NFIC Conference at SCU May 30, 2018 3PM-10PM: Accelerating Smart and Connected Communities

The joint IEEE-NATEA conference on an emerging technology is aimed to provide IEEE and NATEA members with an inexpensive solid overview of a technology that may affect their work and careers in the near future.

Co-organized initially by IEEE Computer Society Silicon Valley Chapter and NATEA in 1999, the New Frontiers in Computing Conference aims to provide computer and engineering professionals with enough technical information on a developing field to make informed decisions as to its role in their professional careers. NFIC strives to make all this accessible through an inexpensive one-day conference on emerging technologies such as Cloud Computing, Nanotechnology, Multi Core Processors and RFID.

Innovation in edge cloud and increased automation of technologies drive urban agglomeration to meet our lifestyle demands. Through keynotes, panelists, and presentations, this conference provides a means to enhance your understanding of the problems and solutions that are at trial in communities and the workplace.

The conference will address the innovation in edge cloud and the increased automation of associated technologies that are driving urban agglomeration to meet our lifestyle demands. In addition, we will explore how these technologies are being used in:

-Mobile Edge Computing with Distributed Cloud

-Smart Devices and Gateways

-Location-Based Applications

At the end of this conference, we hope you are equipped with the knowledge and tools to collaborate with your communities. Most importantly, we hope that you will carry forth the vision of bringing cutting-edge technologies and innovations to ensure that all benefit from the improved standards of living that smart and connected communities offer.

More info at:

https://ieee-nfic.org/program/

https://ieee-nfic.org

Dell’Oro: Market for disaggregated WDM systems increased 142% YoY in 1Q-2018

A new report from market research firm Dell’Oro Group states the market for disaggregated WDM platforms increased at a 142% year-over-year (YoY) growth in sales in the first quarter of this year.  This high growth was driven by the adoption of disaggregated WDM systems expanding beyond web-scale companies and data center interconnect (DCI).   

“Small form factor, disaggregated WDM systems were developed for the hyperscalers,” said Jimmy Yu, Vice President at Dell’Oro Group. “And for a long period of time, they were the only large purchasers. However, now we see a growing number of buyers that include cable operators and wholesale carriers.  We think this is just the start of a good thing, and expect demand for these disaggregated systems will continue to grow at a hyper-scale rate,” added Yu.

Disaggregated WDM systems reached an annualized revenue run-rate of $800 million in the first three months of this year and Dell’Oro projects the run rate will exceed $925 million for full-year 2018. Ciena and Infinera currently have enjoyed the most success in this niche, with a combined market share of approximately 60% for the trailing four quarters ending in 1Q-2018.

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Author’s Note:  The move towards disaggregated network equipment started in the Open Compute Project (OCP) Networking and Telco groups.  It’s now being propelled forward by the the Telecom Infra Project (TIP) which aims to create greater innovation and flexibility through disaggregation of traditional (vendor specific/proprietary) network equipment.  TIP is also  attempting to disaggregate optical line terminal equipment (e.g. OLT) and transmission systems such as those that use mmWave frequencies.  We first wrote about this disaggregation mega-trend almost three years ago in this article.

Here’s a schematic of an open line system (OLS), which allow transponders from many different suppliers to share a single line system:

Figure 1: Open Line System

                                                                       Figure courtesy of Infinera

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Dell’Oro Group’s “Optical Transport Quarterly Report” provides tables stating manufacturers’ revenue, average selling prices, and unit shipments (by speed, including 40 Gbps, 100 Gbps, 200 Gbps, and 400 Gbps). The report tracks DWDM long-haul terrestrial, WDM metro, multiservice multiplexers (SONET/SDH), optical switches, optical packet platforms, and data center interconnect (metro and long haul).

To purchase this report, call Daisy Kwok at +1.650.622.9400 x227 or email [email protected].

About Dell’Oro Group
Dell’Oro Group is a market research firm that specializes in strategic competitive analysis in the telecommunications, networks, and data center IT markets.  Our firm provides in-depth quantitative data and qualitative analysis to facilitate critical, fact-based business decisions.  For more information, contact Dell’Oro Group at +1.650.622.9400 or visit www.delloro.com.

 

Ericsson’s Deliverables and Take-aways from IoT World 2018 & Private Briefing

Ericsson is one of the top three wireless network equipment companies in the world (they were #1 until Huawei took that coveted spot).  Approximately 40% of the world’s mobile traffic is carried over Ericsson networks.  The company has customers in 182 countries and offers comprehensive industry solutions ranging from Cloud services and Mobile Broadband to Network Design and Optimization.  Ericcson also has one of the most compelling IoT platforms in their IoT Accelerator, which we described earlier this year.

IoT platform ecosystem

Image above courtesy of Ericsson

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Ericsson had a huge presence at IoT World 2018 with an impressive exhibit floor booth, a Wednesday private briefing session at their Santa Clara, CA location and three presentations at IoT World 2018 conference sessions.

I attended the private briefing at Ericsson- Santa Clara, got a tour of some of the exhibits there, heard the talk by Shannon Lucas (VP. Head of Emerging Business Unit in North America) on Tuesday and met with Ericsson’s IoT expert Mats Alendal on Thursday for a one on one conversation about Ericsson’s IoT strategy and associated wireless WANs (e.g. NB-IoT, LTE-M, and “5G”).

Most surprising was that Mats claimed that the transition from 4G LTE to whatever the 5G RAN/RIT is will be ONLY A SOFTWARE UPGRADE OF ERICSSON’S BASE STATION.  He also said that if the 5G latency could be reduced to 1 or 2 ms, it would open up many new real time Industrial IoT (IIoT) applications that we haven’t thought of yet.  Such a low latency would require a controlled environment, typically in a manufacturing plant or similar, and mm wave radio.

Currently most IIoT applications rely on wired connectivity on a factory floor, manufacturing plant or test facility.  In a few cases wireless LANs (e.g. WiFi, Zigbee, proprietary) might be used.   Hence, wireless WAN connectivity represents a big shift for many industrial customers. IIoT use cases in manufacturing require a wireless WAN with  low latency, guaranteed delivery of messages/packets/frames, and instant control/feedback.

One of the best IIoT wireless WAN solutions is Private LTE.  It’s probably more robust than cellular LPWANs (NB-IoT and LTE-M) and provides cost benefits as well. In a Thursday afternoon session, Nokia recommended Private LTE for many of those IIoT applications (more information by emailing this author).  Ericsson is delivering Private LTE equipment via its 3GPP compliant, licensed and unlicensed bands for Private LTE.

IIoT use cases powered by Ericsson  include connected factory robots, manufacture of highly precise bladed disks (BLISKs) for turbines, and spherical roller bearings for SKF.  A case study for 5G trial for BLISKs may be viewed here.

Highlights of Shannon Lucas’ talk – Data Infrastructure: Mobile IoT: LPWAN & 5G:

  • 18B connected IoT devices are expected by 2022 (that’s down from earlier forecasts of 20B and more by 2020)
  • Edge computing network is needed for ultimate scalability and a great user experience (user might be a machine/device)
  • Hardware innovation platform can make LTE-M and NB-IoT easier to implement for network operators.  AT&T and Verizon are using Ericsson’s NB-IoT technology for their commercial offerings.
  • Ericsson has driven standards for cellular connectivity, and that effort is now naturally extending into setting standards for IoT, and more specifically, cellular IoT. With standardization, the IoT becomes a platform from which collaboration between organizations, both private and public, will benefit us all.
  • Ericsson’s standardized approach for connecting devices and sensors allows cities to collaborate and share data, regardless of legacy platforms. This helps engineers improve traffic flow, and allows emergency services to optimize response times.
  • A collaboration between Ericsson, Intelight and Teleste is helping to break up traffic and information gridlock. Four cities in the Dallas-Fort Worth metroplex have launched a regional system employing the Ericsson Connected Urban Transport ITS platform.

Wednesday Evening Private Briefing:

Ericsson Ventures (VC arm of Ericsson) is focused on driving innovation in areas that will accelerate Ericsson’s core business and generate strong financial performance.  Intent is to combine start-up solution with Ericsson’s technologies. 6 to 7 deals per year with average investment of $1.5M.  Ericsson likes to be part of a syndicate of VCs and corporate investors in the targeted start-up.  They are start-up stage agnostic.

Areas for Ericsson Ventures investment include:  IoT, analytics connected car, security, SDN, AR and VR, mobile advertising, wireless connectivity AI and ML.

Many new IoT applications will be enabled by 5G (so thinks everyone), including the connected car and real time control for IIoT.  This author is not so sure. We think that high bandwidth and/or low latency might be needed for at most 5 to 10% of IoT applications.

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References:

Ericsson IoT accelerator platform: https://www.ericsson.com/en/internet-of-things/solutions/iot-platform

Ericsson Technology Review (our most technical papers): https://www.ericsson.com/en/ericsson-technology-review

Cellular IoT Use Cases:  https://www.ericsson.com/en/networks/cases/cellular-iot

Enabling intelligent transport in 5G networks

Industrial automation enabled by robotics, machine intelligence and 5G

Ericsson white papers: https://www.ericsson.com/en/white-papers

  • 5G radio access – capabilities and technologies
  • Cellular networks for Massive IoT

Cignal AI: Optical Hardware Spending Grows in Europe, Asia Pacific in 1Q2018; flat in North America

According to research firm Cignal AI, first quarter 2018 growth in optical hardware sales in the Asia Pacific region was fueled by additional increases in spending outside of China. Sales in the EMEA region also grew YoY, and larger equipment vendors express optimism about incumbent operators future spending. Cignal AI’s report also illustrates an ongoing a spending decline in the North American market, which has proved weaker than expected.

“The massive spending in China during 2017 has slackened during 1Q18, resulting in flat year-over-year growth. A precise determination of results for the region is complicated by the ongoing ZTE export ban and ZTE’s communication blackout,” said Andrew Schmitt, lead analyst for Cignal AI. “Meanwhile, North America continues to be weaker than expected in an aggressive pricing environment.”

Cignal AI’s Optical Hardware Report is issued each quarter and examines optical equipment revenue across all regions and equipment types. Shipment information and guidance from individual equipment companies are included, and forecasts are based on spending trends in each region and the equipment types within those regions.

Key Findings In 1Q18 Optical Hardware Report:

  • RoAPAC exceeds forecasts, while Chinese market softens.Optical hardware spending in China was flat year-over-year. Cignal AI estimates ZTE experienced a soft quarter even before the impact of the export ban. Outside of China, the RoAPAC continued to grow, with Huawei, Nokia, and Coriant as primary beneficiaries.
  • North American optical hardware spending remains weak. North American spending declined by nearly double digits YoY in the first quarter. Cignal AI expected the region to rebound in 2018 with the return of stabilized pricing. But aggressive pricing continues and may impact total spending levels for the entire year. Infinera was a bright spot in the North American market as sales of its new ICE3-based products helped lead a revenue turnaround for the company.
  • Optimism abounds in EMEA. Vendors are optimistic about ongoing spending trends in the EMEA region, particularly among the large incumbents. This bodes well for Nokia and Ciena; two companies well-positioned to take advantage of new market opportunities.

Real-Time Optical Hardware Tracker Now Available from Cignal AI

Cignal AI launched its new and unique Optical Hardware Market Share Tracker. The tracker provides real-time visibility on individual vendors’ ongoing results as soon as they are reported. This insightful tool gives Cignal AI clients the freshest, most up to date market data possible to enable well-informed market analysis.

About the Optical Hardware Report

The Cignal AI Optical Hardware Report includes market share and forecasts for optical transport hardware used in optical networks worldwide. Analysis includes an Excel database and PowerPoint summaries, plus Cignal AI’s real-time news briefs on current market events, Active Insight. The Hardware Report examines revenue for metro WDM, long-haul WDM and submarine (SLTE) equipment in six global regions and includes detailed port shipments by speed. Vendors in the report include Adtran, ADVA, Ciena, Cisco, Coriant, Cyan, ECI, Ekinops, Fiberhome, Fujitsu, Huawei, Infinera, Juniper Networks, Mitsubishi Electric, MRV, NEC, Nokia, Padtec, TE Conn, Transmode, Xtera and ZTE.

Full report details, as well as articles and presentations, are available to users who register for a free account on the Cignal AI website.

 

Verizon talks up OTT video over “5G” fixed access; will participate in “5G” trial in South Africa

Verizon will join with an unannounced over-the-top (OTT) video company rather than launch a linear service of its own, CEO Lowell McAdam said during a Yahoo Finance interview yesterday. Verizon intends to bundle the OTTP video service with its “5G” fixed access starting in the fourth quarter. “I think the linear TV model is dead — it’s just going to take a long time to die,” he said.

“Our view is we should partner with those that are in the linear game, let them be very good at what they do. We’ll add digital content to that mix and we’ll position ourselves for where we become more of an over-the-top video culture versus the linear model that we have today.”

What McAdam is previewing is an integrated OTT offer that combines a linear channel line-up and VOD with Verizon’s digital assets. He hopes this approach will provide both some differentiation in the market and additional ways to monetize their Oath digital content.

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Separately,  Verizon will participate in a trial “5G” network to be deployed in South Africa by local telecommunications company Comsol. South Korea’s Samsung Electronics has also joined Comsol as a partner in the venture.  The three firms will deploy a trial “5G” network, which will be operational by the third quarter of 2018, Comsol CEO Iain Stevenson told TechCentral by phone on Tuesday. The objective is to showcase the network at the upcoming ITU Telecom World conference to be hosted by South Africa later this year.

Stevenson said the trial will be converted into a full commercial network with more base stations early next year once the 5G standards have been ratified. Comsol has been working to build a 5G network in South Africa for some time.

The trial, which will take place in Johannesburg, will consist of two “multi-sector” base stations to start, connected to fibre-optic backhaul. Multiple demonstration points will be established where members of the public will be able to experience 5G, which will deliver gigabit-class Internet access. Both Samsung, whose technology will be used in the trial, and Verizon will send engineers to South Africa to assist in the construction of the network.

Though the trial network will be “non-commercial”, customers will be connected to it and will use it in real-world environments, Stevenson said. Other 5G trials in South Africa have not involved live customers.

The “point-to-multipoint” network will utilise Comsol’s extensive spectrum assignment at 28GHz — it owns more than 30% of the high-frequency band. Stevenson declined to comment in detail on Comsol’s strategic plans, including its likely future funding model, but said it intends offering services to both businesses and retail consumers, with the technology serving as a replacement to fiber.

The trial is aimed at delivering a wireless solution that rivals “FTTx” offerings, including fiber to the business and fiber to the home, by early next year. This will be achieved by using the “pre-5G” proprietary standard from Verizon’s 5G Technical Forum for fixed-wireless deployments in the 28GHz and 39GHz bands. The proprietary standard will ultimately be converted into the 3GPP 5G New Radio specification once they have been confirmed by ITU-R WP 5D (not before August 2019!)

Stevenson said 5G fixed-wireless access has the potential to connect millions of South Africans with high-speed connectivity that would never be possible with fiber solutions, which, he said, require significant investment in physical infrastructure.

“Verizon has made significant investments in spectrum and technology and established a number of strategic collaborations to launch fixed-wireless 5G services in between three and five US cities by the end of this year.”

Sung Yoon, president and CEO of Samsung Electronics Africa, said in a statement about the collaboration between the companies that there is “so much opportunity in the region due to the diversity of markets and services already in place here, and we think South Africa is a prime candidate to show off the benefits that 5G can bring to consumers here.”

“While this agreement initially focuses on 5G fixed-wireless access, over time this will evolve into consumer offerings, similar to the way that we use 4G services today,” Stephenson said.

Reference:

https://www.techcentral.co.za/verizon-samsung-back-new-5g-network-in-sa/81229/

 

 

Cable Companies/MSOs Continue to Dominate U.S. Broadband Access with 64% Market Share

by Karl Bode  edited by Alan J Weissberger

The nation’s biggest cable companies continue to dominate traditional telcos when it comes to quarterly broadband additions. According to the latest data by Leichtman Research, the nation’s top cable operators added 845,000 subscribers during the first quarter, while the nation’s telcos lost 45,000 broadband subscribers during the quarter. That’s largely thanks to many phone companies (Verizon, Frontier, Windstream, CenturyLink) refusal to upgrade aging DSL users at any real scale, resulting in a slow but steady exodus as users flee to cable to obtain the FCC’s definition of broadband (25 Mbps).

According to Leichtman, that’s eight straight quarters during which the nation’s telcos have lost subscribers.

Leichtman’s findings for the quarter include:

  • Overall, broadband additions in 1Q 2018 were 83% of the 965,000 net adds in 1Q 2017
  • The top cable companies added about 845,000 subscribers in 1Q 2018 – 84% of the net adds for the top cable companies in 1Q 2017
  • The top telephone companies lost about 45,000 subscribers in 1Q 2018 – similar to the net losses in 1Q 2017
    • Telcos have had combined net broadband losses in each of the past eight quarters
  • At the end 1Q 2018, cable had a 64% market share vs. 36% for Telcos – compared to 61% for cable vs. 39% for Telcos at the end of 1Q 2016

“With the addition of 800,000 subscribers in the quarter, top broadband providers in the U.S. cumulatively now account for about 96.5 million subscribers,” said Bruce Leichtman, president and principal analyst for Leichtman Research Group, Inc.  “Over the past year, there were about 1,950,000 net broadband adds, compared to about 2,550,000 net adds over the prior year.”

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At the end of the first quarter, cable had a 64% market share versus 36% for Telcos — compared to 61% for cable versus 39% for Telcos at the end of 2016. This expanding monopoly not only reduces the incentive on cable to to improve historically-terrible customer service, but it also gives them the green light to abuse these captive markets via a bevy of price hikes — especially arbitrary and unnecessary usage caps and overage fees.

Overall, broadband growth continues to slow, which is driving many of these companies into additional markets (like online advertising).

References:

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Interesting reader comment:

Telcos Refusal to upgrade period.

quote:


That’s largely thanks to many phone companies (Verizon, Frontier, Windstream, CenturyLink) refusal to upgrade aging DSL users at any real scale, resulting in a slow but steady exodus as users flee to cable to obtain the


The mess the US is in goes back to the break up ATT, and possibly further.

The RBOC’s and other ILEC were in the cat bird seat, and BLEW IT! They could have taken their already wired to practically every one position and just blown the MSO’s out of the water in the early days of @Home etc..

INSTEAD they chose to just let the MSO’s develop things, and DO NOTHING In most cases to some DSL, and some fiber. When VZ started to get its act togehter and try to right the ship, Gordon Gecko’s just backed up and ran into the iceberg again!

I honestly believe had ISDN been pushed harder by ATT in the 70’s we would see ubiquitous HSD to everyone via ATT. WHY Well starting with a DIGITAL LINE to the premises in the 70’s… then upgrade from there…128K in the 70’s compared to what most were getting 110 or 300 or even if you were lucky 1200 baud! 2400 baud was not that old into the early 80’s! I had a 2400 baud for QLink..

The ILEC/RBOC’s blew their chance, they had everything there and all they had to do was continue to ugprade. They chose not to! Now we have this mess.

UPS Exec: Data analytics & tracking crucial to effective IoT deployments

Is UPS a package delivery company or a logistics and data/analytics company?  Known for its ubiquitous brown trucks, the global package delivery giant has embraced IoT in just about every facet of its business, with even more projects in the works. There are IoT sensors on trucks, handheld devices, even labels that monitor everything from truck engine performance to packages flowing through the network.

During his May 15th keynote address at IOT World 2018, Juan Perez, chief information officer and chief engineering officer for UPS, said that his company has “truly transformed” the way it does business by leveraging the power of IoT technology to realize efficiencies and avoid downtime. But achieving these benefits is not a product of simply deploying sensor throughout the organization to gather random information, he said.

“I think we all recognize that IoT is data, but, very importantly, data minus analytics is just simply trivia. I get really, really worried when I hear business units … wanting more and more data in the organization without having a solid strategy as to how that data is going to help us make better business decisions.”

“Of course, trivia can cost UPS lots of money—ultimately, without the type of value that we want to generate from it. However, data plus insight helps with decisions.”

IoT has already helped UPS save millions of dollars every year. One of the best-known examples of this is optimizing driver routes. Before drivers leave the facility, they get a manifest on their handheld devices that lays out their route for the day.  It’s a route that factors in numerous data signals in order to minimize the miles they drive. Sensors also track location, traffic conditions, and monitor a truck’s performance to avoid breakdowns on the roads or highway.

UPS at IoT World 2018

Juan Perez of UPS shows off the company’s E-Trikes on stage at IoT World in Santa Clara, CA 

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Perez has been with UPS for  over 25  years, starting as a truck driver in the Beverly Hills, CA area. Juan became UPS’s CIO in 2016 and added engineering to his title in April 2017.  His career has covered assignments in Operations, Industrial Engineering, Process Management, and Technology in corporate, US, and international business units.

Juan said the key between data being a trivial pursuit and an engine for driving more effective and efficient operations is analytics.

“All of these connected devices that we have at UPS collect a significant amount of data, but raw data is just useless—it doesn’t mean anything to us,” he said. “What we’ve had to do to truly extract value from our IoT strategy and from our data strategy is to get very, very effective at analytics.

“Analytics … is taking raw data and making that raw data be converted into insight, so we can make better decisions. We live by this day in and day out.”

Perez said there are three types of analytics: descriptive, predictive and prescriptive. Descriptive analytics is focused on past performance, and predictive analytics is focused on the present—both can be helpful in identifying areas of improvement within an organization, but they only help personnel make good future decisions if conditions do not change, he said.

In contrast, prescriptive analytics are focused on the future and can be adaptive to changing environments, Perez said.

“Where we want to be is in the world of prescriptive analytics,” Perez said. “The output is now allowing us to make really effective decisions and take action on the way we do work. The focus is not only on the present but also on the future. The question that needs to be asked—which is really important—is, ‘What should I do next?’

“Quite frankly, there hasn’t been a downside to UPS in focusing on prescriptive analytics.”

This approach is manifested in several areas, from package-tracking capabilities to analytics that use sensor data on vehicles to determine maintenance needs, Perez said. In addition, UPS drivers are given routes each day that have been optimized to deliver packages in the most efficient manner, he said.

Analytics crucial to effective IoT deployments, UPS exec said.  Matters like route optimization might seem like a small item on the surface, but in a company with UPS’s scale–more than 454,000 employees, more than 100,000 delivery vehicles and a fleet of more than 500 airplane worldwide delivering up to 34 million packages in the U.S. during its peak period last year—even small efficiency gains can have a very real bottom-line impact, Perez said.

“We are detail-oriented,” Perez said. “Think about these numbers: If we save 1 mile per driver per day—across all of our drivers in the U.S.—in the course of a year, UPS can save $50 million. If we can save one minute in our drivers’ day that is non-value-added for our customer or for us as a company, we can save—across all drivers the course of a year–$14.6 million. If we can reduce one minute of idle time, we can reduce $515,000 in a year.

“Details matter. So, as you develop your data strategy and your IoT strategy, ensure that you remain detail-oriented.”

This mindset has altered the way UPS operates, Perez said.

UPS has changed significantly in the last several years,” Perez said. “In fact, we’re no longer a small-package delivery company alone. Yes, we’re definitely the largest package-delivery company in the world, but we’re also a logistics company. We’re also an insurance company. We provide all kinds of freight transportation across multiple modes. And we continue to gather data on all aspects of our business and keep generating insights that can help UPS run better. So, today, we’re a very different company than we were many years ago.

“The journey to get here has been difficult. We were a paper-based company only a few years back … Today, I would make the argument that UPS is truly a technology company that happens to be in the logistics business. We deliver packages, but we are a technology company.”

“We’re working on a number of projects to bring sensors to everything. We believe data and IoT will continue to improve our business in ways that we haven’t even dreamed of.”

The exponential growth of data made possible by connected devices and the industrial Internet is creating a society that is always on and always learning. These connections are transforming entire industries as companies leverage new technologies for greater efficiency, improved service and positive environmental impact.

 

Posted in Uncategorized Tagged ,

GSMA: NB-IoT and LTE-M deployments gaining market traction; Sequans combo module & NB-IoT silicon

NB-IoT and LTE-M Deployments:

A total of 48 commercial narrowband IoT (NB-IoT) and LTE-category M (LTE-M) have been launched worldwide as of the end of April, according to the GSMA.  Statistics from GSMA show that 13 mobile operators have deployed mobile IoT solutions, including all of China’s big three wireless network operators – China Mobile, China Telecom and China Unicom.

South Korea’s KTLG Uplus, Singapore’s M1, Australia’s Telstra, Sri Lanka’s Dialog Axiata and Mobitel, Taiwan’s Far EasTone and Chunghwa Telecom, Japan’s KDDI, Thailand’s True Corp and Vodafone Group have also adopted the technology.

NB-IoT deployments are currently a lot more common than LTE-M, although some operators including Singtel and Australia’s Telstra have deployed both technologies.  AT&T, Verizon, and Sprint have all announced LTE-M.  T-Mobile has only announced support for NB-IoT.

Note that both NB-IoT and LTE-M operate over licensed spectrum, which is much more reliable than unlicensed spectrum used in Sigfox and LoRa.  Those latter two LPWANs are much more widely deployed then NB-IoT and LTE-M combined.

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Sequans Combo Module:

During an IoT World panel session on Tuesday May 15th, France chip design house Sequans Communications announced that both Verizon and AT&T would be selling their combined NB-IoT/LTE-M module for $7.50.  Verizon has certified Sequans” Monarch SiP (system-in-package) LTE-M/NB-IoT connectivity solution.  This module integrates Sequans’ Monarch LTE baseband platform with an RF front-end module in the world’s smallest form factor. Monarch SiP was introduced in late February and is now listed on Verizon’s Open Development website as an approved module.  Complete details are available here.

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NB-IoT Silicon:

In a recent blog post, Nick Hunn claimed there are 13 companies (now 17) that have announced NB-IoT chips.

If you count up real NB-IoT deployments, it’s still early days. There are probably fewer than 10 million chips deployed. That’s the figure from Huawei, who is certainly leading the field. How many of those are actually connected and sending data back is questionable – the last year has largely been an exercise in getting things to work and spinning the PR. Nevertheless, Huawei is predicting that by the end of 2018 the number of chip shipments will reach 150 million, which, given the focus on NB-IoT within China, may well happen. The big question is what will happen in the rest of the world. To understand that, it’s interesting to look at the different companies which will be producing silicon.

The thirteen companies I’m aware of (please let me know if you know of any others) are HiSilicon (part of Huawei), Sanechips (a division of ZTE), RDA, Mediatek, Altair (owned by Sony), Sequans, Nordic Semiconductor, Goodix, Riot Micro, Qualcomm and Nesslab, along with ARM and ASTRI/CEVA. ARM and the ASTRI / CEVA partnership are IP vendors, but appear to be at a state where they are already behind some of the offerings, so are worth including, as if anyone plans to ship in volume, they’re an obvious destination. ARM is further differentiating itself by offering a wider-ranging IoT service including device management and aspects of provisioning. I need to apologise for missing GCT, which brings it up to fourteen. And since writing this I’ve been made aware of a further three – Pinecone Electronics (who have Xiaomi as an investor and appear to be building on ASTRI’s IP), Extra Dimensions Technology – a Beijing startup and Eigencomm – a Shanghai startup. That further highlights the China centric concentration and reflects the amount of Government support being put in to make China the leader in IoT. So we have a sweet seventeen, with probably more to come.

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Mobile IoT for the 5G Future

Image courtesy of GSMA

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GSMA says the technologies will coexist with other 5G components.  Also, that 3GPP is working to allow LTE-M and NB-IoT to be placed directly in a 5G new radio frequency band, and is investigating options for the 5G core network to support LTE-M and NB-IoT radio access networks.

Sigfox launches Sens’It Discovery; Network used for Gas Tank Monitoring in Mexico via IoTnet & Levelgas

At the IoT World conference, May 15th, global IoT network operator Sigfox unveiled its Sens’It Discovery solution. It combines a sensor-packed device (thermometer, hygrometer, light meter, accelerometer, magnetometer and a reed switch), the sensit.io application (for Web browsers and mobile) to remotely control the device, and 1 year of network connectivity to Sigfox’s IoT Cloud.  Sigfox hopes that Sens’it becomes one more way for users to experiment with IoT projects and/or produce insightful data to be analyzed.

The new Sens’It device and Sigfox connectivity service will be available in the 45 countries where Sigfox currently operates.  Priced at around $75, Sens’it also comes with a software development kit (SDK) for developers to start building a wide range of IoT applications from home appliances, vending machines, smart metering, asset tracking, supply chain management, logistics and even waste management.

Developers can turn the device into a development kit, create their own firmware, and fully re-configure the device thanks to a dedicated Software Development Kit (SDK) available on www.sensit.io.  They will be able to:

  • Get direct access to the device data on the Sigfox Cloud and create new application integrations.
  • Build custom embedded applications to completely change the device behaviour and adapt sensors’ logic to create new uses and solutions.
  • For hardware engineers, Sens’it Device Sources are available for download, to be re-used in other device projects.

“With Sens’it, our goal is to demystify IoT and accelerate its adoption by showing how easy anyone, from consumers to developers, can connect anything to the Internet,” says Cédric Giorgi, the director of experience design at Sigfox. “Just attach the device to your door, a bicycle or anything really, and you will start receiving feeds of real-time data coming from the device, via the Sigfox Cloud, on your phone, through email, SMS or push notifications. It’s that easy.”

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Backgrounder:

Sigfox, which has raised almost $300 million in venture capital, operates a low-power, low data rate communications network to send tiny packets of information using 2G – like radio technologies. The idea is to allow large volumes of connected devices to send small amounts of data without needing much battery power and at a very low cost.  That enables massive numbers of devices to be deployed over long periods of time without having to replace the batteries.

Today, large scale IoT applications are mostly deployed over 2 competitive low-power, wide-area (LPWA) IoT network: The one built by Sigfox and its telecom operators partners, and the other, LoraWAN, pushed by chip supplier Semtech through the LoRa Alliance.  We compared and contrasted those two LPWANs in this article.

Sigfox devices have better power efficiency (longer battery life) and resistance to jamming and interferences. And unlike Semtech, which is the only one making the radio for LoRa, Sigfox offers its technology license-free, making their money on network services and not on the device itself.

The SigFox network covers 45 countries, which means that a Sigfox device will work seamlessly anywhere wherever it operates in the world.

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For additional information about Sens’it please visit: https://www.sensit.io/

References:

https://www.sigfox.com/en/news/sigfox-launches-sensit-discovery

https://techblog.comsoc.org/2017/10/25/lora-wan-and-sigfox-lead-lpwans-interoperability-via-compression/

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In a superb tag team presentation late Thursday afternoon, a Mexican MVNO and device maker provided a real life case study: How LPWAN is Helping Levelgas Uberize Gas Tank Monitoring.  Daniel Guevara – CEO, IoTnet Mexico – aka WND Group (the Sigfox MVNO) and Pedro Gabay Villafaña – Founder of Edison Effect were the presenters.

IotNet is the exclusive network operator for Sigfox in Mexico and will initially focus on utility applications, such as remote metering for water, gas and residential electricity. The company is owned by the shareholders of NXTVIEW, a company that is deploying the first metering-as-a-service that exists in the Mexican energy market.  They worked closely with Edison Effect which makes the Levelgas product for measuring the level of gas in tanks.  Collectively, the two companies provide a complete end to end solution for gas companies throughout Mexico.

IoTnet provides CONNECTIVITY for the INTERNET OF THINGS in all of MEXICO:

LOW CONSUMPTION

Optimized communication for low power consumption devices.

LOW COST

Low cost subscription, with easy integration technology and open protocol.

LONG-RANGE

The IoT global network with a coverage of 1.7 million km.

TRUSTWORTHY

The SigFox network is built on strong security mechanisms.

Levelgas is revolutionizing the management of stationary gas tanks in homes.  Its solution integrates a device that is quickly placed directly in the tank and sends information (via Sigfox) to a mobile application where the user can check the gas level, calculate refills, verify the supply of the tank in real time , buy gas remotely and transparently, and know their consumption habits.

For the gas companies, Levelgas becomes a commercial partner with a unique advantage: generating data. This data becomes essential when it is translated into a deep knowledge of the market for better marketing strategies, the optimization of routes based on real demand, and a logistical efficiency that results in important savings.

More in a future IEEE Techblog article………………………………

 

Network Slicing and 5G: Why it’s important, ITU-T SG 13 work, related IEEE ComSoc paper abstracts/overviews

Why end-to-end network slicing will be important for 5G:

In network slicing of a 5G network, the intent is to take infra­structure resources from the spectrum, antennas and all of the backend network and equipment and use it to create multiple sub-networks with different properties. Each sub-network slices the resources from the physical network, end to end, to create its own independent, no-compromise network for its preferred applications.

One slice type is specifically targeted for ultra-low latency and high reliability (like self-driving vehicles) (URRLC), another slice type is spe­cifically targeted for devices that don’t have large batteries (like sensors) (MMTC) and need efficiency and yet another slice type is targeted at ultra-high speed (eMBB) as required for 4K or immersive 3d video. While the initial standards work calls for only three slice types, the architec­tures are flexible for future slice types.

Since it would be far too expensive to allocate a complete end-to-end network to each type of slice, the network infrastructure that supports 5G (and likely 4G) will employ sharing techniques (virtualization and cloud), which allow for mul­tiple slice types to co-exist without having too many multiples of the resources.

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In 2017, ITU–T Study Group 13 (SG13) cre­ated a Focus Group with a mandate to research the areas that needed standardization for the non-radio aspects of 5G. The harmonious oper­ation through software control, referred to as “softwarization” of all of the components of the 5G network, was one of the many subjects stud­ied by the Focus Group, and which is now being more formally considered by SG13. Many of the areas requiring control are not uniquely wireless components but are also involved in service providers’ other end-to-end-businesses. For example, the cloud and transport networks which interconnect them will require new agile control to ensure that the packet, non-packet interconnections and compute, meet the Quality-of-Service (QoS) demands of that slice. The success of 5G lies in entire ecosystems 5G slicing technology, to be truly successful, will need entire ecosystems to come together to solve and standardize their end-to-end applications.

Read more here and here.   ITU-T SG13 Working Party 1 Questions on Non Radio Aspects of IMT 2020 Networks & Systems:

WP1/13 IMT-2020 Networks & Systems 
Q6/13 Quality of service (QoS) aspects including IMT-2020 networks 
Q20/13 IMT-2020: Network requirements and functional architecture 
Q21/13 Network softwarization including software-defined networking, network slicing and orchestration 
Q22/13 Upcoming network technologies for IMT-2020 and Future Networks 
Q23/13 Fixed-Mobile Convergence including IMT-2020 

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Selected IEEE ComSoc Papers on 5G Network Slicing:

Efficient and Secure Service-oriented Authentication Supporting Network Slicing for 5G-enabled IoT

by Jianbing Ni, Student Member, IEEE, Xiaodong Lin, Fellow, IEEE, Xuemin (Sherman) Shen, Fellow, IEEE (edited by Alan J Weissberger)

To be published in a future issue of IEEE Journal on Selected Areas in Communications sometime in 2018 

Abstract

“5G” network is considered as a key enabler in meeting continuously increasing demands for future Internet of Things (IoT) services which will connect numerous devices.  Those IoT demands include high data rate  and  very low network latency. To satisfy these demands, network slicing and FOG computing have been envisioned as promising solutions in service-oriented 5G architecture. However, security paradigms enabling authentication and confidentiality of 5G communications for IoT services remain elusive, but indispensable. In this paper, we propose an efficient and secure service oriented authentication framework supporting network slicing and fog computing for 5G-enabled IoT services.

Specifically, users may efficiently establish connections over a 5G core network and anonymously access IoT services under their delegation through proper network slices of 5G infrastructure.  The particular 5G service might be selected by FOG nodes based on the slice/service types of accessing services. The privacy preserving slice selection mechanism is introduced to preserve both configured slice types and accessing service types of users. In addition, session keys are negotiated among users, local fogs and IoT servers to guarantee secure access of service data in fog cache and remote servers with low latency. We evaluate the performance of the proposed framework through simulations to demonstrate its efficiency and feasibility under 5G infrastructure.

From the Introduction:

How to enhance security and privacy protection for IoT services powered by 5G is the focus of this paper.  To secure 5G-enabled IoT services, a national demand is to design efficient service-oriented authentication protocols for numerous users with the severe demands of different IoT services. To preserve user privacy, it is critical to hide users’ identities during service authentication. Thus, the challenge is to support anonymous service-oriented authentication with scalability of handing a large number of authentication requests.  Furthermore, after users’ identities are well protected, it is still possible for local fog nodes to identify users through some side-channel information, such as users’ accessing services, which results in unwelcome advertisements for users.

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Network slicing for 5G systems: A review from an architecture and standardization perspective

by Riccardo Trivisonno; Xueli An; Qing Wei

Published in: Standards for Communications and Networking (CSCN), 2017 IEEE Conference in Helsinki, Finland, 18-20 Sept. 2017.

Abstract:

The discussion around Network Slicing for 5G Systems is slowly converging to concrete solutions which will be adopted in the early deployment of 5G Networks due by 2020. In particular, within 3GPP standardization body, study items recently completed have finalized the definition of 5G System architecture, comprising Access and Core Networks, and defined the key design principles for End to End Network Slicing. This paper reviews the latest achievements of 3GPP SA2 and RAN3 Working Groups (WGs) in this respect, relating them to the genesis of Network Slicing and to prior 4G technical solutions, which can be considered precursors of the concept. Essentially, this paper timely clarifies how Network Slicing will be brought into real systems, and sheds some light on the necessary next steps to further progress on the topic.
Introduction:
In the ongoing hectic activities aiming at defining and standardizing 5G System (5GS) cornerstones, targeting an early deployment in the 2020 horizon, Network Slicing is amongst the most debated issues. The concept of Network Slicing was brought into the 5G system domain by early discussions among mobile network operators within NGMN. To shed some light on the concept, it is beneficial to fall back to its genesis.

The problem statement originated back in 2015, at the time 5G use cases were analyzed ([1]), when it emerged 4G network architecture did not suit with the diversity of requirements derived from 5G use cases. 4G architecture was considered “not flexible and scalable enough to efficiently support a wider range of business needed when each has its own specific set of performance, scalability and availability requirements”. Additionally, it was argued that a future-proof 5G system should have been conceived allowing efficient introduction of new network services. From this simple and clear starting point, the concept of Network Slicing for 5G was introduced. According to NGMN, the network slicing concept consisted of 3 layers: Service Instance Layer, Network Slice Instance (NSI) Layer, and Resource layer. As described in [1], “the Service Instance Layer represents the services which are to be supported. Each service is represented by a Service Instance.” Also, [1] stated “a Service Instance can either represent an operator service or a 3rd party provided service”. Furthermore, NGMN assumed a network operator would use a Network Slice Blueprint to create an NSI. An NSI provides the network characteristics which are required by a Service Instance. An NSI may also be shared across multiple Service Instances provided by the network operator. An NSI was defined as “ a set of network functions, and resources to run these network functions, forming a complete instantiated logical network to meet certain network characteristics required by the Service Instance (s) ”. Network Slice Blueprint was defined as a complete description of the structure, configuration and the plans/work flows for how to instantiate and control the NSI during its life cycle. A Network Slice Blueprint enables the instantiation of a Network Slice and describes required physical and logical resources. NGMN definitions are sound and complete but, being written from network operator’s standpoint, they focus on the end service perspective and they fail to distinguish among domains they apply to. In particular, it is straightforward the Network Slice Blueprint definition includes system architecture, network lifecycle/management and resource/infrastructure aspects.

The implicit wide scope of such definitions and the appeal the slicing concept was gaining in the R&D community triggered a number of initiatives aiming at extending and clarifying the concepts in all possible concerned domains (see e.g. [2] for SDN related aspects, or [3] for protocols ecosystem issues). The bottom line is: to further progress in the definition of the technologies required to bring Network Slicing into real systems, it is essential to focus on a narrower scope.

The scope of this paper is restricted to 5G end to end System Architecture aspects (i.e. Access and Core networks), leaving aside network management, transport network, network and data centres infrastructure issues. The purpose of this paper is to examine the 4G legacy on Network Slicing (where related early concepts can be found), to review the current status of 5G system standardization in this respect, and to highlight the critical open points which will require significant effort before 5G standardization completes.

The paper is organized as follows: Sec II looks back to 4G systems, analysing early solutions which can be considered precursors of Network Slicing. Sec III presents an in-depth review of latest achievements from 3GPP WGs, which cast the actual foundations over which 5GS will be built. Sec IV highlights the key open issues on which research and standardization will further devote significant effort. Finally, Sec V concludes the paper.

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Network Slicing for 5G: Challenges and Opportunities

by Xin Li; Mohammed Samaka; H. Anthony Chan; Deval Bhamare; Lav Gupta; Chengcheng Guo; Raj Jain

Published in: IEEE Internet Computing (Volume: 21Issue: 5, 2017)

Abstract:

Network slicing for 5G provides Network-as-a-Service (NaaS) for different use cases, allowing network operators to build multiple virtual networks on a shared infrastructure. With network slicing, service providers can deploy their applications and services flexibly and quickly to accommodate diverse services’ specific requirements. As an emerging technology with a number of advantages, network slicing has raised many issues for the industry and academia alike. Here, the authors discuss this technology’s background and propose a framework. They also discuss remaining challenges and future research directions.
Research in fifth-generation (5G) mobile networks has gained momentum in both academia and industry recently. These 5G mobile networks will carry a plethora of mobile devices and provide faster network connection speed. In addition, mobile data traffic in future 5G networks will experience explosive growth. According to the latest Cisco forecast,1 by 2020, the number of devices connected to mobile networks will exceed the world’s population, reaching 11.6 billion. At that time, mobile data traffic will be 30.6 exabytes per month, which is 8 times that in 2015. However, the most challenging aspect is that 5G networks will support a wide variety of use cases, as we’re entering the era of the Internet of Everything (IoE). Some applications, such as ultra-high defmition (UHD) video and augmented reality need high-speed, high-capacity communications, while others such as the mission-critical Internet of Things (IoT) and autonomous vehicles require ultralow latency, ultra-reliable services.

Traditional mobile communication networks employ the one-size-fits-all approach to providing services to mobile devices, regardless of the communication requirements of vertical services. This design philosophy can’t offer differentiated services. Hence, it’s necessary for the research community to explore new techniques to address the challenges associated with supporting vertical industries in 5G networks.

Software-defined networking (SDN) and network functions virtualization (NFV) have been proposed as key technologies to build softwarized, virtualized, and cloudified 5G systems in recent years. SDN2 decouples network control and data forwarding. Network control functions can run as applications independently in the logically centralized controllers. NFV3 decouples specific network functions from dedicated and expensive hardware platforms to general-purpose commodity hardware. Network operators can implement a variety of virtual network functions (VNFs) over the standard commodity servers. In addition, Mobile Edge Computing (MEC)4 as a key emerging technology in 5G is expected to serve low-latency communication that’s one of the use cases in future 5G. It moves computing, storage, and networking resources from remote public clouds closer to the edge of the network. Thus, mobile clients can request virtual resources within the access network and experience low end-to-end delay.

The concept of network slicing 5 has been proposed to address the diversified service requirements in 5G under the background of the aforementioned technologies. Network slicing is an end-to-end logical network provisioned with a set of isolated virtual resources on the shared physical infrastructure. These logical networks are provided as different services to fulfill users’ varying communication requirements. Network slicing provides a network-as-a-service (NaaS) model, flexibly allocating and reallocating resources according to dynamic demands, such that it can customize network slices for diverse and complex 5G communication scenarios.

Network slicing will be the fundamental feature of 5G networks. Slice-based 5G has the following significant advantages when compared with traditional networks:

  • Network slicing can provide logical networks with better performance than one-size-fits-all networks.
  • A network slice can scale up or down as service requirements and the number of users change.
  • Network slices can isolate the network resources of one service from the others; the configurations among various slices don’t affect each other. Therefore, the reliability and security of each slice can be enhanced.
  • Finally, a network slice is customized according to service requirements, which can optimize the allocation and use of physical network resources.

With this in mind, next we discuss some details on network slicing for 5G networks and explore why 5G needs network slicing, as well as how to implement network slicing in 5G. For others’ work on network slicing for 5G, see the related subhead below.

Network Slicing in 5G

Fifth-generation networks need to integrate multiple services with various performance requirements — such as high throughput, low latency, high reliability, high mobility, and high security — into a single physical network infrastructure, and provide each service with a customized logical network (that is, network slicing). The Third-Generation Partnership Project (3GPP) has identified network slicing as one of the key technologies to achieve the aforementioned goals in future 5G networks. Some 3GPP work items have the features of network slicing: for example, the dedicated core (DÉCOR) feature supports the operator to deploy multiple dedicated core networks by sharing a common Public Land Mobile Network (PLMN). An exhaustive description about how the next-generation wireless system will support network slicing is provided elsewhere.6

Network slicing refers to partitioning of one physical network into multiple virtual networks, each architected and optimized for a specific application/service. Specifically speaking, a network slice is a virtual network that’s created on top of a physical network in such a way that it gives the illusion to the slice tenant of operating its own dedicated physical network. A network slice is a self-contained network with its own virtual resources, topology, traffIC flow, and provisioning rules. There might be various network slices to meet the specific communication needs of different users in the future mobile network systems. For example, a massive industrial IoT slice might need a light 5G core, with no handover but a large number of connections. On the other hand, a mobile broadband slice might need a high-capacity core, full feature mobility, and low latency. Slices are logically isolated, but resources can be shared among them. Figure 1 illustrates the network slicing concept.

Figure 1

Figure 1.Conceptual illustration of network slicing. NFV stands for Network Function Virtualization, RAN stands for radio access network, and SDN stands for software-defined networking.

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Network slicing makes use of the concept known as network virtualization. Network virtualization enables flexible and dynamic network management to address the problem of network ossification by allowing multiple heterogeneous and service-specific virtual networks to share a single substrate network.

In addition, the emerging technologies software-defined networking (SDN) and network functions virtualization (NFV) are considered as the necessary tools to implement network slicing. The following work summarizes use of SDN and NFV to implement 5G network slicing.

Csaba Simon and colleagues1 propose a flexible 5G network architecture to support the coexistence of heterogeneous services and to quickly create services. The authors propose to use SDN and NFV in the architecture to realize the sharing of resources by different services and orchestrating resources automatically. The concept of resource slicing is similar to network slicing in the proposed architecture. Resource slices, which include virtual resources and virtual network functions, are tailored on-demand according to service categories, namely slice as a service (SlaaS).

Manuel Peuster and colleagues designed an NFV-based platform called Multi Datacenter service ChaIN Emulator (MeDICINE) for network services.2 It allows management and orchestration (MANO) system to deploy virtual network resources for network services in a multi-domain infrastructure. The design and implementation of this platform show that NFV plays an important role in realizing network slicing.

Navid Nikaein and colleagues3 proposed a novel slice-based 5G architecture based on SDN, NFV, and cloud computing. They designed the elements required to implement network slicing and present a validation prototype. The concept of a network store in this work can achieve dynamic 5G network slicing. The authors discuss building a multitenant and multiservice end-to-end 5G mobile network architecture using SDN, NFV, and network slicing in the 5G NORMA project.4

Mobile operators, hardware manufacturers and open source communities are also actively studying the ways to implement 5G network slicing. Ericsson and NTT DOCOMO successfully showed a dynamic 5G network slicing proof of concept on 9 June 2016.5 Ericsson6 discussed the decomposition schemes of radio access network (RAN) functions that can support network slicing. The schemes provide a meaningful guidance for implementing flexible and resilient RAN slices.

Very recently, Huawei (with other three enterprises) released a network slicing white paper.7 They discussed several key technologies, such as network management system and security to achieve service-guaranteed network slicing, which will be helpful for network industries.

It’s worth noting that the Open Network Automation Platform (ONAP), established in February 2017, is working on a cloud-centric and SDN/NFV-based network platform, which might lay the groundwork for the implementation of 5G network slicing. Also, currently, the Wireless World Research Forum (WWRF) is launching a working group for 5G network slicing.

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Network Slicing for 5G with SDN/NFV: Concepts, Architectures, and Challenges

by Jose Ordonez-Lucena; Pablo Ameigeiras; Diego Lopez; Juan J. Ramos-Munoz; Javier Lorca; Jesus Folgueira

Published in: IEEE Communications Magazine Volume: 55Issue: 5, May 2017 )

Abstract:

The fifth generation of mobile communications is anticipated to open up innovation opportunities for new industries such as vertical markets. However, these verticals originate myriad use cases with diverging requirements that future 5G networks have to efficiently support. Network slicing may be a natural solution to simultaneously accommodate, over a common network infrastructure, the wide range of services that vertical- specific use cases will demand. In this article, we present the network slicing concept, with a particular focus on its application to 5G systems. We start by summarizing the key aspects that enable the realization of so-called network slices. Then we give a brief overview on the SDN architecture proposed by the ONF and show that it provides tools to support slicing. We argue that although such architecture paves the way for network slicing implementation, it lacks some essential capabilities that can be supplied by NFV. Hence, we analyze a proposal from ETSI to incorporate the capabilities of SDN into the NFV architecture. Additionally, we present an example scenario that combines SDN and NFV technologies to address the realization of network slices. Finally, we summarize the open research issues with the purpose of motivating new advances in this field.
Overview:
The authors present the network slicing concept, with a particular focus on its application to 5G systems. They start by summarizing the key aspects that enable the realization of so-called network slices. Then they give a brief overview on the SDN architecture proposed by the ONF and show that it provides tools to support slicing. They argue that although such architecture paves the way for network slicing implementation, it lacks some essential capabilities that can be supplied by NFV.
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Ericsson:  Network Slicing can be a piece of cake

Network slicing in essence means that connectivity becomes differentiated, enabling you to provide innovative business models and demonstrate additional value.

Ericsson has a complete solution for network slicing, with all the key components in place. Available now, it will let you get started with network slicing, and elevate your offerings above mobile broadband.

This paper looks at the practicalities of network slicing and automation, how to support a multitude of new use cases, and how to simplify operations with services which are quick to provision, replicate, scale, upgrade and delete. The paper also considers the business support and monetization aspects required to generate revenue using this technology, and concludes with an example of network slicing collaborative work with a leading network operator.

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