GPP, making us the first operator to deploy a multi-vendor interoperable RAN. The rise of smartphones in conjunction with our 4G services revolutionised the user experience, and its benefits are well-known.”

While DOCOMO’s communication services continued to thrive, the company also expanded its non-communication services, evolving into the smart-life service segment.

When it comes to the rollout of 5G, DOCOMO has contributed not only to 3GPP but also to the O-RAN alliance to realise multi-vendor interoperable Open RAN solutions. “In 2018, we established the 5G Open Partner Program, aiming to create new services and address social issues by collaborating with vertical players,” Abeta adds. “Currently, this program has attracted participation from 5,300 companies and organisations.”

In this exclusive interview, Sadayuki Abeta, NTT DOCOMO’s Global Head of Open RAN Solutions and OREX Evangelist discussed its OREX brand, which offers a pre-integrated solution that simplifies integration, interoperability and lifecycle management.

“OREX provides the Open RAN solution, creating a new network experience that is truly open to the world.”

NTT DOCOMO has been featured in the July issue of Mobile Magazine

Mobile Magazine is the ‘Digital Community’ for the global Telecoms industry. Mobile Magazine covers 5G, IoT, Technology, AI, Connectivity, Mobile Operators, Wireless networks and Media – connecting the world’s largest community of Telecoms executives. Mobile Magazine focuses on telecoms news, key telecoms interviews, telecoms videos, along with an ever-expanding range of focused telecoms white papers and webinars.

References:

https://www.prnewswire.com/news-releases/ntt-docomo-2023-to-be-the-defining-year-for-open-ran-301868277.html

https://mobile-magazine.com/magazines

https://www.businesswire.com/news/home/20230226005031/en/DOCOMO-Cooperating-on-Open-RAN-Initiatives-with-5-Global-Operators

 

 

SDFI: Denmark Achieves 94.5% Gigabit Broadband Internet Coverage

New data from the Broadband Mapping 2023 report by the Danish Agency for Data Supply and Efficiency (SDFI) reveals that 97.5% of homes and businesses in Denmark now have access to high-speed broadband internet access.

The latest report from the Styrelsen for Dataforsyning og Infrastruktur (SDFI) sheds light on Denmark’s regional broadband coverage rates. The Region North Jutland has almost reached a 100 percent coverage rate.

According to the report, the coverage rate in Northern Jutland stands at an impressive 98.9%. Central Jutland closely follows with 97.7% coverage, while Southern Denmark boasts a coverage rate of 98.3%t. Zealand, the country’s largest island, achieves a solid coverage rate of 98%.

Although the country has made progress in digital connectivity, according to SDFI, there are still regional disparities in coverage. The Capital Region of Hovedstaden lags behind the other regions with a coverage rate of 96.2% (compared to Northern Jutland with 98.9%). Further, 94.5% of all households in Denmark can access Gigabit speeds, an increase of 2.6 percentage points year-on-year.

The report highlights the ongoing efforts of telecommunications companies in deploying broadband across the country. According to SDFI, 97.5% of homes and businesses currently can access fast broadband with speeds of at least 100 Mbps download and 30 Mbps upload. Moreover, 94.5% of users have access to gigabit speeds, representing a 2.6 percent increase from last year.

The findings of the SDFI report demonstrate Denmark’s commitment to improving broadband infrastructure and connectivity nationwide. As the country continues to prioritize digital transformation, it will pave the way for a more connected and digitally empowered society.

References:

https://www.commsupdate.com/articles/2023/06/30/95-of-danish-households-covered-by-gigabit-speeds/

https://telecomtalk.info/denmark-achieves-945percent-gigabit-broadband-coverage-sdfi/727153/

https://digital-strategy.ec.europa.eu/en/node/9828/printable/pdf

SNS Telecom & IT: Private LTE & 5G Network Infrastructure at $6.4 Billion by end of 2026

 SNS Telecom & IT‘s latest research report indicates that global spending on private LTE and 5G network infrastructure for vertical industries – which includes RAN (Radio Access Network), mobile core and transport network equipment – will account for more than $6.4 Billion by the end of 2026.

Private cellular networks – also referred to as NPNs (Non-Public Networks) in 3GPP terminology – have rapidly gained popularity in recent years due to privacy, security, reliability and performance advantages over public mobile networks and competing wireless technologies as well as their potential to replace hardwired connections with non-obstructive wireless links.

With the 3GPP-led standardization [1.] of features such as MCX (Mission-Critical PTT, Video & Data), URLLC (Ultra-Reliable, Low-Latency Communications), TSC (Time-Sensitive Communications), SNPNs (Standalone NPNs), PNI-NPNs (Public Network-Integrated NPNs) and network slicing, private networks based on LTE and 5G technologies have gained recognition as an all-inclusive connectivity platform for critical communications, Industry 4.0 and enterprise transformation-related applications. Traditionally, these sectors have been dominated by LMR (Land Mobile Radio), Wi-Fi, industrial Ethernet, fiber and other disparate networks.

Note 1.  3GPP specs become standards when they are “rubber stamped” by ETSI.  Some are also contributed to ITU-R WP5D by ATIS, e.g. 3GPP NR became the essence of ITU-R M.2150 recommendation for 5G RANs.

The liberalization of spectrum is another factor that is accelerating the adoption of private LTE and 5G networks. National regulators across the globe have released or are in the process of granting access to shared and local area licensed spectrum.

Examples include, but are not limited to, the three-tiered CBRS (Citizens Broadband Radio Service) spectrum sharing scheme in the United States, Canada’s planned NCL (Non-Competitive Local) licensing framework, United Kingdom’s shared and local access licensing model, Germany’s 3.7-3.8 GHz and 28 GHz licenses for 5G campus networks, France’s vertical spectrum and sub-letting arrangements, Netherlands’ geographically restricted mid-band spectrum assignments, Finland’s 2.3 GHz and 26 GHz licenses for local 4G/5G networks, Sweden’s 3.7 GHz and 26 GHz permits, Norway’s regulation of local networks in the 3.8-4.2 GHz band, Poland’s spectrum assignment for local government units and enterprises, Bahrain’s private 5G network licenses, Japan’s 4.6-4.9 GHz and 28 GHz local 5G network licenses, South Korea’s e-Um 5G allocations in the 4.7 GHz and 28 GHz bands, Taiwan’s provision of 4.8-4.9 GHz spectrum for private 5G networks, Hong Kong’s LWBS (Localized Wireless Broadband System) licenses, Australia’s apparatus licensing approach, India’s CNPN (Captive Non-Public Network) leasing framework and Brazil’s SLP (Private Limited Service) licenses. Even China – where mobile operators have been at the forefront of initial private 5G installations – has started allocating private 5G spectrum licenses directly to end user organizations.

Vast swaths of globally and regionally harmonized license-exempt spectrum are also available worldwide that can be used for the operation of unlicensed LTE and 5G NR-U equipment for private networks. In addition, dedicated national spectrum in sub-1 GHz and higher frequencies has been allocated for specific critical communications-related applications in many countries.

LTE and 5G-based private cellular networks come in many different shapes and sizes, including isolated end-to-end NPNs in industrial and enterprise settings, local RAN equipment for targeted cellular coverage, dedicated on-premise core network functions, virtual sliced private networks, secure MVNO (Mobile Virtual Network Operator) platforms for critical communications, and wide area networks for application scenarios such as PPDR (Public Protection & Disaster Relief) broadband, smart utility grids, railway communications and A2G (Air-to-Ground) connectivity.

However, it is important to note that equipment suppliers, system integrators, private network specialists, mobile operators and other ecosystem players have slightly different perceptions as to what exactly constitutes a private cellular network. While there is near universal consensus that private LTE and 5G networks refer to purpose-built cellular communications systems intended for the exclusive use of vertical industries and enterprises, some industry participants extend this definition to also include other market segments – for example, 3GPP-based community and residential broadband networks deployed by non-traditional service providers. Another closely related segment is multi-operator or shared neutral host infrastructure, which may be employed to support NPN services in specific scenarios.

Key findings:

Summary of Private LTE/5G Engagements:

Some of the existing and planned private LTE and 5G engagements are in the following industry verticals:

 

References:

https://www.snstelecom.com/private-lte

SNS Telecom & IT: Open RAN Intelligent Controller, xApps & rApps to reach $600 Million by 2025

SNS Telecom & IT: Shared Spectrum to Boost 5G NR & LTE Small Cell RAN Market

SNS Telecom & IT: Spending on Unlicensed LTE & 5G NR RAN infrastructure at $1.3 Billion by 2023

SNS Telecom: U.S. Network Operators will reap $1B from fixed wireless by late 2019

BT to offer HPE Aruba managed wireless LAN service

UK network operator BT announced a partnership with HPE’s Aruba division [1.] to offer customers a new managed wireless LAN service powered by HPE Aruba Networking delivering improved performance, flexibility and control of local area networks (LANs). It combines BT’s global reach and extensive experience in the design, deployment and management of in-building wired and wireless connectivity with the latest HPE Aruba Networking LAN solutions.

Note 1.  On March 2, 2015, Hewlett-Packard announced it would acquire Aruba Networks for approximately $3 billion.  It’s interesting that enterprise LANs are now moving from Ethernet to WiFi where Aruba has been a leader (see IDC chart below).

Many legacy LANs struggle to support hybrid workers’ expectations when accessing apps in offices, branches, warehouses, factories or campuses. This is exacerbated by increasing use of bandwidth-hungry video collaboration tools. Colleagues also expect consistent and reliable Wi-Fi connectivity around the building. The increasing number of connected devices, including internet of things (IoT), adds further complexity and cyber security risks.

BT’s new HPE Aruba Networking Managed LAN service will allow customers to securely modernise connectivity to support changing workstyles and keep apace of IoT demands.

As a first step, BT audits the LAN to identify what is already in place and what could be re-used and anything that should be replaced. HPE Aruba Networking provides interoperable technology that can avoid the need to replace the entire network. BT will work collaboratively with the customer to manage costs by providing a staged approach to modernisation with benefits realised at each stage.

BT then evaluates how to secure and protect connected devices. It simplifies visibility by giving customers a single dashboard hosted in the cloud. This centralises reporting, analytics, security, scalability and resilience in one platform to help customers deliver a consistent end-user experience. It can also identify redundant devices using unnecessary power and automate network and energy optimisation.

Andrew Small, director of voice and digital work, Business, BT Group, said: “It’s clear that legacy in-building networks can’t handle modern hybrid working and IoT devices, never mind what comes next.  That’s why we’re expanding customer choice of managed LAN solutions by partnering with HPE Aruba Networking. This will offer the visibility, flexibility and security customers need to deliver productive, trusted wired and wireless connectivity.”

“Global customers that are building their connectivity strategies are focusing on modern enterprise networks that are secure, agile, responsive to business needs and simple to operate, while being powerful drivers of transformation,” said Phil Mottram, executive vice president and general manager, HPE Aruba Networking. “HPE Aruba Networking is at the forefront of reinventing how customers and partners can consume or deliver business-outcome focused networking, and by integrating our AI, security, automation, and Network as a Service capabilities, our global managed LAN service with BT is an example of how the network is helping customers achieve their business objectives.

Benefits  from Aruba LAN managed by BT:

  • Visibility across your network: Through cloud-native management console and single operating system that simplifies visibility and improves performance.
  • Optimized existing assets: A solution that integrates and optimizes existing LAN infrastructure, so you are future-ready.
  • Supported by BT’s experience in managing and transforming multi-vendor solutions to a more simplified and efficient network.
  • Remove the skills gaps: With a trusted partnership that has the combined breadth and depth of our expertise to deliver standalone LAN, campus-wide LAN, and wider transformation solutions.
  • Secure and automate: End-to-end managed service and deployment. Scale up or down as needed. Implement additional services, such as advanced security to gain greater insight into your network and apps.
  • Innovate and grow: Through centralised reporting, analytics, security, scalability, and resilience all in one platform that helps you deliver a consistent end-user experience and build a robust and innovative LAN.
  • Sustainable solution: BT’s Aruba LAN can identify redundant devices using unnecessary power. In addition, it uses automation to optimise network management and energy efficiency.

Market Assessment:

According to Dell’Oro group, enterprise WLAN revenues surged 48% year-on-year in the first quarter of the year, reaching $2.7 billion. Dell’Oro’s Wireless LAN research director Siân Morgan noted that the market hasn’t seen such consistent y-o-y revenue growth for 10 years. Dell’Oro expects revenues to reach $10 billion this year.  Dell’Oro said the growth in Q1 appears to have been driven by backlogged orders being filled, and that this is actually masking a decline in new orders.

IDC published its own figures this month that put global enterprise Wireless LAN (WLAN) revenue at $2.8 billion in the first quarter, up 43.3 percent on last year. Similarly to Dell’Oro, IDC said growth was driven by the easing of component shortages and supply constraints, allowing suppliers to catch up with back orders.

In terms of vendors, IDC ranks HPE Aruba second by Q1 market share at 16 percent, noting that its revenue grew 39.5%. Cisco is still the clear leader, with a market share of 47.1% and impressive enterprise WLAN revenue growth of 62.7% (see chart).

References:

https://newsroom.bt.com/bt-and-hpe-partner-for-new-global-managed-lan-service/

https://www.globalservices.bt.com/en/solutions/products/aruba-lan

https://www.arubanetworks.com/products/wireless/access-points/indoor-access-points/

https://telecoms.com/522453/bt-taps-hpe-for-global-managed-lan-service/

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