5G Network Slicing Tutorial + Ericsson releases 5G RAN slicing software
5G Network Slicing Tutorial:
While there is no ITU-T recommendation to implement 5G network slicing, 3GPP Network Slicing requirements are included in 3GPP TS 22.261, Service requirements for the 5G system Stage 1, for Release 15 and updated for Release 16. As defined by 3GPP, Network slicing allows the 5G network operator to provide customized networks with different QoS capabilities.
A Network Slice is a logical (virtual) network customized to serve a defined business purpose or customer, consisting of an end-to-end composition of all the varied network resources required to satisfy the specific performance and economic needs of that particular service class or customer application. The ideas in play in developing and progressing the ‘slice’ concept draw on a progression of similar but simpler parallels in preceding network architectures including IP/Ethernet networking services (VLANs, IP VPNs, VPLS, etc.), and broaden the scope to include a wide range of access and core network functions from end-to-end and from the top to the bottom of the networking stack. Network slicing offers a conceptual way of viewing and realizing service provider networks by building logical networks on top of a common and shared infrastructure layer. Network slices are created, changed and removed by management and orchestration functions, which must be considerably enhanced to support this level of multi-domain end-to-end virtualization.
Here are a few use cases for 5G network slicing, which will likely to lead to different phases of adoption:
• Network Slicing can be used for operational purposes by a single network operator, to differentiate characteristics and resources for different broad
classes of services
• Network slicing can be used by a service provider seeking to establish a virtual service provider network over the infrastructure of a physical network operator
• Network slicing can allow individual end customers (enterprises) to be able to customize a virtual network for their operations and consume these network resources in a more dynamic way similar to today’s cloud services (i.e. dynamically varying scale, or for temporary needs).
• Network slicing can allow for “traffic splitting” across networks (5G, 4G, and WiFi via hybrid fiber-coax).
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Ericsson launches 5G RAN Slicing to spur 5G business growth:
- New software solution enables communications service providers to deliver innovative 5G use cases to consumers and enterprises with guaranteed performance
- Built on Ericsson radio expertise and a scalable and flexible architecture, the new solution supports customized business models and growth requirements of advanced use cases
- Ericsson 5G RAN Slicing strengthens end-to-end network slicing capabilities needed to deliver different services over a common infrastructure
Network slicing supports multiple logical networks for different service types over one common infrastructure. It is a key enabler for unlocking 5G revenue opportunities such as enhanced video, in-car connectivity and extended reality, Ericsson said.
Ericsson said what makes its product distinct is that it boosts end-to-end management and orchestration support for fast and efficient service delivery. This gives service providers the differentiation and guaranteed performance needed to monetize 5G investments. Ericsson’s network slicing platform is already in use in the consumer segment and for enterprise applications such as video-assisted remote operations, AR/VR, sports event streaming, cloud gaming, smart city, and applications for Industry 4.0 and public safety. Customers working with the system include KDDI and Swisscom.
An Ericsson report estimates USD 712 billion in an addressable consumer market for service providers by 2030. The addressable market for network slicing alone in the enterprise segment is projected at USD 300 billion by 2025 (GSMA data). As 5G scales up, service providers are looking to maximize returns on their investments by targeting innovative and high revenue-generating use cases such as cloud gaming, smart factories, and smart healthcare.
Toshikazu Yokai, Executive Officer, Chief Director of Mobile Technology, at KDDI, says: “End-to-end slicing is key to monetizing 5G investment and RAN slicing will help make that happen. Across different slices in our mobile networks, RAN slicing will deliver the quality assurance and latency required by our customers.”
Mark Düsener, Head of Mobile and Mass Market Communication at Swisscom, says: “We’re gearing up for the next stage of 5G where we expect to apply end-to-end network slicing, and RAN slicing is key to guaranteed performance. With efficient sharing of network resources across different slices, we will be able to provide communications for diverse 5G applications such as public safety or mobile private networks.”
Sue Rudd, Director, Networks and Service Platforms, Strategy Analytics, says: “Ericsson is the first vendor to offer a fully end-to-end solution with RAN slicing based on dynamic radio resource partitioning in under 1 millisecond using embedded radio control mechanisms to assure Quality of Service, Over the Air, in real time. This truly end-to-end approach integrates radio optimization with policy-controlled network orchestration to deliver inherently secure virtualized private RAN slicing without the loss of the 30 – 40 percent spectrum capacity due to ‘hard slicing’. Ericsson’s real-time dynamic RAN slicing bridges the ‘RAN gap’ to make e2e slicing profitable.”
About Ericsson 5G RAN Slicing:
The Ericsson 5G RAN Slicing solution offers a unique, multi-dimensional service differentiation handling that allows for the effective use of dynamic radio resource partitioning, slice-aware quality of service (QoS) enforcement, and slice orchestration functionality for service-level agreement (SLA) fulfilment. Built on Ericsson radio expertise and a flexible and scalable slicing architecture, the solution dynamically shares radio resources at 1 millisecond scheduling for best spectrum efficiency. This enables service providers to offer a variety of use cases with increased flexibility and versatility. It ensures end-to-end network slice management and orchestration support for fast service delivery and supports business models for virtual, hybrid and dedicated private networks. The solution can also power use cases for mission-critical and time-critical communication services.
References:
https://techblog.comsoc.org/2018/05/18/ieee-comsoc-papers-on-network-slicing-and-5g/
https://www.ericsson.com/en/network-slicing
https://www.telecompaper.com/news/ericsson-releases-5g-ran-slicing-software–1369987
Join an Ericsson live broadcast session: February 4, 2021 at, 3pm CET on LinkedIn, Facebook, Twitter, or YouTube
LG U+ first to deploy 600G backbone network in Korea with Ciena’s ROADM equipment
South Korea network operator LG U+ today announced it is the first carrier in South Korea to deploy 600Gb/sec on a single wavelength for long haul, using Ciena’s WaveLogic 5 technology. LG U+ made this upgrade to support remote experiences.
The company will establish a ROADM (Re-configurable Optical Add-Drop Multiplexer) backbone network to strengthen the competitiveness of business. LG U+’s newly constructed and dedicated nationwide ROADM backbone network will satisfy the needs of customers and preemptively respond to increased traffic following the introduction of the remote era. For this network transformation, LG U+ has selected Ciena’s WaveLogic 5 Extreme and WaveLogic Ai coherent optical solutions.
Sung-cheol Koo who’s in charge of LG U+’s wired business said, “Amid the expansion of cloud services such as telecommuting, video conferencing and remote classes, we are building a new backbone network that can accommodate the needs of various corporate customers. With a flexible and stable transmission network, we expect that companies can provide a higher level of service.”
LG U+ also applied the Optical Time Domain Reflectometer (OTDR) technology, which measures the loss of optical lines, disconnection points, and distances across the entire section of the new backbone network. By intuitively monitoring the condition of the line in real time, it is possible to shorten the response time in case of a failure.
With rapidly increasing traffic, Ciena will enable LG U+ to transmit single-carrier 600G wavelengths over the new flexible grid backbone that has six times the network capacity compared to the existing network. The new backbone network will provide enhanced availability through low-latency, multiple route diversity and direct connections between large cities without the need for regeneration.
LG U+ is in the process of implementing a major capacity upgrade, including multi-terabits of additional capacity, to accommodate large-capacity customers and enable stable traffic management. By applying OTDR (Optical Time Domain Reflectometer) technology to all sections of the backbone network, real-time and intuitive line condition monitoring is possible to shorten troubleshooting time and enable smooth network management and operations.
In addition, Ciena’s 6500 ROADM equipment can reliably configure DR (Disaster Recovery) line services to public government, financial institutions and compute centers of large enterprises through third party interworking certification. LG U+ can also provide a dedicated line service with enhanced security through optical transport encryption.
LGU+ will be using Ciena’s Manage, Control and Plan (MCP) SDN controller to be able to automate service delivery via next-generation OPEN APIs to improve customer experience and increase operational efficiencies.
References:
https://www.ciena.com/about/newsroom/press-releases/lg-u-builds-new-nationwide-backbone-network.html
Starlink Internet could be a game changer with 100 megabytes per second download speed
Elon Musk’s Space Exploration Technologies Corp (Space X) has launched more than 1,000 satellites for its Starlink internet service and is signing up early customers in the U.S., U.K. and Canada. SpaceX has told investors that Starlink is angling for a piece of a $1 trillion market made up of in-flight internet, maritime services, demand in China and India — and rural customers such as Brian Rendel. He became a Starlink tester in November after struggling for years with sluggish internet speeds at his 160-acre farm overlooking Lake Superior in Michigan’s Upper Peninsula. After he paid about $500 for the equipment, FedEx arrived with a flat dish and antenna. For $99 a month, Rendel is now getting speeds of 100 megabytes per second for downloads and 15 to 20 for uploads — far faster, he says, than his previous internet provider.
“This is a game changer,” said Rendel, a mental health counselor, who can now easily watch movies and hold meetings with clients over Zoom. “It makes me feel like I’m part of civilization again.”
For months, SpaceX has been launching Starlink satellites on its Falcon 9 rockets in batches of 60 at a time, and the 17th Starlink launch was on Jan. 20. There are now roughly 960 functioning satellites in orbit, heralding an age of mega-constellations that have prompted worries about visual pollution for astronomers.
But the Starlink array in low-Earth orbit, closer to the planet than traditional satellites, is enough to enable SpaceX to roll out service along a wide swath of North America and the U.K. As SpaceX sends up more satellites, the coverage area will grow, expanding the potential customer base — and revenue stream — beyond the initial stages of today.
“The big deal is that people are happy with the service and the economics of Starlink versus other alternatives,” said Luigi Peluso, managing director with Alvarez & Marsal, who follows the aerospace and defense industries. “SpaceX has demonstrated the viability of their solution.”
Last year, SpaceX Chief Operating Officer Gwynne Shotwell said that Starlink is a business that SpaceX– one of the most richly valued venture-backed companies in the U.S. — is likely to spin out and take public. That dangles the possibility of another Musk enterprise offering shares after last year’s sensational stock-market gains by Tesla Inc.
Starlink will face plenty of competition. While fiber optic cable is widely considered too expensive to lay down in remote regions and many rural locations, cellular connectivity is expected to make big advances with 5G and then 6G. Meanwhile, a number of innovative attempts to extend cellular to unserved areas are being developed by other well-heeled companies such as Facebook Inc.
“There will always be early Starlink adopters who think that anything from Elon Musk is cool,” said John Byrne, a telecom analyst at GlobalData. “But it’s hard to see the satellite trajectory keeping pace with the improvements coming with cellular.”
SpaceX, based in Hawthorne, California, is primarily known for launching rockets for global satellite operators, the U.S. military, and NASA. Last year, SpaceX made history by becoming the first private company to fly astronauts to the International Space Station. Maintaining strong service while growing the customer base is something SpaceX has never tried before.
“Like any network, Starlink is going to enjoy rave reviews while it is underutilized,” said industry analyst Jim Patterson. “However, it will be challenged with the same congestion issues as their peers as they grow their base.”
Then again, SpaceX says the service will improve as it builds out more infrastructure.
“As we launch more satellites, install more ground stations and improve our networking software, data speed, latency and uptime will all improve dramatically,” Kate Tice, a senior engineer at SpaceX, said in a livestream of a Starlink mission in November.
Starlink is gearing up for a big 2021, hiring software engineers, customer support managers, a director of sales, and a country launch manager. The fan fervor that made Tesla cars such a hit with consumers and retail investors extends to Starlink. Facebook groups, Reddit threads and Twitter are filled with reports from early customers sharing images of their download speeds. You Tube has videos of people “unboxing” their Starlink dish and going through the initial set-up.
Ross Youngblood lives in Oregon and works remotely as an engineer for a tech company in San Jose. He owns a Tesla Model X and follows All Things Musk pretty closely. He got Starlink before Thanksgiving.
“I just plugged it all in and it started to work,” said Youngblood. “It’s going to be very disruptive, and I don’t think enough people are paying attention.”
Many other customers are waiting in the wings. In December, the Federal Communications Commission awarded SpaceX $885.5 million in subsidies as part of a wider effort to bring broadband to over 10 million Americans in rural areas. SpaceX will focus on 35 states, including Alabama, Idaho, Montana and Washington.
“We can’t continue to throw money at aging infrastructure,” said Russ Elliot, director of the Washington State Broadband Office. “With Starlink, you can be anywhere. The cost to build in deep rural or costly areas is now less of an issue with this technology as an option.”
Early in the coronavirus pandemic, Elliot connected SpaceX with members of the Hoh Tribe in far western Washington. The Native American community had struggled for years to bring high-speed internet to their remote reservation, which spans about 1,000 acres and has 23 homes. Kids struggled to access remote learning, and internet connections were so slow that downloading homework could take all day.
“SpaceX came up and just catapulted us into the 21st century,” said Melvinjohn Ashue, a member of the Hoh Tribe, in a short video produced by the Washington State Department of Commerce. In a phone interview with the Economic Times of India, Ashue said that the first thing he did once he connected to Starlink was download a long movie: Jurassic Park. Now most of the reservation’s households have Starlink, making it possible for families to access not just online schooling but tele-health appointments and online meetings.
“Internet access is a utility. It’s no longer a luxury,” said Maria Lopez, the tribal vice chairwoman. Lopez said that Starlink was easy to hook up. The scariest part was climbing up a ladder to set up the dish on her roof. “Every now and then it will glitch,” she said. “But it quickly reboots itself,” Ms. Lopez added.
References:
After 9 years Alphabet pulls the plug on Loon; Another Google X “moonshot” bites the dust!
After nine years as the high-flyer of the Google X lab, Alphabet is ending Loon, which was one of the company’s high-profile, cutting-edge efforts. Loon aimed at providing Internet access to rural and remote areas, creating wireless networks with up to 1 Mbit/second speeds using high-altitude balloons at altitudes between 18 and 25 km (11 and 16 miles). As for so many of Google X labs “moonshots,” it was difficult to turn Loon into a business.
“The road to commercial viability has proven much longer and riskier than hoped. So we’ve made the difficult decision to close down Loon,” Astro Teller, who heads Google X, wrote in a blog post. Alphabet said it expected to wind down operations in “the coming months” with the hope of finding other positions for Loon employees at Alphabet.
Sadly, despite the team’s groundbreaking technical achievements over the last 9 years — doing many things previously thought impossible, like precisely navigating balloons in the stratosphere, creating a mesh network in the sky, or developing balloons that can withstand the harsh conditions of the stratosphere for more than a year — the road to commercial viability has proven much longer and riskier than hoped. So we’ve made the difficult decision to close down Loon. In the coming months, we’ll begin winding down operations and it will no longer be an Other Bet within Alphabet.
From the farmers in New Zealand who let us attach a balloon communications hub to their house in 2013, to our partners who made it possible to deliver essential connectivity to people following natural disasters in Puerto Rico and Peru, to our first commercial partners in Kenya, to the diverse organizations working tirelessly to find new ways to deliver connectivity from the stratosphere — thank you deeply. Loon wouldn’t have been possible without a community of innovators and risk-takers who are as passionate as we are about connecting the unconnected. And we hope we have reason to work together again before long.
The idea behind Loon was to bring cellular connectivity to remote parts of the world where building a traditional mobile network would be too difficult and too costly. Alphabet promoted the technology as a potentially promising way to bring internet connectivity to not just the “next billion” consumers but the “last billion.”
The giant helium balloons, made from sheets of polyethylene, are the size of tennis courts. They were powered by solar panels and navigated by flight control software that used artificial intelligence to drift efficiently in the stratosphere. While up in the air, they act as “floating cell towers,” transmitting internet signals to ground stations and personal devices.
Credit…Loon LLC, via Associated Press
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Google started working on Loon in 2011 and launched the project with a public test in 2013. Loon became a stand-alone subsidiary in 2018, a few years after Google became a holding company called Alphabet. In April 2019, it accepted a $125 million investment from a SoftBank unit called HAPSMobile to advance the use of “high-altitude vehicles” to deliver internet connectivity.
Last year, Google announced the first commercial deployment of the Loon technology with Telkom Kenya to provide a 4G LTE network connection to a nearly 31,000-square-mile area across central and western Kenya, including the capital, Nairobi. Before then, the balloons had been used only in emergency situations, such as after Hurricane Maria knocked out Puerto Rico’s cellular network. In closing down this pilot service in Kenya, Loom said it would pledge $10 million to Kenyan non-profits and businesses offering “connectivity, internet, entrepreneurship, and education.”
Loon was starting to run out of money and had turned to Alphabet to keep its business solvent while it sought another investor in the project, according to a November report in The Information.
The decision to shut down Loon is another signal of Alphabet’s recent austerity toward its ambitious and costly technology projects. Under Ruth Porat, Alphabet’s chief financial officer since 2015, the company has kept a close watch over the finances of its so-called Other Bets, fledgling business ventures aimed at diversifying from its core advertising business.
Alphabet has aggressively pushed its “Other Moonshot Bets” like Waymo and Verily, a life sciences unit, to accept outside investors and branch out on their own. Projects that failed to secure outside investment or show enough financial promise have been discarded, such as Makani, a project to produce wind energy kites that Alphabet shut down last year.
That austerity has been a notable change from a time when units like X, which had been a favored vanity project of Google’s co-founders Larry Page and Sergey Brin, had autonomy to spend freely to pursue ambitious technology projects even if the financial outlook remained unclear.
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Facebook’s efforts have likewise stumbled, with Mark Zuckerberg’s company deciding in 2018 to ground Aquila, its gigantic, solar-powered drone designed to deliver Internet by laser. “Surprisingly, it’s just not practical,” drolly commented Techcrunch. Instead, it is efforts to beam the net from satellites that seem to be meeting with higher-flying fortunes.
Starlink, the satellite network being built by Elon Musk’s SpaceX, appears to be making fast progress – with 800 satellites, including 60 launched in November.
Its launch of services in the rural UK this month is bad news for OneWeb – which only just emerged from bankruptcy in November with new owners, the UK Government and Bharti Global. Analysts, though, think neither will provide too much of a threat to established Internet providers in urban are
For all that was innovative about its technology, Loon never turned a profit, and the company was tight-lipped about precisely how many users it ever had. It was never a matter of providing free Internet to the masses, but instead, of amplifying the reach of existing telecoms companies to rural populations, via the balloon network. Once connected, clients paid for the Internet, just like anybody else. It just seems there were not enough of them who did.
Its technical advances concerned a type of ballet, using its software system to predict how weather events could move its balloons, then adapting the balloons’ height in accord with wind currents to manipulate their position. The balloons usually lasted a few hundred days, after which they were directed to a landing zone – though the landings weren’t always as accurate as its engineers would have hoped.
References:
https://blog.x.company/loons-final-flight-e9d699123a96
https://medium.com/loon-for-all/loon-draft-c3fcebc11f3f
https://www.lightreading.com/services/google-pops-loon-balloon/d/d-id/766855?
Analysis: Telefonica, Vodafone, Orange, DT commit to Open RAN
Four of Europe’s biggest network operators have signed a Memorandum of Understanding (MoU) to express their individual commitment to the implementation and deployment of Open Radio Access Network (Open RAN) as the technology of choice for future mobile networks across Europe. In a statement, Telefonica, Deutsche Telekom, Orange and Vodafone pledged to back Open RAN systems that take advantage of new open virtualized architectures, software and hardware with a view to enhancing the flexibility, efficiency and security of European networks in the 5G era.
The four operators committed to working together with existing and new ecosystem partners, industry bodies like the O-RAN Alliance and the Telecom Infra Project (TIP), as well as European policy makers, to ensure Open RAN quickly reaches competitive parity with traditional RAN solutions. “This initiative is an important milestone towards a diverse, reinvigorated supplier ecosystem and the availability of carrier-grade Open RAN technology for a timely commercial deployment in Europe,” they said in a joint statement.
The MNOs added that the introduction of Open RAN, virtualisation and automation would pave the way for a fundamental change in the way operators manage networks and deliver services, allowing them to add or shift capacity more quickly for end users, automatically resolve network incidents or provide enterprise level services on-demand for industry 4.0.
The four operators also expressed the hope that the European Commission and national governments will agree to play an important role in fostering and developing the Open RAN ecosystem by funding early deployments, research and development, open test lab facilities as well as incentivising supply chain diversity by lowering barriers to entry for small suppliers and startups.
The MoU comes a few days after Telefonica announced plans to use open RAN technology at around 1,000 of its mobile sites in Germany. Vodafone made a similar commitment at around 2,600 of its masts and rooftops in the UK at the end of last year.
Without orders from numerous large operators, open RAN producers have struggled to increase volumes and generate the necessary economies of scale.
“This is like putting the band back together,” says Gabriel Brown, a principal analyst with Heavy Reading, a sister company to Light Reading. “The European operators are saying if we co-operate then we can have a meaningful influence and impact on the way open RAN develops.”
Operators are drawn to open RAN because it would allow them to mix and match vendors, using radio software from one vendor in tandem with general-purpose equipment developed by another. Traditional radio access networks typically force operators to buy all their components from the same supplier.
While today’s statement is light on details of firm commitments, Vodafone has already promised to use open RAN technology at around 2,600 of its mobile sites in the UK, while Telefónica this week said it would do the same at roughly 1,000 sites in Germany.
Deutsche Telekom, Germany’s telecom incumbent, has had less to say about rollout targets, although in December it revealed plans to build an “O-RAN town” in Neubrandenburg this year. “This will be a small-scale commercial deployment, which will encompass up to 150 cells, and will bring open RAN into a real 4G/5G network environment,” said a Deutsche Telekom spokesperson by email.
That leaves France’s Orange, which has now made a jaw-dropping commitment: Starting in 2025, it will buy only open RAN equipment when upgrading its European networks.
“From 2025, our intention is that all new equipment deployed by Orange in Europe should be based on open RAN,” says Arnaud Vamparys, Orange’s senior vice president of radio networks. “This is a good time to send a clear message.”
His expectation is that over this timeframe open RAN will reach “parity” with traditional RAN for deployment in a macro network. That would mean resolving some of the performance shortcomings that have mainly restricted open RAN to rural and less demanding conditions.
“2025 sounds about right,” says Brown. “The integrated systems are really setting a very high bar and open RAN is behind on features and performance right now.”
Brown told Light Reading he was encouraged by some of the recent open RAN activity in the semiconductor industry, citing baseband advances by Marvell and radio innovation by Xilinx. But he says it is too early to say open RAN will definitely be a mainstream success by the mid-2020s. “Can this be the best way to build a radio access network? If it isn’t, it is probably not going to succeed.”
“We continue to work to unlock the value of these European programs because clearly there are industry-leading initiatives of some of the manufacturing being brought back to Europe, especially on open RAN,” said Markus Haas, Telefónica Deutschland’s CEO, when asked during an analyst call this week if the telecom sector could be a beneficiary of Europe’s COVID-19 recovery fund.
“There is high interest so that the overall industry, the vendor landscape, might change or might be empowered by additional funds in order to progress and accelerate open RAN.”
While Ericsson and Nokia say they are now investing in open RAN technology, Vodafone looks determined to use alternative players for its 2,600-site rollout. Supplier diversification has topped the agenda for other service providers, as well.
“We want Europe to play a role in that evolution and it has to unite a bit to achieve this goal,” says Orange’s Vamparys. “There are lots of US and Japanese companies pushing strongly for the acceleration of open RAN. If we don’t communicate and help other companies, it could create an unbalanced situation.”
SOURCE: ORAN Alliance
Telefónica Deutschland named Altiostar, KMW, NEC and Supermicro as potential open RAN partners in a presentation it gave this week, while Deutsche Telekom has been in talks with Dell, Fujitsu, Mavenir, Nokia and NEC.
Vodafone has already carried out open RAN trials with Mavenir and Parallel Wireless.
The region’s biggest gap is probably in silicon, says Heavy Reading’s Brown. Most of the high-profile chipmakers developing open RAN technology, including Marvell and Xilinx, are based in the US.
Arm, a UK-based firm whose processor designs are used in many of the world’s smartphones, is a member of the O-RAN Alliance, the group responsible for open RAN specifications. But it is also currently the target of a $40 billion takeover move by Nvidia, a US semiconductor maker.
In the meantime, any plan to use part of the European recovery fund to support open RAN could meet with political resistance given the healthy state of the telecom sector compared with other industries, including airlines, hospitality, retail and tourism.
John Strand, the CEO of advisory firm Strand Consult, lashed out at the suggestion that open RAN could benefit from Europe’s COVID-19 stimulus package.
“Do these companies need subsidies? Is Telefónica in such a bad position that it needs public funding?” he told Light Reading. “We are living in a time when numbers of companies are in deep financial crisis because of COVID-19 and telecom operators, which definitely haven’t been hit, are asking for subsidies.”
Market forecasters now think open RAN will account for about one tenth of the overall market for radio access network products by the mid-2020s:
- Omdia expects industry revenues to increase from just $70 million in 2019 to about $3.2 billion in 2024, giving it a 9.4% share of the 4G and 5G market.
- Dell’Oro, another analyst firm, is in broad agreement: Last year, it predicted operators would spend somewhere north of $3 billion on open RAN products in 2024.
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References:
https://www.telecompaper.com/news/telefonica-vodafone-orange-dt-sign-open-ran-mou–1369273
Viavi Solutions and Mavenir collaborate to validate new SD, cloud-native RAN infrastructure
VIAVI Solutions Inc today announced that Mavenir, an upstart provider of end-to-end cloud-native network software for mobile operators, is collaborating with VIAVI for lab validation of radio access solutions in the U.S. VIAVI’s lab test platform, in use by almost every base station manufacturer in the world, provides scalable test systems for validating network performance as experienced by end users, across multiple cells and different radio access technologies.
The year 2020 marked a significant inflection point for mobile networks around the globe. With 229 million subscribers as of December 2020, 5G became the fastest growing mobile technology in history. New MNOs (like Dish Network) were granted licenses to establish greenfield networks to take advantage of this demand. Meanwhile, #1 base station maker Huawei was restricted from supplying infrastructure in markets around the globe. These trends have driven an expansion of the supply chain for mobile network solutions.
VIAVI tools are able to measure the complete performance of the network over multiple interfaces including O-RAN and RF through to the packet core. Capable of emulating one to many thousands of UEs, the platforms create a sophisticated and precise test environment, including comprehensive feature interactions, simulated RF and mobility, accurate replications of real-world user behavior profiles, together with mobility across the radio access network.
“Mavenir is proud to be a leading vendor to mobile operators around the globe, offering software-defined infrastructure that can adapt to evolving requirements for both brownfield and greenfield networks, large-scale to startup networks,” said Ramnik Kamo, EVP Quality, Systems and People, Mavenir. “VIAVI has been a highly collaborative partner with our two companies’ engineering teams working together to prove a new technology against very tight customer timescales.”
“As vendors across the industry develop open, cloud-native and disaggregated architectures, testing against user expectations of service quality will be critical to accelerate adoption at scale,” said Luiz Cesar Oliveira, Vice President, Americas, VIAVI. “We are excited to help Mavenir optimize their advanced radio access solutions based on our unique experience supporting over 200 service providers and virtually every network equipment manufacturer worldwide.”
About VIAVI
VIAVI (NASDAQ: VIAV) is a global provider of network test, monitoring and assurance solutions for communications service providers, enterprises, network equipment manufacturers, government and avionics. We help these customers harness the power of instruments, automation, intelligence and virtualization to Command the network. VIAVI is also a leader in light management solutions for 3D sensing, anti-counterfeiting, consumer electronics, industrial, automotive, and defense applications. Learn more about VIAVI at www.viavisolutions.com. Follow us on VIAVI Perspectives, LinkedIn, Twitter, YouTube and Facebook.
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References:
Deutsche Telekom’s T-Labs enters research partnership to progress quantum technologies
Deutsche Telekom said it is taking part in the Platform and Ecosystem for Quantum-Assisted Artificial Intelligence project to conduct research into quantum technologies, under the leadership of research and development unit T-Labs. Deutsche Telekom will carry out research activities and tests for potential use cases of quantum technologies, particularly for network operators. A consortium of 15 partners and 33 associated partners are taking part the research projects, funded by the German Federal Ministry of the Economy.
T-Labs will provide specific use cases from the field of telecommunications, including the optimization of communication networks, Industry 4.0 applications or AI-clustering problems for customer segments. Quantum algorithms can provides solutions to the complexity and size of applications. Quantum computers could be used for Deutsche Telekom’s operational business.
Quantum algorithms for telecommunication providers
Quantum computers promise an exponential increase in processing speed for selected problem classes. For example, in combinatorial optimization problems or the training of AI models (AI: artificial intelligence). In communication science, Shor’s algorithm is usually considered the “killer application” of quantum computing. This is because quantum computers can use it to attack today’s security infrastructures.
In the PlanQK project, T-Labs provides some specific use cases from the field of telecommunications. These include the optimization of communication networks, Industry 4.0 applications or AI-clustering problems for customer segments. These applications have a high level of complexity and, if the problem exceeds a critical size, can only be calculated classically with great difficulty. Here, quantum algorithms promise the solution. With growing size, quality and processing speed, quantum computers could find their way into Telekom’s operational business.
The path to a standardized quantum app store
However, the goal is not only to evaluate and demonstrate the applicability of current quantum technology for use at Telekom. The PlanQK project also seeks to prevent the risk of any one company achieving a dominant market position and setting de facto industry standards. This project is targeted at ensuring the development and establishment of a vendor-independent platform and associated ecosystem for quantum-assisted artificial intelligence. Users could then, for example, compile solutions for their company or commission them via the cloud or a quantum app store.
About Deutsche Telekom: Deutsche Telekom at a glance
About T-Systems: T-Systems company profile
References:
New ITU-T SG13 Recommendations related to IMT 2020 and Quantum Key Distribution
OneWeb secures additional funding with goal of 648 total satellites for broadband connectivity by end 2022
OneWeb, the Low Earth Orbit (LEO) satellite communications company that’s emerged from bankruptcy is jointly owned by the UK Government and Bharti Global. The company today announced that it has secured additional funding from SoftBank Group Corp. (“SoftBank”) and Hughes Network Systems LLC (“Hughes”), bringing OneWeb’s total funding to $1.4 billion. The capital raised to date positions the Company to be fully funded for its first-generation satellite fleet, totaling 648 satellites, by the end of 2022.
Prior to the latest funding round, the UK government and Bharti Global held 42.2% stake, respectively in OneWeb with other partners holding the balance 15.6%. “The capital raised to date positions the company to be fully funded for its first-generation satellite fleet, totaling 648 satellites, by the end of 2022,” as per a statement released by OneWeb.
Currently, satellite internet is a great option for residents of rural or suburban areas. Along with basically unlimited availability, satellite internet also offers Wi-Fi connectivity and speeds fast enough for streaming services. In addition to OneWeb, Starlink/SpaceX, Kuiper/Amazon, Boeing and Telesat are investing heavily into LEO satellites, aiming to launch thousands of low-orbiting satellites in coming years.
OneWeb’s mission is to deliver broadband connectivity worldwide to bridge the global Digital Divide by offering everyone, everywhere access including to the Internet of Things (IoT) future and a pathway to 5G.
OneWeb’s LEO satellite system includes a network of global gateway stations and a range of user terminals for different customer markets capable of delivering affordable, fast, high-bandwidth and low-latency communications services. In December 2020, OneWeb launched 36 new satellites, built at its Airbus Joint Venture assembly plant in Florida, USA, bringing the Company’s total fleet to 110 satellites, all fully-functioning and benefitting from International Telecommunication Union spectrum priority.
Sunil Bharti Mittal, Executive Chairman of OneWeb, commented, “We are delighted to welcome the investment from SoftBank and Hughes. Both are deeply familiar with our business, share our vision for the future, and their commitment allows us to capitalise on the significant growth opportunity ahead for OneWeb. We gain from their experience and capabilities, as we deliver a unique LEO network for the world.”
Secretary of State, BEIS, The Rt. Hon. Kwasi Kwarteng, MP said: “Our investment in OneWeb is part of our continued commitment to the UK’s space sector, putting Britain at the forefront of the latest technological advances. Today’s investment brings the company one step closer to delivering its mission to provide global broadband connectivity for people, businesses and governments, while potentially unlocking new research, development and manufacturing opportunities in the UK.”
Masayoshi Son, Representative Director, Corporate Officer, Chairman & CEO of SoftBank, said, “We are excited to support OneWeb as it increases capacity and accelerates towards commercialisation. We are thrilled to continue our partnership with Bharti, the UK Government and Hughes to help OneWeb deliver on its mission to transform internet access around the world.”
Pradman Kaul, President of Hughes, remarked, “OneWeb continues to inspire the industry and attract the best players in the business to come together to bring its LEO constellation to fruition. The investments made today by Hughes and SoftBank will help realise the full potential of OneWeb in connecting enterprise, government and mobility customers, especially with multi-transport services that complement our own geostationary offerings in meeting and accelerating demand for broadband around the world.”
Neil Masterson, CEO of OneWeb, added “OneWeb’s mission is to connect everyone, everywhere. We have made rapid progress to re-start the business since emerging from Chapter 11 in November. We welcome the investments by SoftBank and Hughes as further proof of progress towards delivering our goal.”
In connection with the investment, SoftBank will gain a seat on the OneWeb Board of Directors. Hughes is an investor through its parent company EchoStar, and also an ecosystem partner, developing essential ground network technology for the OneWeb system.
Additionally, OneWeb has reduced its request for US market access from 47,884 to 6,372 satellites. Together with the satellites for which it is already licensed by the FCC, the total constellation size will be roughly 7,000, down from the 48,000 or so proposed last year.
According to the company, this solidification of their constellation demonstrates the commitment and vision of OneWeb’s new owners, the UK Government and Bharti Global, who are dedicated to deploying a cost effective, responsible, and groundbreaking satellite network to deliver global broadband.
The firm stated that OneWeb remains focused on launching its first-generation system of 648 satellites and is on track to start regional commercial services within a year. This streamlining of activities highlights OneWeb’s plan for global connectivity services and for future generations and possibilities for the network.
About OneWeb:
OneWeb is a global communications network powered from space, headquartered in London, enabling connectivity for governments, businesses, and communities. It is implementing a constellation of Low Earth Orbit satellites with a network of global gateway stations and a range of user terminals to provide an affordable, fast, high-bandwidth and low-latency communications service, connected to the IoT future and a pathway to 5G for everyone, everywhere. Find out more at http://www.oneweb.world
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Google Cloud and Nokia partner to build cloud-native 5G Core and Edge Networking
Google Cloud, Nokia partner to accelerate cloud-native 5G readiness for communication service providers:
- Google Cloud and Nokia will jointly develop cloud-native 5G core solutions for communication service providers and enterprise customers
- New partnership will deliver cloud capabilities to the network edge to accelerate enterprise digital transformation
Google Cloud and Nokia today announced a global, strategic partnership to bring new solutions for communications service providers (CSPs) that modernize their network infrastructures, build on a cloud-native 5G Core, and develop the network edge as a business services platform for enterprises.
The agreement, which comes three months after Nokia said it will move its on-premises IT infrastructure to Google Cloud, blends multiple technology platforms and services into a more comprehensive and integrated offering, according to the companies.
Google Cloud and Nokia will work closely to validate, optimize and evolve cloud-native network functions, and the two companies will also co-innovate new solutions that will help CSPs deliver 5G connectivity and services at scale.
Today, global CSPs can unlock new monetization opportunities by driving 5G connectivity and advanced services to enterprise customers at the network edge, to deliver new, digital experiences for consumers. Google Cloud and Nokia will create solutions that bring together Nokia’s 5G operations services and networking capabilities with Google Cloud’s leading technologies in AI, ML and analytics, running on Anthos as a platform for shifting workloads to the network edge, across public and private clouds.
As part of this collaboration, Nokia is supplying its voice core, cloud packet core, network exposure function, data management, signaling, and 5G core. This includes Nokia’s IMPACT IoT Connected Device Platform, which enables automated, zero-touch activation and allows for remote management of IoT devices, as well as Nokia’s Converged Charging solution provides real-time rating and charging capabilities that enable CSPs to capture new revenue opportunities from the 5G economy.
Google Cloud’s Anthos for Telecom will serve as the platform for deploying applications, enabling CSPs to build an ecosystem of services that are deployable anywhere, from the edge of the network, to public clouds, private clouds and carrier networks. Anthos is an open hybrid and multi-cloud application platform that offers telecommunications companies the flexibility to modernize existing applications, build new ones and securely run them on-premises and across multiple clouds.
By delivering cloud-native applications at the edge, businesses can benefit from lower latency and reduce the need for costly, on-site infrastructure, enabling them to transform their businesses in industries such as smart retail, connected manufacturing and digital consumer experiences.
In general, Google Cloud is focusing on three strategic areas to support telecommunications companies:
- Helping telecommunications companies monetize 5G as a business services platform.
- Empowering them to better engage their customers through data-driven experiences.
- Assisting them in improving operational efficiencies across core telecom systems.
In December, Google Cloud announced an ecosystem of over 30 partners that will serve more than 200 partner applications at the edge. Google Cloud has more than 2,000 locations globally where it can help service providers monetize their infrastructures.
Adding Nokia as another partner will help Google Cloud modernize telcos’ infrastructures by tapping into 5G connectivity as well as cloud-native applications and capabilities from the 5G network core to the edge.
Note yet again, there are no standards for 5G Core, let alone a cloud-native version. In the References below, we list 5G cloud-native core white papers from Nokia, Ericsson and Samsung.
Supporting Quotes:
“Through our partnership we can give customers choice and simplicity in interfacing with Google Cloud and Nokia systems. In many cases, we can provide pre-integrated solutions from Google Cloud and Nokia, which may offer a time-to-market advantage and a more seamless path to 5G for communications service providers,” a Google Cloud spokesperson wrote in response to questions. “At a high level, our approach to supporting the telecommunications industry will span multiple partnerships, geographies, and technology layers,” the Google Cloud spokesperson said.
George Nazi, VP, Telco, Media & Entertainment Industry Solutions at Google Cloud, said: “Communications service providers have a tremendous opportunity ahead of them to support businesses’ digital transformations at the network edge through both 5G connectivity and cloud-native applications and capabilities. Doing so requires modernized infrastructure, built for a cloud-native 5G core, and we’re proud to partner with Nokia to help the telecommunications industry expand and support these customers.”
Alex Choi, SVP, Strategy and Technology Innovation at Deutsche Telekom, said: “Deutsche Telekom is on a journey to transform to a new open, disaggregated and cloud-native infrastructure with an automated production model. We are therefore excited to see two innovative organizations like Nokia and Google Cloud joining forces to accelerate ecosystem innovation across critical areas like Open RAN and virtual RAN and the cloud-native 5G Core.”
Neil McRae, Chief Architect at BT Group, said: “BT is deploying cloud-native technologies across our platform, creating value for our customers and ensuring they get the best network experience in every aspect of their daily lives, whether at home, on the move or at work. The network and the services that our customers depend upon in their everyday lives can be further enhanced in terms of scalability, reliability, and experience with cloud-native technologies. BT is excited that Google and Nokia are innovating together to help accelerate new, on-demand edge and convergence solutions, creating new possibilities for consumers and enterprises.”
Ron Haberman, CTO of Cloud and Network Services at Nokia, said: “In the past five years, the telecom industry has evolved from physical appliances to virtual network functions and now cloud-native solutions. Nokia is excited to work with Google Cloud in service of our customers, both CSPs and enterprise, to provide choice and freedom to run workloads on premise and in the public cloud. Cloud-native network functions and automation will enable new agility and use-cases in the 5G era.”
References:
https://www.sdxcentral.com/articles/news/nokia-argues-cloud-native-is-essential-to-5g-core/2019/11/
Google Cloud’s telecommunications Strategy
https://www.ericsson.com/en/digital-services/core-network-automation/guide
Dell CTO: Enterprise use cases will dominate 5G public and private deployment models
The 5G telecom ecosystem will shift to become more enterprise driven from consumer-focused in 2021 and the fundamental architecture become software-defined, said John Roese, global chief technology officer, Dell Technologies.
“In 2021, we will have true standalone 5G materialize and it will include advanced features. (This author strongly disagrees as there are no standards for 5G SA and there will be no roaming or portability as a result.).
Enterprise use cases will dominate the technical landscape of 5G for both public and private deployment models. (We agree on that point). The fundamental architecture of 5G (core network) will move away from the telco and shift to a cloud (native) and IT architecture, which will be open and software-defined for the first time,” said Roese recently while briefing the journalists on the technology trends this year. The Dell senior executive said 5G infrastructure ‘needs to be developed in a very different way with software defined architecture.’
5G SA and Non Stand Alone Core Network
Roese said in 2021 and 2022 the industry would see the shift to building edge computing platforms that can run multiple edge experiences and software-defined services on them to solve the edge proliferation problem. “Edge platforms will become major new areas of on-premise IT capacity delivered as both product and as-a-service,” he added.
Dell said 2021 will also be a prominent year for the quantum computing and semiconductor ecosystem. “This is the year that will enable broader software development ecosystems to experiment with quantum computing. This is the first year that a computer scientist with no prior access to quantum computing can go into a simulator and start to learn the language of quantum,” said Roese.
According to the company, the industry will move from the era of homogeneous compute to an era of heterogeneous compute. This means that homogenous compute like x86 will be highly augmented with domain specific architectures (Accelerators), and semiconductor ecosystems are being reorganized for this domain.
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