FCC’s auction of 24 GHz spectrum attracts >$1.5B in bids after 26 rounds; IMT 2020 frequencies?
Bids in the Federal Communications Commission’s (FCC’s) 24 GHz millimeter-wave spectrum auction 102 have passed $1.5 billion after 26 rounds. The figure is more than double the the $704 million collected during the recent sale of 28 GHz spectrum.
Bidding has been from AT&T, T-Mobile US, Verizon and Sprint (bidding as ATI Sub LLC); U.S. Cellular; Dish Network, bidding as Crestone Wireless; Starry Spectrum Holdings and Windstream Communications (which recently filed for bankruptcy protection in the wake of a court case). There are a total of 38 qualified bidders.
Auction 102 is the FCC’s second auction of Upper Microwave Flexible Use Service (UMFUS) licenses (see below for information on auction 1010). Auction 102 offers 2,909 licenses in the 24 GHz band. The lower segment of the 24 GHz band (24.25–24.45 GHz) will be licensed as two 100-megahertz blocks, and the upper segment (24.75–25.25 GHz) will be licensed as five 100-megahertz blocks. Those frequencies are being considered for the IMT 2020 5G radio aspects standard and will be determined at the ITU-R WRC-19 meeting this fall (details in Editor’s Note below).
Three rounds of bidding are being held each day at this point in the auction. The clock auction format begins with a “clock phase” (the current auction phase) which lets participants bid on generic blocks in each Partial Economic Area in successive bidding rounds, followed by an “assignment phase” that allows the winners of the generic blocks to bid for frequency-specific license assignments. The clock phase continues, with prices automatically increasing each round, until bidders’ demand for licenses at a certain price matches the supply — and at that point, the bidders who have indicated they are willing to pay the final clock price for a license will be considered winners and the assignment phase can begin.
The most hotly contested licenses are those covering New York City and Los Angeles, California. New York City metropolitan licenses are dominating the bidding: four bids for NYC licenses in the upper portion of the band are currently above $30 million. One of those is at $41.1 million, the largest bid of the auction thus far. The most expensive bid for a Los Angeles license, also in the upper portion of the band, is up to $31.6 million, with other bids on LA licenses as high as $28.7 million and $26.1 million.
Much of the auction process is secretive—there are anti-collusion rules and bidders can’t talk to one another, for example. The FCC isn’t releasing the names of the winners of the 28-GHz or 24-GHz auctions until both have been concluded.
…………………………………………………………………………………………………………………………………………………………………………………….
The FCC is making a total of 1.55 gigahertz of spectrum available through auctions 101 (which concluded in late January after raising $702 million) and 102. The agency plans to hold three more mmWave auctions during 2019, covering spectrum at 37 GHz, 39 GHz and 47 GHz. Although the FCC has usually makes winning bidders public shortly after the close of an auction, the winning bidders from Auction 101 will not be publicly named until after the close of Auction 102.
References:
https://auctiondata.fcc.gov/public/projects/auction102
https://www.rcrwireless.com/20190325/policy/24-ghz-auction-hits-1-4-billion
……………………………………………………………………………………………………………..
Update on FCC Auction 103:
Analysis and results of FCC Auction 103 for 5G mmWave Spectrum
Deputy PM: 5G Crucial to Vietnam’s Development; Viettel installs Vietnam’s first 5G base stations in Hanoi
Vietnam’s deputy prime minister Vu Duc Dam has thrown his support behind the adoption of 5G in the nation, stating that 5G will be crucial to Vietnam’s development.
During the recent ASEAN Conference on 5G, the deputy prime minister acknowledged that the government will need to proactively support businesses to ensure they are more confident in investing in 5G, according to Nhan Dan Online, the official newsletter of the Communist Party of Vietnam.
Deputy Prime Minister Vu Duc Dam has stated that 5G, the next-generation of mobile communications standard, is crucially important to the development of Vietnam
…………………………………………………………………………………………………………………………………………………………………………………………………………………………………………
During the conference, Dam said the technology will not only provide major speeds improvements but involve changes in global production methods. He suggested that participants use the Vietnam-organized conference to discuss the pathway to 5G development in the ASEAN region.
Vietnam aims to become one of the world’s early adopters of 5G. Several Vietnamese operators have been allocated licenses to trial the technology in Hanoi and Ho Chi Minh City ahead of a commercial launch.
Also at the event, Vietnam’s ICT minister Nguyen Manh Hung also stated that 5G will be the most vital part of the infrastructure required for the future digital economy. He told the delegates at the conference that Vietnam will be one of the first countries in the world to roll out the next-generation of wireless technology. Several local carriers have been licensed to trial 5G in Hanoi and Ho Chi Minh City, Minister Hung added.
Update (April 10, 2019):
Viettel deploys Vietnam’s first 5G base stations
Vietnamese military-run operator Viettel has installed Vietnam’s first 5G base stations in Hanoi ahead of planned 5G trials.
The operator has deployed three test 5G base stations at various offices, and expects to switch them on for trials in early May, state news agency Nhan Dan Online reported.
Viettel plans to test 70 5G base stations in Hanoi and Ho Chi Minh City in June in preparation for a large-scale deployment, the report states. The military run telecom group is targeting a 5G commercial launch in 2020. Viettel is taking the lead in the deployment of the technology in the market.
Military-run telecommunications group Viettel has installed the first base transceiver station (BTS) of fifth generation (5G) in Vietnam on the roof of the Viettel Centre in Hoan Kiem District.
……………………………………………………………………………………………………………………………………………………………………………………………………………………………
At the recent ASEAN Conference on 5G in Vietnam, minister of information and communications Nguyen Manh Hung said 5G represents an opportunity for Vietnam to change its global rankings by stimulating growth in the digital economy.
…………………………………………………………………………………………………………………………………………………………………………………………………………………………….
Update: April 26, 2018:
Indochina Telecom on Thursday launched Vietnam’s first mobile virtual network operator (MVNO) ITelecom, increasing the number of telecom service providers in the Southeast Asian country to six.
The five veteran mobile network operators in Vietnam include Vinaphone, MobiFone, Viettel, Vietnamobile, and G-tel.
An MVNO is a wireless communications service provider that does not own the wireless network infrastructure over which it provides the service to its customers.
Newcomer ITelecom obtained access to network services from telecom market leader Vinaphone under a business agreement to offer its own network service.
Prefixing phone numbers on its network with 087, ITelecom says it is committed to offering flexible telecom services and stable quality at reasonable costs.
The company’s deputy general director Luu Anh Son said the virtual model helps save considerable costs, time, and effort whilst still ensuring quality for its users.
For Vinaphone, the agreement offers an opportunity to resell voice and data packages and share network operating costs, allowing the telecom giant to ultimately add to its bottom line.
Indochina Telecom’s services are currently offered to workers in industrial parks in nine provinces and cities including Hanoi, Thai Nguyen, Vinh Phuc, Bac Giang, Bac Ninh in northern Vietnam, and Binh Duong, Ho Chi Minh City, Long An and Dong Nai in the south.
The operator’s most popular package allows users to enjoy all under-20-minute calls within its and Vinaphone’s networks, as well as 30-minute calls to other networks and 3GB of daily Internet data at a cost of VND77,000 (US$3.3) a month. ITelecom has yet to establish its own system of representative offices in Vietnam, instead relying on wholesale and authorized agents to connect with customers – a system which could potentially inconvenience customers in need of customer or tech support.
To overcome this drawback, the operator plans to ink agreements with other networks to contract out such services at reasonable prices, while providing a variety of packages to different groups and user segments, according to Son. Established in 2008, Indochina Telecom has more than a decade of experience in providing basic mobile network and Internet services across Vietnam.
GSA announces 5G Device Database and 5G Ecosystem Report +Hadden Telecoms
The Global mobile Suppliers Association (GSA) today launched the industry’s first database tracking worldwide 5G devices. Part of the GSA Analyser for Mobile Broadband Devices (GAMBoD) database, the new 5G device tracking and reporting represents an important milestone for the 5G ecosystem as it moves from service trials and prototype user equipment to commercially available services and devices. 5G Ecosystem Report containing summary statistics can be downloaded here.
The report details that as of mid-March 2019 GSA had identified 23 vendors who have confirmed the availability of forthcoming 5G devices with 33 different devices including regional variants. There were seven announced 5G device form factors: (phones, hotspots, indoor CPE, outdoor CPE, modules, Snap-On dongles, adapters and USB terminals). Breakdown by 5G form factor:
- 12 phones (plus regional variants)
- 5 hotspots (plus regional variants)
- 8 CPE devices (indoor and outdoor)
- 5 modules
- 2 snap-on dongles / adapters
- 1 USB terminal
GSA also confirms that 5G chipsets have been announced or are available from five vendors (Huawei, Intel, Mediatek, Qualcomm and Samsung).
Editor’s Note:
Huawei and Samsung use their 5G chip sets for their products and so far have not announced they would sell them on the merchant market.
………………………………………………………………………………………………………………………………………………………………………………
Other potential, but – as far as GSA has been able to determine – not officially announced, 5G devices, include:
-
- Netgear Nighthawk M2 5G Hotspot – reported by secondary sources as planned for Telstra’s network
- Samsung Galaxy Note 10 5G – secondary source confirmation only, based on analysis of Galaxy Note 10 Kernel code.
- In addition, earlier versions of the Huawei indoor CPE containing the Balong 5G01 chipset are, according to the vendor, still being used in selected pre-commercial trials.
This is the latest component of the GSA Analyser for Mobile Broadband Devices (GAMBoD) database, a tool designed to help industry stakeholders keep track of all this stuff. Its launch comes on the same day at the publication of the latest 5G Market Reality Check from Hadden Telecoms.
“Operators globally are preparing for the large-scale introduction of 5G, the first services have launched, and the devices ecosystem is rapidly building and poised for the imminent scale availability of a range of smartphone models,” said Hadden. “Dozens more operators are expected to launch their respective 5G services in the coming 12 months.”
211 operators are investing in 5G in 87 countries – List
Operators investing in 5G are at a variety of stages, ranging from network deployments, to technology testing, demonstrations and pilot trials. 15 operators have commercially launched 5G services, including Telstra and Optus in Australia, which are offering fixed wireless 5G services on the 3.6-GHz band. Vodafone Australia and the market’s national broadband network operator NBN Co are also investing in 5G.
Download the full list as of 24th March 2019: Operator-5G-investments-240319.pdf
References:
http://telecoms.com/496540/5g-has-already-yielded-12-phones-and-five-chipset-vendors-gsa/
Ericsson: MOU with SK Telecom for 5G SA core network; KT commercial contract for 5G roll-out in April
SK Telecom (SKT) and Ericsson have signed a MOU agreement to collaborate on research and development of 5G standalone (SA) core network technology and architecture. The three year agreement focuses on potential enhancements and optimization enabled by cloud native micro-services based design principles. The collaboration is directed at creating a more agile and programmable 5G standalone core network architecture capable of efficiently managing growth through automation and more simplified operations.
“After the successful launch of 5G [non-standalone] network, SK Telecom is preparing to migrate towards 5G [standalone – no LTE dependence] networks to provide the latest and greatest technology and services to its customers,” SK Telecom SVP and head of 5GX Labs Jong-kwan Park said.
“This joint collaboration with Ericsson on the next generation 5G Standalone Core and cloud native principles will not only enable us to introduce new services faster while at the same time improve our operational efficiency but also support higher availability through simplified operation.”
Ericsson head of packet core Peo Lehto added that cloud native micro-services architecture promises to deliver higher degrees of automation and availability, more predictable performance and more robust operations for next-generation mobile networks.
“This will relieve requirements on the infrastructure by allowing better handling of multiple failures, better infrastructure utilization with more flexible and granular scaling, as well as increased rate of innovation with independent life cycles and in-service software upgrade for each service,” he said.
“Ericsson and SKT have been cooperating closely for many years around 5G innovation. With the new MoU we can accelerate the necessary evolution of 5G core networks the profitable introduction of 5G-based services and use cases.”
A three-year Memorandum of Understanding (MoU) between the companies focuses on possible enhancements and optimization enabled by cloud native micro-services-based principles. The MoU comes as increasing focus is being placed on the need for more agile and programmable 5G standalone core network that efficiently manage growth with automation and simplified operations.
………………………………………………………………………………………………………………………………………………………..
Separately, Ericsson has secured a deal from South Korea’s largest telecom firm KT to implement its forthcoming 5G network as South Korea wireless network operators target 5G launch in April 2019. In addition to 3GPP Release 15 “5G New Radio” hardware and software for KT’s 3.5 GHz Non-Standalone network, Ericsson is facilitating KT to stimulate the Internet of Things (IoT) and Industry 4.0 opportunities to local enterprises on a global scale. In addition to immersive media, KT’s 5G commercialization use case plans covers: smart factories; safety; drones; and connected vehicles.
Many believe that the extensive deployment of 5G networks will boost the adoption of IoT devices that require real time control and low latency. As 5G accelerates the digital transformation in many industries, enabling new use cases in areas such as IoT, automation, transport and Big Data, Ericsson is poised to benefit from favorable growth dynamics. The company is investing heavily in its competitive 5G-ready portfolio to enable customers to seamlessly migrate to 5G.
Jinho Choi, Vice President, Access Network Design, KT, says: “Having worked successfully with Ericsson on 4G LTE, we are pleased to continue that partnership to make our 5G ambitions a reality with Ericsson’s leading 5G technology.
“Korea is one of the most competitive and technology-advanced markets in the world. By taking a global lead to enable nationwide commercial 5G services through commercially available 5G smartphones, KT is demonstrating our commitment to our customers and showing how we can drive a global 5G ecosystem where Korea plays a key role.”
Patrick Johansson, Head of Ericsson Korea, says: “We’ve worked with KT for many years to bring the very best mobile user experiences to its customers. Notably on 5G, we worked closely together to show the world what 5G could do during a major global winter sports event in 2018.
“With 5G we aim to help KT to take their customers’ experiences to new levels, whether through enhanced mobile broadband for mobile subscribers, or helping to make national and global IoT and Industry 4.0 opportunities a reality for enterprises and industries.”
References:
https://www.ericsson.com/ci/en/news/2019/2/ericsson-and-sk-telecom-team-up-on-cloud-native-5g-core
https://www.ericsson.com/en/press-releases/2019/3/ericsson-wins-5g-commercial-deal-with-kt
https://www.telecomasia.net/content/skt-ericsson-team-cloud-native-5g-core
China Mobile reports 2018 net profit of $17.58 billion; 5G accomplishments and 2019 plans
2018 Financial Overview:
On March 20, 2019, China Mobile (the world’s largest wireless carrier by subscribers and revenue) reported a 3.1% increase in net profit for 2018 to 117.78 billion yuan ($17.58 billion). The company focused on reducing costs and increasing operational efficiency. Telecommunications service revenue fell a reported 0.4% but grew 3.7% in comparable terms to 670.9 billion yuan. China Mobile’s net profit was aided by the listing of the company’s tower division China Tower in August last year.
2018 Highlights:
- China Mobile reported a 4.3% increase in its total customer base for the year to 925 million, of which 713 million are 4G customers – a 9.7% increase from 2017.
- However, mobile ARPU fell 8% to 53.1 yuan as a result of strong competition.
- Total wireline broadband subscribers increased by 39% to 157 million, of which 147 million were household broadband customers. Household broadband blended ARPU grew 3.2% to 34.4 yuan.
- The company’s four growth engines are: personal mobile market, home broadband market, corporate market, emerging business
- IoT revenue +40.2% to RMB7.53 bil
- ICT, Cloud Computing, Big Data Revenue Revenue =RMB4.19 bil which was +75.3%
- Boasted 2.41 mil 4G base stations with an industry-leading 4G network coverage capability
- Realized NB-IoT continuous coverage in areas at township level and above across China
- Achieved household broadband access capability of ≥100Mbps.
- More efficient deployment of CDN edge nodes resulted in ongoing enhancements to customer perception
- Maintained a backbone network with a further enhanced transmission and loading capability.
- Performance of international submarine cables, cross-border terrestrial cables and PoPs was substantially lifted
“2018 was a challenging year for telecommunications operators. Competition amongst peers changed in characteristics as products and services have become homogenized while cross-sector challenges have intensified. The value of traditional telecommunications business rapidly diminished, coupled with multiple challenges from a complex and rapidly-changing policy environment,” China Mobile chairman Yang Jie said.
“In order to counter market competition, overcome the major obstacles in the ongoing reforms and enhance management, we continued to encourage everyone across the Company to take the ‘Big Connectivity’ strategy even further and implement the integrated development of the four growth engines.”
2018 5G Accomplishments:
- Permitted to adopt 2.6GHz and 4.9GHz frequency bands for trials
- Network tests and application trials in 17 cities
- Developed 5G Ecology:
• 5G Joint Innovation Centre
• 5G Device Forerunner Initiative
• 5G Joint Innovation Industry Fund
2019 Goals dor 5G: Construct end-to-end network infrastructure; Promote 5G commercialization:
• Develop NSA and SA networks concurrently with SA (stand alone- no LTE) as the primary goal
• Promote 4G/5G synergistic development and expedite 4G VoLTE
• Join hands with the industry supply chain to develop devices supporting multiple modes, bands and form factors
• Share end-to-end smart technology capabilities and serve vertical industries
Work together to build an open and win-win innovative ecosystem. Promote 5G cross-industry integration:
- Culture and entertainment
- Smart transportation
- Smart city
- Smart manufacturing
- Remote healthcare
https://www.chinamobileltd.com/en/ir/webcasts/pre190321.pdf
China Mobile on 5G (from Press Release):
We will continue to conduct tests on the 5G network and perform trials on business applications to ensure the precommercial launch of 5G services this year. We aim to provide direction and leadership for 5G development, exploring suitable 5G products and business models with industry partners. To build a strong foundation for the ongoing transformation towards an intelligent network, we will speed up the pace of network upgrades and strengthen our core capabilities. The Company will expand into new retail business and strive for the large-scale development of our own branded intelligent hardware. We will build up our capabilities in key business areas and develop an open and shared innovative ecosystem. In order to realize a win-win situation, we will continue to enhance the collaborative opening-up efforts, reinforcing industrial cooperation,investment planning and international expansion.
http://mms.prnasia.com/00941/20190321/2018ARPressRelease_ENG.pdf
India delays 5G trials; Advocates “the Indian Way” within ITU-R WP 5D for IMT 2020
India Delays 5G Trials:
5G technology trials in India are now expected to begin by the end of the current calendar year or early next year, according to a recently-constituted committee looking into the 5G field trial initiative.
“5G trials may happen towards the end of this year or early next year. Early deployments may happen in the second or third quarter of 2020,” Abhay Karandikar, director, IIT Kanpur and chairman of the recently set up committee to look into SG spectrum for trials told ETT.
The much-anticipated 5G field trials have hit a policy roadblock with the department of telecom (DoT) wireless planning and coordination wing (WPC) averse to allocating airwaves beyond 90 days, which according to industry, would not serve any purpose.
March 29, 2919 Update from Prof AJ Paulraj:
“Government of India has confirmed that several statements in the article are incorrect. 5G trials are this year on and WPC has not created any hurdles.”
That implies the first reference cited (see below) is inaccurate.
………………………………………………………………………………………………………………………………………………………………………………………………………………………………….
Prof. Karandikar said that the industry needs to get trial spectrum for a reasonable duration or for at least one year with a minimum cost to telecom carriers for carrying out 5G trials. “Current mechanisms of experimental license by DoT require modifications in terms of scope and duration for enabling telecom service providers and industry to undertake the 5G trial at the network level,” he said.
On February 25, the department has formed a committee headed by Karandikar with representation from the academia, industry and the government, to make recommendations related to licensing for carrying out 5G pilots, and also asked for the quantum, size, price and other aspects for offering experimental spectrum. The 5G India Forum will serve as a strategic national initiative which concerns all stakeholders, private and public, small and large, to meet the challenge of making 5G a reality in India, at timelines aligning with the rest of world. 5G India Forum is a collaborative body under the aegis of COAI.
- Objective: This 5G India forum aims to become the leading force in the development of next generation communications and will enable synergizing national efforts and will play a significant role in shaping the strategic, commercial and regulatory development of the 5G ecosystem in India.
Earlier in 2018, the Indian government has asked telecom service providers— Vodafone Idea, Bharti Airtel and Reliance Jio— to partner with telecom gear makers such as Cisco, Samsung, Ericsson and Nokia, and showcase India-specific 5G use cases by early 2019.
The department has so far excluded Chinese telecom equipment firm ZTE from awarding intent letter to participate in trials. Shenzhen-based Huawei said it was still awaiting clarity from the government to conduct 5G trials and could deploy a 5G network within the three week’s time after the allocation of trial radiowaves.
Karandikar, one of the sector regulator’s advisers is also a member of the 5G high-level forum which under the noted scientist AJ Paulraj is working on to prepare a roadmap for 5G rollout in the country in tandem with some of the matured markets worldwide. In September 2018, the forum submitted its recommendations to the government which has constituted several implementation-level committees or working groups to develop a wider 5G deployment strategy.
References:
https://www.coai.com/5g_india_forum
………………………………………………………………………………………………………………………………………………………………………………………………………………………
ITU-R WP5D split on the way forward for IMT 2020 specifications:
At the February 2019 ITU-R WP5D meeting 31bis, TSDSI (India’s telecom standards body) submitted updated information related to their proposal of candidate IMT-2020 radio interfaces. The TDSI contribution was reviewed and the respective IMT-2020 documents were revised accordingly.
This meeting received and reviewed a number of input contributions on “Process and use of the Global Core Specification (GCS), references, and related certifications in conjunction with Recommendation ITU-R M.[IMT‑2020.SPECS].” There continues to be two diverse philosophies on how to proceed with the document – one desiring to significantly alter the process to support specific national needs (e.g. India) in the transposition phase of the process and the other demonstrating how the same objective could be accomplished with the existing process remaining unaltered in its scope, steps, and procedures.
The two views are Indian Way Forward (provided by TSDSI) and Summary of a Proposed IMT-2020 VVV Way Forward (AT&T v3 2-14-19) (provided by AT&T).
The Indian Way courtesy of TSDSI:
- India believes that, the process works well ONLY for countries with strong industry presence in 3GPP
- Most developing countries have no way to influence the technology they consume
- Much of the value transactions in standardization are abrogated to external bodies
- That relegates most of the developing countries to be consumers
What the ITU-R IMT 2020 standardization process should enable:
- India believes the process should enable developing countries to take 3GPP (or other GCS) as the base specification.
- Then provide enhancements and innovations to the base specifications, depending on local use cases.
- TDSI believes it is possible to preserve interoperability/international roaming, while allowing for these regional enhancements
- That is not enabled by the current process
TSDSI Proposal for ITU-R IMT-2020 Standard:
- Reference to Base Specification – Version 1.
- Delta-DIS Version 1. (for national options)
References:
TSDSI’s Initial Proposal on candidate RIT/SRIT for IMT 2020 Accepted
AT&T CEO Talks up 5G: Deploying small cells, China/Huawei – Security or Critical U.S. Infrastructure Risk?
AT&T CEO Randall Stephenson said China still lags behind the U.S. in the 5G race (for dubious reasons- see comment in box below this article), but slow cell site permitting processes in the U.S. and heavy Chinese investment, coupled with Huawei’s 5G dominance, could change the situation. Also, European carriers that use Huawei equipment in 4G networks are unable to switch suppliers for 5G networks because “Huawei is not allowing interoperability to 5G-— meaning if you are 4G, you are stuck with Huawei for 5G,” said Stephenson during an interview with Carlisle Group co-founder David Rubenstein at the Economic Club in Washington DC.
“When the Europeans say we got a problem — that’s their problem. They really don’t have an option to go to somebody else…To me, the biggest risk is not that the Chinese government might listen in on our phone conversations or mine our data some how if we use their equipment. That’s not the issue,” he said.
AT&T’s CEO is very optimistic about 5G technology, claiming it “will be the most transformative of all the Gs … you can’t conceive all the services that 5G implies.”
But in a 5G world millions of “things” will be connected and located within a square mile. To make that possible, AT&T will deploy hundreds of thousands of small cell sites throughout the U.S. They will be placed on light poles, sides of buildings, roof tops and other structures.
According to the AT&T CEO, 5G is a more efficient technology, delivering a better smartphone user experience, but it won’t be cheaper than 4G. AT&T has not “worked out what or pricing arithmetic looks like,” Stephenson said.
Regarding 5G replacing smartphone screens with Internet video enabled smart eye glasses, Stephenson said:
We carry around these devices and they’re bigger than they should be, because there’s a lot of computing in here, there’s a lot of storage in here. When you get to 5G, all that computing, all that storage goes away — it’s back in the network. These form factors, some would say they shrink.
I say they go away. It is conceivable that we’re going to be moving into a world without screens, a world where this [points to his eye glasses] is your screen. You don’t need any more of a form factor than this, once the computing and storage requirements move out and into the network. And guys like you [waving to the TV cameras in the back] can think very differently about how you deliver your content to your customers. It becomes a delivery without screens. It’s just a totally different experience. …
AT&T is right at the very center of all this because, if you ask yourself: Five years from now, in this room, will you be consuming more or less global bandwidth. More? Who thinks more? Will you be consuming more or less premium entertainment? More? Well, I like where we are on both of those.
You can watch and listen to Stephenson’s 52 1/2 minute talk here.
References:
https://www.cnn.com/2019/03/20/business/att-randall-stephenson-5g/index.html
……………………………………………………………………………………………………………………………………………………………………….
AT&T says its leading wireless and fiber network, including investments in new technology such as 5G, will provide the network bandwidth required as customers increase engagement with premium video and emerging 4K and virtual reality content.
AT&T is now a software company: “Software is increasingly at the heart of everything we do. Whether a patent or an open source project, software is the future of AT&T. Software is our thing,” AT&T’s Mazin Gilbert wrote in a blog post.
China Telecom to accelerate 5G deployment; 100% Fiber network coverage; Gigabit fiber broadband deployment
According to its latest financial report published today, China Telecom has big plans for 5G. The report states in part:
New technologies represented by 5G and AI are integrating and evolving, enabling them to support supply-side structural reform, which will lead to a rapid expansion of potential value for digital economy. As the next generation infrastructure, 5G network will become ever more intertwined with applications and telecom operators will play an increasingly pivotal role in the information communications industry. The Company (China Telecom) will actively explore commercial applications of various new technologies, accelerate the development of operation mechanisms that are adapted for 5G, and capitalize on its advantages to promote ecological services ahead
of time.Recently, China Telecom was awarded the 3.5GHz band to conduct nationwide 5G network trials. Leveraging the advantages of the 5G mainstream frequency band and insisting on open cooperation, the Company will accelerate 5G deployment proactively and pragmatically. Persisting in a market-oriented and demand-driven approach, the Company will appropriately manage the momentum, propel the development of non-standalone (NSA) and standalone (SA) concurrently, and progressively expand the scale of network trials and the pilot project of 2B/2C applications.
In a presentation on its 2018 financial results, China Telecom noted these 5G milestones:
1. Technology:
• Published industry’s first 5G Technology White Paper
• Launched industry’s first 5G+AI handset standard
• Pioneered to accomplish 4G-5G interoperability on SA network architecture
• Pioneered to interoperate 5G SA (Stand Alone) on equipment from different vendors
2. Extensive Application Trials:
• Internet of Vehicles (IoV): 5G-based remote-controlled driving in Xiong’an and passed test
• Media convergence: Ultra-high definition 5G 4K, VR live broadcasting of gala show
• Smart city: 5G full coverage along a 28km road in city area, performing data traffic management for ultra-high definition 5G+, cloud VR and 5G smart transport
• Energy Internet: Trial on IoT electricity distribution leveraging 5G network slicing (?), performing 5G precision control on electricity distribution and usage
3. Network Capability- Prepare for flexible and agile 5G deployment with:
• Prompt assessment and modification of existing network
• Acceleration of network cloudification and intelligent upgrade
• 100MHz spectrum at 3.5GHz band, which has the world’s most developed industry chain for 5G trial
……………………………………………………………………………………………………………………………………………………….
China Telecom plans to accelerate 5G development pragmatically:
• Persistence in SA as the goal and direction, to expediate industry chain maturity and conduct scale trials in SA/NSA which is concurrently in a very early stage
• Adjust investment plan and expand trial subject to technology maturity, licensing, market competition and results of scale trial
• Actively explore network co-building and co-sharing to reduce network construction and maintenance cost
Open co-operation initiatives include:
• Promote key 5G technology researches, actively participate in formulating 5G international standards and foster end-to-end development of industry supply chains
• Collaborate with customers and business partners for innovations, enrich products and applications
• Work with industry to commence trials on smart city, autonomous driving, industrial Internet, entertainment, medical service, education, etc.
The Company has modified its R&D system to enhance the R&D capability of key technologies of strategic, pioneering and fundamental importance, such as 5G, network capability, AI, etc.
……………………………………………………………………………………………………………………………………………………………………………………………………………………
In its SEC Form 6-K the company wrote:
- Focusing on user experience, business scale expansion and value management, the Company pushed forward the construction and intelligent upgrade of its network to build up comprehensive network advantages.
- Leveraging big data analysis, we deployed dynamic capacity expansion of 4G network with precision, and further optimized in-depth coverage at key locations.
- The number of 4G base stations reached 1.38 million, effectively supporting the upgrade to VoLTE high definition voice, as well as the continuous growth of large data traffic business.
- Our fiber network now fully covers all cities and towns in the service area of the Company, enabling a leading customer experience. By leading the deployment of Gigabit fiber broadband, we established a new edge in broadband network.
- We continued to enhance our NB-IoT network, and built a whole-range speed rate IoT structure, which combines high, medium and low speeds, supporting further expansion in vertical industries.
- By pushing forward cloud-network integration at full throttle, we continued to optimize our nationwide deployment of cloud resources and backbone network coverage, resulting in the establishment of a cloud-led network.
- By introducing new technologies such as Software-Defined Networking (SDN) and Network Functions Virtualization (NFV), the Company accelerated the re-constitution of its networks, and rolled out scale promotion of intelligent self-selecting bandwidth network products for government and enterprise customers as well as home gateway products based on SDN technology, which allows our network products to be activated within minutes.
- We also launched a VoLTE virtual IP Multimedia Subsystem (vIMS) core network with software and hardware decoupling, facilitating the progress of cloudification and virtualization. This significantly strengthened our competitiveness and differentiation in the cloud market, while laying a foundation for 5G network cloudification in the future.
- The Company proactively contributed to the formulation of international standards for 5G technologies and conducted large-scale 5G network trial runs in a number of locations.
- We achieved some preliminary progress in areas such as 5G voice call, 4G/5G interoperability, and interoperability between (pre-standard 5G) equipment, among others.
- By supporting the Ultra HD Live broadcast for CCTV’s 2019 Spring Festival Evening Gala with “5G+4K” and “5G+VR” solutions, we took an important step towards the successful accomplishment of enhanced mobile broadband (eMBB) application scenarios.
- The Company also actively explored applications for other vertical industries, such as 5G autonomous driving bus, smart water treatment and mobile remote medical service.
………………………………………………………………………………………………………………………………………………………………………………
China Telecom’s CAPEX is expected to increase 4% this year, to roughly RMB78 billion ($11.6 billion), after dropping 7.9% in 2018. That will include a 21% increase in spending on “information and application services,” to about RMB10.5 billion ($1.56 billion), as China Telecom prepares for its 5G future.
…………………………………………………………………………………………………………………………………………………………………………………….
In a paper published last August, consulting company Deloitte said China had outspent the US on 5G-supporting infrastructure by around $24 billion since 2015. Last year, the 1.9 million mobile sites across China worked out at 14.1 for every 10,000 people. With just 200,000 sites, the US had an equivalent ratio of just 4.7, according to Deloitte. Catching up with China in 5G may be “near impossible” for the Americans, Deloitte said in its report which we summarized for the IEEE Techblog.
In a recent Lightreading.com blog post, Iain Morris wrote:
With its huge population and model of state capitalism, China could be a fertile testing ground for new 5G applications. China Telecom alone had a staggering 303 million mobile customers at the end of last year — an increase of 53 million on the number in 2017 — including 242 million on 4G networks. Revenues were up 3%, to RMB377.1 billion ($56.2 billion), thanks to customer growth, and net profit rose 14%, to RMB21.2 billion ($3.16 billion).
Seeking advantage in AI, China’s government will undoubtedly look for support to a such a large, financially stable organization, with its vast reserves of customer data and stake in 5G. Demographics and democracy make the task much harder for US authorities worried about falling behind in the new technology arms race. Amid recent political talk of building a nationalized 5G network, the US operators may be under government pressure on a generation of mobile technology like never before.
Editor’s Note: Mr. Morris strongly asserts that China Telecom said it will be a leader in delivering 5G low latency (which will be specified in 3GPP release 16- due to be completed in 2020 and later in ITU-R IMT 2020 for ultra low latency.high reliability use case). He wrote, “China Telecom said it will be “industry leading” in latency, a signaling delay that could become a new battleground for 5G competitive advantage.” However, we have NOT found that reference to latency in any of China Telecom’s reports (see highlights above) and presentation made today (March 19, 2019).
The 5G-IMT2020 radio access network latency objectives, which Ericsson and others often say will faciliate many new applications, are specified in ITU-R M.2410-0: https://www.itu.int/dms_pub/itu-r/opb/rep/R-REP-M.2410-2017-PDF-E.pdf
The minimum requirements for user plane latency are: 4 ms for eMBB and 1 ms for URLLC assuming unloaded conditions (i.e. a single user) for small IP packets (e.g. 0 byte payload + IP header), for both downlink and uplink.
………………………………………………………………………………………………………..
There is no spec or even target for cloud network latency related to carrying 5G packets. In fact, the cloud network might not be used at all for real time control of 5G applications such as V2V or IoT
FCC to open spectrum above 95 GHz for new technologies
The Federal Communications Commission (FCC) has adopted rules to clear spectrum in the 95 GHz to 3 TeraHz frequencies for experimental use in order to ecnourage technological breakthroughs in communications. It might even set the stage for 6G and beyond. The FCC will issue experimental licenses for up to 10 years and open 21.2 GHz of spectrum in that range for testing unlicensed devices.
FCC Chairman Ajit Pai invited NYU Wireless Professor Ted Rappaport, who was instrumental in conducting ground-breaking millimeter wave research, to present his institution’s findings thus far on the opportunities afforded by the spectrum bands above 95 GHz, where “science fiction will become reality,” Rappaport told the commission.
The applications that become possible at these higher frequencies are kind of mind-blowing, he said. With so much bandwidth and wider bandwidth channels, you can start having data rates that approach the bandwidth needed to provide wireless cognition, where the computations of the human brain at those data rates could actually be sent on the fly over wireless. As such, you could have drones or robotics receive in real time the kind of perception and cognition that the human brain could do.
The conventional wisdom is that as you go higher in frequency, you get more loss. “That’s only if you use an omnidirectional antenna, the old way of doing cellular 10 and 20 years ago. When you start using directional antennas, what happens is, you actually do better as you go higher in frequency for a given power level and a given antenna physical size,” Rappaport said.
The FCC’s Spectrum Horizons First Report and Order creates a new category of experimental licenses for use of frequencies between 95 GHz and 3 THz. These licenses will give innovators the flexibility to conduct experiments lasting up to 10 years, and to more easily market equipment during the experimental period, according to the FCC.
The item also makes a total of 21.2 gigahertz of spectrum available for use by unlicensed devices. The Commission selected bands with propagation characteristics that will permit large numbers of unlicensed devices to use the spectrum, while limiting the potential for interference to existing governmental and scientific operations in the above-95 GHz bands, such as space research and atmospheric sensing.
The First Report and Order provides unprecedented opportunities for new experimental and unlicensed use in the frequencies above 95 GHz and will help ensure that the United States stays at the forefront of wireless innovation. Moreover, study of these uses could ultimately lead to further rulemaking actions and additional licensing opportunities within the Spectrum Horizons bands.
“Today, we take big steps towards making productive use of this spectrum,” Pai said in his statement. “We allocate a massive 21 gigahertz for unlicensed use and we create a new category of experimental licenses. This will give innovators strong incentives to develop new technologies using these airwaves while also protecting existing uses.”
References:
https://www.fiercewireless.com/wireless/fcc-moves-to-open-spectrum-above-95-ghz-for-new-technologies
https://venturebeat.com/2019/03/15/fcc-opens-95ghz-to-3thz-spectrum-for-6g-7g-or-whatever-is-next/
Facebook’s F16 achieves 400G effective intra DC speeds using 100GE fabric switches and 100G optics, Other Hyperscalers?
On March 14th at the 2019 OCP Summit, Omar Baldonado of Facebook (FB) announced a next-generation intra -data center (DC) fabric/topology called the F16. It has 4x the capacity of their previous DC fabric design using the same Ethernet switch ASIC and 100GE optics. FB engineers developed the F16 using mature, readily available 100G 100G CWDM4-OCP optics (contributed by FB to OCP in early 2017), which in essence gives their data centers the same desired 4x aggregate capacity increase as 400G optical link speeds, but using 100G optics and 100GE switching.
F16 is based on the same Broadcom ASIC that was the candidate for a 4x-faster 400G fabric design – Tomahawk 3 (TH3). But FB uses it differently: Instead of four multichip-based planes with 400G link speeds (radix-32 building blocks), FB uses the Broadcom TH3 ASIC to create 16 single-chip-based planes with 100G link speeds (optimal radix-128 blocks). Note that 400G optical components are not easy to buy inexpensively at Facebook’s large volumes. 400G ASICs and optics would also consume a lot more power, and power is a precious resource within any data center building. Therefore, FB built the F16 fabric out of 16 128-port 100G switches, achieving the same bandwidth as four 128-port 400G switches would.
Below are some of the primary features of the F16 (also see two illustrations below):
-Each rack is connected to 16 separate planes. With FB Wedge 100S as the top-of-rack (TOR) switch, there is 1.6T uplink bandwidth capacity and 1.6T down to the servers.
-The planes above the rack comprise sixteen 128-port 100G fabric switches (as opposed to four 128-port 400G fabric switches).
-As a new uniform building block for all infrastructure tiers of fabric, FB created a 128-port 100G fabric switch, called Minipack – a flexible, single ASIC design that uses half the power and half the space of Backpack.
-Furthermore, a single-chip system allows for easier management and operations.
Facebook F16 data center network topology
………………………………………………………………………………………………………………………………………………………………………………………………..
Multichip 400G b/sec pod fabric switch topology vs. FBs single chip (Broadcom ASIC) F16 at 100G b/sec
…………………………………………………………………………………………………………………………………………………………………………………………………..
In addition to Minipack (built by Edgecore Networks), FB also jointly developed Arista Networks’ 7368X4 switch. FB is contributing both Minipack and the Arista 7368X4 to OCP. Both switches run FBOSS – the software that binds together all FB data centers. Of course the Arista 7368X4 will also run that company’s EOS network operating system.
F16 was said to be more scalable and simpler to operate and evolve, so FB says their DCs are better equipped to handle increased intra-DC throughput for the next few years, the company said in a blog post. “We deploy early and often,” Baldonado said during his OCP 2019 session (video below). “The FB teams came together to rethink the DC network, hardware and software. The components of the new DC are F16 and HGRID as the network topology, Minipak as the new modular switch, and FBOSS software which unifies them.”
This author was very impressed with Baldonado’s presentation- excellent content and flawless delivery of the information with insights and motivation for FBs DC design methodology and testing!
References:
https://code.fb.com/data-center-engineering/f16-minipack/
………………………………………………………………………………………………………………………………….
Other Hyperscale Cloud Providers move to 400GE in their DCs?
Large hyperscale cloud providers initially championed 400 Gigabit Ethernet because of their endless thirst for networking bandwidth. Like so many other technologies that start at the highest end with the most demanding customers, the technology will eventually find its way into regular enterprise data centers. However, we’ve not seen any public announcement that it’s been deployed yet, despite its potential and promise!
Some large changes in IT and OT are driving the need to consider 400 GbE infrastructure:
- Servers are more packed in than ever. Whether it is hyper-converged, blade, modular or even just dense rack servers, the density is increasing. And every server features dual 10 Gb network interface cards or even 25 Gb.
- Network storage is moving away from Fibre Channel and toward Ethernet, increasing the demand for high-bandwidth Ethernet capabilities.
- The increase in private cloud applications and virtual desktop infrastructure puts additional demands on networks as more compute is happening at the server level instead of at the distributed endpoints.
- IoT and massive data accumulation at the edge are increasing bandwidth requirements for the network.
400 GbE can be split via a multiplexer into smaller increments with the most popular options being 2 x 200 Gb, 4 x 100 Gb or 8 x 50 Gb. At the aggregation layer, these new higher-speed connections begin to increase in bandwidth per port, we will see a reduction in port density and more simplified cabling requirements.
Yet despite these advantages, none of the U.S. based hyperscalers have announced they have deployed 400GE within their DC networks as a backbone or to connect leaf-spine fabrics. We suspect they all are using 400G for Data Center Interconnect, but don’t know what optics are used or if it’s Ethernet or OTN framing and OAM.
…………………………………………………………………………………………………………………………………………………………………….
In February, Google said it plans to spend $13 billion in 2019 to expand its data center and office footprint in the U.S. The investments include expanding the company’s presence in 14 states. The dollar figure surpasses the $9 billion the company spent on such facilities in the U.S. last year.
In the blog post, CEO Sundar Pichai wrote that Google will build new data centers or expand existing facilities in Nebraska, Nevada, Ohio, Oklahoma, South Carolina, Tennessee, Texas, and Virginia. The company will establish or expand offices in California (the Westside Pavillion and the Spruce Goose Hangar), Chicago, Massachusetts, New York (the Google Hudson Square campus), Texas, Virginia, Washington, and Wisconsin. Pichai predicts the activity will create more than 10,000 new construction jobs in Nebraska, Nevada, Ohio, Texas, Oklahoma, South Carolina, and Virginia. The expansion plans will put Google facilities in 24 states, including data centers in 13 communities. Yet there is no mention of what data networking technology or speed the company will use in its expanded DCs.
I believe Google is still designing all their own IT hardware (compute servers, storage equipment, switch/routers, Data Center Interconnect gear other than the PHY layer transponders). They announced design of many AI processor chips that presumably go into their IT equipment which they use internally but don’t sell to anyone else. So they don’t appear to be using any OCP specified open source hardware. That’s in harmony with Amazon AWS, but in contrast to Microsoft Azure which actively participates in OCP with its open sourced SONIC now running on over 68 different hardware platforms.
It’s no secret that Google has built its own Internet infrastructure since 2004 from commodity components, resulting in nimble, software-defined data centers. The resulting hierarchical mesh design is standard across all its data centers. The hardware is dominated by Google-designed custom servers and Jupiter, the switch Google introduced in 2012. With its economies of scale, Google contracts directly with manufactures to get the best deals.Google’s servers and networking software run a hardened version of the Linux open source operating system. Individual programs have been written in-house.