Dell’Oro: Broadband Access equipment spending increased 18% YoY

A newly published Broadband Access and Home Networking 1stQ2021 report by Dell’Oro Group stated that the total global revenue for the Broadband Access equipment market increased to $3.3B in 1st Quarter, up 18 percent year-over-year (YoY).  The growth was driven by strong fiber infrastructure investments such as PON (Passive Optical Network) OLT (Optical Line Terminal) ports, particularly 10 Gbps PON technologies.

XGS-PON revenue jumped 500% year-on-year to about $200 million, reflecting several quarters of steady growth as fiber players up their game in anticipation of competition from cable operators deploying DOCSIS 4.0.

“The shift to 10 Gbps PON technologies is happening quickly and on a global basis,” noted Jeff Heynen, Vice President, Broadband Access and Home Networking at Dell’Oro Group. “The only thing preventing further expansions are supply chain constraints and increased costs,” Heynen explained.
“You can see the trajectory. It’s very clear that operators, if they’re deploying new fiber networks, in a lot of cases they’re doing so starting off with 10-gig. And even those that are beginning the process of upgrading from the first-generation GPON technologies they’re also doing so with XGS,” Heynen said. “This trend was accelerated by the Covid-19 pandemic,” he added.
“I think what has happened among operators, particularly in North America, is that they’re starting to realize that if we deploy more fiber and we do so with multi-gigabit capabilities then we’re putting ourselves in a position to anticipate and at least already be competitive with that DOCSIS 4.0 rollout.”
Additional highlights from the 1Q 2021 Broadband Access and Home Networking quarterly report:
  • Total broadband access equipment revenue was down 6 percent from the record revenue of 4Q 2020.
  • Total cable access concentrator revenue (a category that includes DOCSIS infrastructure elements such as converged cable access platform cores and chassis, virtual CCAP licensing and DAA nodes and modules) increased 15 percent YoY to $243 M.
  • Though DOCSIS license purchases were down, new hardware purchases in the form of CCAP chassis, line cards, and DAA nodes and modules helped push revenue higher.
  • CommScope led the cable access concentrator market with about 40% of revenues in Q1 2021, followed by Cisco (16%), Harmonic (16%) and Casa Systems (15%).
  • 80% of DOCSIS modems shipped in Q1 2021 were of the DOCSIS 3.1 variety.
  • Revenue from purchases of remote-PHY and remote MAC-PHY equipment were up 66% from Q4 2020, which can be interpreted as a sign that cable operators are resuming long-term projects that were put on hold during the height of the pandemic last year.
  • Total DSL Access Concentrator revenue was down 30 percent YoY, driven by slower port shipments worldwide as more operators shift their spending to fiber.
  • Total PON ONT (Optical Network Terminal which is CPE) revenue was down quarter over quarter, but unit shipments remained above 30M globally for the second straight quarter.

About the Report

The Dell’Oro Group Broadband Access and Home Networking Quarterly Report provides a complete overview of the Broadband Access market with tables covering manufacturers’ revenue, average selling prices, and port/unit shipments for Cable, DSL, and PON equipment. Covered equipment includes Converged Cable Access Platforms (CCAP) and Distributed Access Architectures (DAA); Digital Subscriber Line Access Multiplexers ([DSLAMs] by technology ADSL/ADSL2+, G.SHDSL, VDSL, VDSL Profile 35b, and G.FAST); PON Optical Line Terminals (OLTs), Cable, DSL, and PON CPE (Customer Premises Equipment); and SOHO WLAN Equipment, including Mesh Routers. For more information about the report, please contact


Long term, MoffetNathanson analysts forecast cable operators (MSOs) having a 50% broadband share in the markets where they compete with FTTH—significantly less than cable’s 85% market share against VDSL and 95% market share against DSL.


Will Cable Broadband Market Share Decline as Telcos Deploy Fiber?


Google & Subcom to build Firmina cable connecting U.S. and South America

Cable maker/installer SubCom said it has teamed up with Google to build and deploy a new undersea cable connecting North and South America. The cable, named ‘Firmina’ after Brazilian abolitionist and author Maria Firmina dos Reis, will run from the East Coast of the United States to Las Toninas in Argentina, with additional landings in Praia Grande, Brazil and Punta del Este, Uruguay. Designed as a twelve-fiber pair trunk, Firmina will be Google’s second proprietary U.S. to South America cable designed to improve access to the company’s services for users in the region.

SubCom said Firmina will be the world’s longest cable capable of maintaining operations with single-end feed power, in the event of a far-end fault. Manufacture of the cable and equipment will take place at SubCom’s recently-expanded manufacturing campus in Newington during 2021 and early 2022, with main lay installation operations scheduled for summer 2022. The system is expected to be ready for service by the end of 2023.

In a blogpost, Google Cloud’s vice-president of global networking, Bikash Koley, said:

“As people and businesses have come to depend on digital services for many aspects of their lives, Firmina will improve access to Google services for users in South America. With 12 fiber pairs, the cable will carry traffic quickly and securely between North and South America, giving users fast, low-latency access to Google products such as Search, Gmail and YouTube, as well as Google Cloud services.

Connecting North to South America, the cable will be the longest ever to feature single-end power feeding capability. Achieving this record-breaking, highly resilient design is accomplished by supplying the cable with a voltage 20pc higher than with previous systems.”

SubCom’s CEO, David Coughlan, said the partnership with Google will “supply a high-speed, high-capacity undersea cable system that will encompass some of the most advanced transmission technologies in the world.”

Source: Google


Firmina will join other Google cables in the region, including the 10,500 kilometer Monet system running from Boca Raton in the US to Fortaleza and Praia Grande in Brazil, the Tannat (Brazil-Uruguay) cable and the Junior cable connecting Rio de Janeiro to Santos in Brazil.

Google is also working with fellow tech giant Facebook on two new subsea cables that will connect North America and south-east Asia.

This came after another Google-Facebook subsea cable was blocked. Plans for the Pacific Light Cable Network were cancelled late last year due concerns from the U.S. government about direct communications links between the U.S. and Hong Kong.


About SubCom:

SubCom is the leading global partner for today’s undersea data transport requirements.
SubCom designs, manufactures, deploys, maintains, and operates the industry’s most reliable
fiber optic cable networks. Its flexible solutions include repeaterless to ultra-long-haul, offshore
oil and gas, scientific applications, and marine services. SubCom brings end-to-end network
knowledge and global experience to support on-time delivery and meet the needs of customers
worldwide. To date, the company has deployed over 200 networks – enough undersea cable to
circle Earth more than 17 times at the equator.

Mobile Optical Pluggables (MOPA) Technical Whitepaper

Nokia, Ericsson, II-VI, Lumentum and Sumitomo Electric published a joint technical paper making the case for reducing the wide choice of Mobile Optical Pluggables (MOPA) used to connect cell sites to fiber optic networks. The co-authors of the paper have recommended predefined optical blueprints that help operators speed up time to market using a common list of optical pluggable modules in a market worth $500 million per year.

Optical pluggables are defined as front-panel pluggable optical transceivers in popular form factors like SFP+, SFP28, QSFP28, etc. and the Blueprints are intended as global solutions, i.e., as generic as possible to cover a wide range of network scenarios.

The first-time joint industry initiative, published in time for the Optical Networking and Communication Conference & Exhibition, lays out a set of Mobile Optical Blueprints which describe the most optimized optical pluggable modules and passive optical components. Recommendations include optical characteristics such as data rates, reach, power, wavelengths as well as mechanical characteristics such as form factor, heat dissipation and operational temperature.

Ian Redpath, Practice Leader, Transport Networks and Components at Omdia said:  “In a 5G world, optical pluggables will be utilized to connect cell sites to the network core. Network operators are currently challenged with assessing many pluggable variations, increasing their qualification work load and slowing time to deploy. MOPA will streamline efforts for the connectivity community, enabling cost reductions and reducing time to deploy.”

Stefaan Vanhastel, CTO Nokia Fixed Networks said: “Fiber is a critical component of 5G rollouts and provides unmatched capacity for 5G transport. A clear overview of available optics strategies makes it easier to design and deploy 5G networks. We are pleased to be joining forces with Ericsson, II-VI, Lumentum and Sumitomo Electric on this vital initiative which will make the choice for fiber even more compelling in the transport domain.”


Mobile Optical Pluggables (MOPA) Technical Paper, June 8, 2021

Verizon Exec on 4G/5G fiber backhaul, One Fiber initiative and 5G at Home

SourceVerizon Communications Inc. at Wells Fargo Virtual Media & Telco Day: 5G & Streaming & Beyond on June 07, 2021 TRANSCRIPT /

Verizon Executive VP and CTO Kyle Malady stated:  Right now we have about 1/3 of our cell sites and small cells on our own fiber asset (backhaul). And I think that’s — we like the owner’s economics of that. We also like the control of the network because we can maintain quality and reliability.

Wells Fargo Question:

Let’s talk about Verizon’s One Fiber project, where you’re building in more than 60 cities. Has that continued at its pace that it was at last year? Has it slowed down at all? And at what point is most of the network core already built and you’ve really flipped to more kind of success-based fiber CapEx once you get beyond the core build?

Kyle Malady’s Answer:

We’re getting there on the core build. I’d say maybe 80% there roughly. And now it’s more connecting in a lot of markets. It’s more connecting the cell sites into it and making what we call laterals. So building the fiber laterals to cell sites or what have you and connecting back to the core. So we got two or three more years left on our fiber build here. And then primarily, it will be just success-based builds.

Verizon launched its One Fiber initiative in 2016, unifying its fiber planning and purchasing for both wireless and wireline into a single program. It initially announced a six-year, $300 million project in Boston, eventually outlining ambitions to add fiber to more than 60 markets outside of its ILEC footprint.

Speaking in May 2019 during the Wireless Infrastructure Association’s Connectivity Expo, Verizon SVP Adam Koeppe said:

We’ve made a conscious effort to really pair our wireless engineering with a fiber engineering process and what that’s allowed us to do is pursue over 60 markets around the country. We’re going to actually be building fiber into the footprint and, you know, truthfully, serving our own needs if you will from a frontal and backhaul perspective. That’s a very integrated engineering process that creates tremendous synergy on our end and allows for very rapid deployment.

Regarding Verizon’s 5G Home (fixed wireless access or FWA) expansion, Malady said:

Now that we have millimeter wave and C-Band spectrum, I feel confident that we can do this. And I feel confident we can do this in a good way, a way that is consistent with the quality people have come to rely on Verizon for. So we’re going to engineer this right. We have enough spectrum to do it. And I’m excited about the possibilities for us from a — meeting customers where they want to be. And without this millimeter wave and C-Band, we couldn’t have been able to support this kind of use case.

Besides the consumer market for 5G Home, SMB seems to be kind of a no-brainer. If we make it easy to use, if we make it easy to buy and set up and utilize, people will probably figure out ways to use that we haven’t even thought of yet. So I do think it’s something that will be used across the board. You could use it (5G Home) at Wells Fargo. You could use them in ATMs. You can use the service for a whole host of things, if you make — if it’s easier to use, more reliable, good price point. So if the value is there, I think people will use it no matter kind of — no matter what segment of the economy they are in. So — but obviously, we’re a heavy Consumer company, and that’s where we’re going to start.

Malady added he expects Verizon’s fiber experience to give it a competitive edge in the FWA arms race with rivals like T-Mobile. “Having been in the FiOS game for a long time we understand what works, what doesn’t work, how to set things up, the customer support, all the different angles. So I do believe that having experience with FiOS is absolutely going to translate over to what we do with 5G Home.”


Verizon Communications Inc. at Wells Fargo Virtual Media & Telco Day: 5G & Streaming & Beyond on June 07, 2021 / 1:30PM

For fiber and small cells, Verizon follows an ‘integrated engineering process’ (

Verizon’s ‘One Fiber’ Scam for 5G Wireless: Did Verizon Fool the Public and Investors? | by bruce kushnick | Medium


Qualcomm introduces 7 new chips to power IoT installations

Qualcomm has released a new range of cellular connectivity modules for IoT devices. The seven new products range from entry-level to premium tier to expand access to a variety of industrial and commercial applications, including transportation and logistics, warehousing, video collaboration, smart cameras, retail and healthcare.

Qualcomm senior director of product management Nagaraju Naik said that the new chips are a comprehensive offering from entry-level to high-end products that meet the needs of a broad range of IoT solutions.  Naik said that the high-end chips in particular will support video collaboration with support for high-resolution cameras and image signal processing for electronic pan, tilt and zoom actions.

“Companies need highly capable cameras and AI compute capability and connectivity to provide these services,” he said.

The chips can support a variety of activities, according to the company, including:

  • Integrated connectivity
  • Sensor fusion
  • Person identification and detection
  • Object detection
  • Edge interaction
  • Activity analysis
  • Personalization

Naik said the chips also can support modern warehouse management from inventory management to package delivery to driver safety and productivity. In a warehouse environment, the entry-level chip can power the handheld device for managing inventory while the high-end chip can run the robot that pulls items.  “All of these scenarios can be supported with the family of products we are introducing today,” Naik said.

Qualcomm also has promised extended life hardware and software options for a minimum of eight years for the new products. All of the new chips are available now except the QCM 6490.

The Qualcomm QCS8250 is the premium-tier offering, optimized to enable maximum performance at the greatest power efficiency possible for intensive AI at the edge. It comes with support for Wi-Fi 6 and 5G, with the Qualcomm Kryo 585 CPU architecture, latest Qualcomm AI Engine and an image signal processor to support up to 7 concurrent cameras with 4K resolution at 120 frames per second. The new Neural Processing Unit supports AI and machine learning for products such as smart cameras, video collaboration, AI hubs, connected healthcare and smart retail.

The next tier is the Qualcomm QCS6490 and QCM6490, also with global 5G connectivity and Wi-Fi 6E, and available from the second half of this year. These come with the Kryo 670 CPU architecture targeting industrial and commercial IoT applications such as transportation, warehousing, connected healthcare, logistics management and POS kiosks. The models can support triple ISPs and advanced edge-AI based on the 6th generation Qualcomm AI Engine.

The Qualcomm QCS4290 and QCM4290 are aimed at mid-tier devices, running the Kryo 260 CPU and 3rd generation Qualcomm AI Engine. This platform supports LTE Cat13 and is ready for upgrade to Wi-Fi 6.

For the entry-level market, the company has the Qualcomm QCS2290 and QCM2290 with LTE connectivity and memory support for low power consumption. Equipped with the Cortex A53 CPU architecture, this cost-effective solution is aimed at retail point-of-sale, industrial handheld, tracking and camera applications.

Customers supporting the new modules include Arrow Electronics, Zebra, Amtran, EInfoChips, Honeywell, Fibocom, Lanotronix and Quectel.



Viasat realizes major milestone for its global satellite broadband plan

Viasat Inc. today announced the first satellite in its ViaSat-3 global constellation has reached a major milestone with completion of payload integration and performance testing, and shipment to the Boeing Satellite Systems facility in El Segundo, Calif.   That satellite constellation will serve the Americas and the surrounding oceans regions. Launch is targeted for early calendar year 2022.

“This is an incredibly exciting time for Viasat as the first of the three high-powered ViaSat-3 satellites in our global constellation enters the final stages of production,” said Dave Ryan, president, Viasat Space & Commercial Networks. “Once complete, we will be ready to put the world’s highest-capacity single satellite into geostationary orbit to serve the world by delivering broadband to the hardest-to-reach areas anywhere — on the ground, in the air and at sea.”

Each ViaSat-3 satellite is expected to generate over 20kW of payload power, making it among the highest-power commercial satellites ever built. Just three of these satellites will cover nearly the entire globe, and are expected to deliver over 3,000 Gigabits per second (Gbps) of capacity — or 3 Terabits per second (Tbps) total — for 15 years or more.

The ViaSat-3 constellation is anticipated to have roughly eight times more capacity than Viasat’s current fleet combined. Vast amounts of bandwidth are needed to address increased demand for high speed internet access — particularly in the video streaming realm. ViaSat-3 represents a major advancement in Viasat’s mission to extend broadband internet service to the many places around the world that don’t have it.

Ryan added, “While the payload was assembled at Viasat’s Tempe, AZ facility, the effort was company-wide. From Tempe, to the antenna expertise in Duluth (GA), to Germantown (MD) for their software and systems engineering know-how and other offices around the world from Chennai, India to Lausanne, Switzerland as well as at our Carlsbad headquarters, all of these teams worked together to come up with a totally unique way to not only build this spacecraft, but to test it in record time.”

Viasat plans to launch and operate two more ViaSat-3 satellites that will serve Europe, the Middle East and Africa (EMEA) and the Asia Pacific (APAC) regions. The ViaSat-3 EMEA payload is expected to be delivered to Boeing in the latter part of the company’s fiscal 2022.  That will help Viasat push ahead with plans for a new set of satellites that have been slowed by the pandemic.

“I can’t predict that there won’t be any other COVID impacts,” Rick Baldridge, Viasat’s president and CEO, said on the company’s recent fiscal Q4 2021 earnings call regarding the ViaSat-3 program, noting that the second payload (for the EMEA) region is running about six months behind the first payload for the Americas. “It has definitely hit us pretty hard this last year on that payload.”

Together, the trio of ViaSat-3 satellites is expected to deliver more than 3 Tbit/s of capacity over an anticipated lifespan of at least 15 years. The ViaSat-3 constellation is expected to support about eight times more capacity than Viasat’s current satellite broadband fleet combined, the company said.

That will also be coming together amid a race to deliver satellite broadband services on a global scale. SpaceX’s Starlink service, still in beta, is progressing with a plan to launch and operate thousands of low-Earth orbit (LEO) satellites.

Last month, Viasat asked the FCC to stay an April 27 order granting SpaceX’s application to modify its LEO system until a court reviews Viasat’s request for an environmental review of Starlink’s expanding constellation of broadband satellites.

“The Commission has violated the National Environmental Policy Act (NEPA) by failing even to assess the environmental impact of both deploying thousands of satellites into low-Earth orbit (LEO) and then having those satellites ultimately disintegrate into the atmosphere,” Viasat argued in its filing. “Because the Order will allow SpaceX to cause immediate and irreparable harm to Viasat and the public at large, the Commission should stay the Order until judicial review is complete.”

About Viasat:

Viasat is a global communications company that believes everyone and everything in the world can be connected. For 35 years, Viasat has helped shape how consumers, businesses, governments and militaries around the world communicate. Today, the Company is developing the ultimate global communications network to power high-quality, secure, affordable, fast connections to impact people’s lives anywhere they are—on the ground, in the air or at sea. To learn more about Viasat, visit:, go to Viasat’s Corporate Blog, or follow the Company on social media at: FacebookInstagramLinkedInTwitter or YouTube.



NeoPhotonics CFP2-DCO Module Transmission of 400Gbps over 1500 km

Optical components maker NeoPhotonics said it was able to transmit data at 400 Gbps over a distance of 1500 km, using its Multi-Rate CFP2-DCO coherent pluggable transceivers, in a 75 GHz-spaced DWDM network.

The demonstration was done in NeoPhotonics Transmission System Testbed using production modules with enhanced firmware and 19 in-line erbium-doped fiber amplifiers (EDFA).

To achieve 1,500 km reach and a 400G data rate, the modules were operated at 69 Gbaud using 16 QAM modulation. NeoPhotonics added that the modules each consumed considerably less electrical power than line card systems operating at comparable data rates and distances. These 400G CFP2-DCO coherent pluggable transceiver modules use NeoPhotonics Indium Phosphide-based coherent components, along with its ultra-narrow linewidth tunable laser. These components include Class 40 CDM, Class 40 Micro-ICR and Nano-ITLA.

These 400G CFP2-DCO coherent pluggable transceiver modules use NeoPhotonics high performance Indium Phosphide-based coherent components, along with its ultra-narrow linewidth tunable laser. These components are all shipping in high volume into multiple coherent system applications, and include:

  • Class 40 CDM: NeoPhotonics Class 40, polarization multiplexed, quadrature coherent driver modulator (CDM) features a co-packaged InP modulator with a linear, high bandwidth, differential driver, and is designed for low V-Pi, low insertion loss and a high extinction ratio. The compact package is designed to be compliant with the form factor of the OIF Implementation Agreement #OIF-HB-CDM-01.0.
  • Class 40 Micro-ICR: NeoPhotonics Class 40 High Bandwidth Micro-Intradyne Coherent Receiver (Micro-ICR) is designed for >60 GBaud symbol rates. The compact package is designed to be compliant with the OIF Implementation Agreement OIF-DPC-MRX-02.0.
  • Nano-ITLA: NeoPhotonics Nano-ITLA is based on the same proven and reliable high performance external cavity architecture as NeoPhotonics’ industry leading Micro-ITLA and maintains comparable ultra-narrow linewidth, low frequency phase noise and the low power consumption in a compact package approximately one half the size.

NeoPhotonics Multi-Rate CFP2-DCO modules are fully qualified. Telcordia testing has been successfully extended to 2000 hours of High Temperature Operating Life (HTOL) testing, showing the high reliability and performance of NeoPhotonics CFP2-DCO platform.

Multi-Rate CFP2-DCO modules supporting Metro (64G baud/DP-16 QAM) and Long Haul (64 G baud/DP-QPSK) applications are shipping in General Availability.

“Coupled with our recent demonstration of 800 km 400 Gbps transmission using our 400ZR+ QSFP-DD, our CFP2-DCO 400G 1500 km transmission brings the use of pluggable modules in regional and long haul networks closer to reality,” said Tim Jenks, Chairman and CEO of NeoPhotonics. “The ability to implement a long haul coherent transponder in the size and power envelope of a pluggable module is a testament to the progress that has been made in photonic integration and DSP development, and has the potential to be a game changer for telecom as well as DCI networks,” concluded Mr. Jenks.

June 8, 2021 Update:

NeoPhotonics announced that its QSFP-DD and OSFP 400ZR pluggable modules are in General Availability and shipping to customers.

These products utilize NeoPhotonics Silicon Photonics Coherent Optical Subassembly (COSA) and low power consumption, ultra-narrow linewidth Nano-ITLA tunable laser, combined with the latest generation of 7 nm node DSP (digital signal processing) technology, to provide full 400ZR transmission in a standard data center QSFP-DD or OSFP form factor that can be plugged directly into switches and routers. This greatly simplifies and cost reduces data center interconnect (DCI) networks by enabling the elimination of a layer of network equipment and a set of short reach client-side transceivers, and paves the way for similar benefits in metro networks.

These 400G modules are compliant with the OIF 400ZR Implementation Agreement and are interoperable with other manufacturers’ 400ZR modules that utilize a standard forward error correction (FEC) encoder and decoder.  These modules are capable of tuning to and transmitting within 75 GHz or 100GHz spaced wavelength channels, as specified in the OIF agreement, and operate in 400ZR mode for Cloud DCI applications.  For longer metro reaches, the modules are designed to support 400ZR+ modes.

NeoPhotonics QSFP-DD and OSFP modules have completed reliability qualification and have passed 2000 hours of High Temperature Operating Life (HTOL) as well as other critical tests per Telcordia requirements.

The company recently announced that it had used its QSFP-DD coherent pluggable transceiver to transmit at a 400 Gbps data rate over a distance of 800 km in a 75GHz-spaced DWDM system with more than 3.5 dB of OSNR margin in the optical signal while remaining within the power consumption envelope of the QSFP-DD module’s power specification.

“This demonstration of high data rates over longer distances shows the potential of these game-changing products, and we expect to see increasing deployment of coherent pluggable modules with different use cases, from data center interconnect to metro and regional applications as well as 5G wireless backhaul,” said Tim Jenks, Chairman and CEO of NeoPhotonics.  “Since the beginning of coherent transmission, NeoPhotonics has been at the forefront in meeting the volume needs of our customers, as is indicated by our recent announcement that we had shipped a cumulative total of more than two million ultra-narrow linewidth tunable lasers,” concluded Mr. Jenks.

About NeoPhotonics:

NeoPhotonics is a leading developer and manufacturer of lasers and optoelectronic solutions that transmit, receive and switch high-speed digital optical signals for Cloud and hyper-scale data center internet content provider and telecom networks. The Company’s products enable cost-effective, high-speed over distance data transmission and efficient allocation of bandwidth in optical networks. NeoPhotonics maintains headquarters in San Jose, California and ISO 9001:2015 certified engineering and manufacturing facilities in Silicon Valley (USA), Japan and China. For additional information visit


BofA on 5G Use Cases and Industry Vertical Applications


The 5G journey is only just beginning and the shape of its implications are barely visible, but the anticipation among industry participants is palpable. Bank of America (BofA) telecom analyst David Barden examines 5G use cases across different industry verticals. Examples span across Healthcare, Industrials, Energy and Consumer just to name a few.

While there is not a “killer app” for 5G yet, BofA expects the app economy to develop the right applications over time as 5G networking deployment and phone adoption is stimulated by the generational tech war between U.S. and China.

Long-term possibilities include doctors performing remote surgeries, flying cars, haptic bodysuits that fully immerse you in the game world, machines proactively monitoring and warning of breakdowns and predictive maintenance, automated loading at warehouses and smart grids for utility providers.  Other examples are included in this excerpt from BofA’s global research report.

5G in the wild:

Over the last year, the 5G conversation has evolved from What is 5G? to Why do we want it? to What do you do with 1Gbps speed? What you do with that kind of speed, latency and connectivity capability is push massive amounts of information across a vast number of devices very fast. One example relevant to the drone and auto industries is the notion of beyond the line of sightTake an example where metro traffic cameras can collect and process sensor information from an entire city and feed it directly into your car so your car already knows there is a stopped vehicle in the middle of the road one mile ahead of you on your planned route and adjusts accordingly.

Examples are endless, and are as big as one can dream  think remote surgeries performed by doctors thousands of miles away due to the power of robotics while using 5G powered medical devices and a lightning fast network, 5G-empowered flying vertical takeoff and landing (VTOL) cars, connected diapers, haptic bodysuits that fully immerse you in your game world, beyond just looking but also now feeling.

While it is still tough to conceive of the killer 5G app that will drive adoption, there is no shortage of people thinking about it. Based on a recent McKinsey study (The 5G Era), companies are willing to adopt to 5G in order to enable new standard use cases or to comply with future connectivity standards. And these new standard use cases are expected to drive 5G IoT unit sales over the next decade. Below, we survey different industry verticals (from healthcare to industrials, energy to consumer) and specific use cases that may utilize this next generation of connectivity most heavily today and how they may evolve.

Sizing the IoT opportunity:

In the next few exhibits, we will look at the potential market size and economics of 5G-powered IoT technology. By comparing the IoT addressable market in various industry verticals side-by-side we found that while the Consumer IoT market would grow to be the largest IoT market vertical at about $142b in 2026, it would be growing at the slowest rate of 17%. The Internet of Medical Things (IoMT) Market closely trails Consumer IoT as the second largest market opportunity, with market size that iexpected to reach around $123b in 2026 but growing at a faster rate of 27.2%. The industrials IoT market would be growing by far the fastest with a CAGR of 79.1%, but off of a relatively small base of just $500m in 2020.

We note that the consumer IoT market is currently the largest as the term IoT broadly covers a wide array of devices that range from smartphones and fitness wearables, to end-use applications such as in-car entertainment, traffic management, connected cars, home automation and more. It is the vertical that is furthest along the adoption curve in the IoT spacethereby explaining the slower-than-peers projected growth rate. Because consumer use cases have been most widely covered in our previous reports, we focus on commercial 5G and IoT use cases in this report.

The consumer vertical would be the largest IoT Market

Albeit slowest growing at 17%

In $ millions

Exhibit 1: For an accessible version Merrill clients call 800-637-7455; Merrill Edge Self-Directed clients call 877-653-4732

Source: Market Research Engine report from 2019




The industrials IoT market is the smallest today

Growing the fastest vs. peers at 79.10%

In $ millions

Exhibit 2: For an accessible version Merrill clients call 800-637-7455; Merrill Edge Self-Directed clients call 877-653-4732

Source: MarketandMarkets report from February 2021




The energy IoT market is expected to reach about $75b by 2026

It is expected to grow at 25.05% CAGR through 2026

In $ millions

Exhibit 3: For an accessible version Merrill clients call 800-637-7455; Merrill Edge Self-Directed clients call 877-653-4732

Source: Facts & Factors research report from March 2021




Internet of Medical Things market would be growing at 27.20%

It is expected to reach $156b by 2027

In $ millions

Exhibit 4: For an accessible version Merrill clients call 800-637-7455; Merrill Edge Self-Directed clients call 877-653-4732

Source: Acumen research and consulting report from December 2020




Revolutionizing healthcare with 5G:

5G will play a pivotal role in shaping tomorrows healthcare infrastructure. The common use cases for 5G in healthcare can be broadly bucketed into two key areas 1) providing connectivity everywhere to enable the omnipresence of telemedicine and 2) powering the Internet of Medical Things (IoMT).

Enabling the omnipresence of telemedicine:

The adoption of telemedicine has been accelerating due in part to the COVID-19 pandemic. Based on a market report by ReportLinker in April 2020, the telehealth market is expected to grow at a 29%+ CAGR from 2019 to 2025. Following the outbreak of the COVID-19 pandemic, telehealth has transformed from nice-to-have to a necessity as traditional healthcare providers encourage patients with mild to moderate illnesses to be treated virtually rather than via in-person visits. The latest McKinsey study titled Telehealth: A quarter-trillion-dollar post-COVID-19 reality? estimates that up to $250b of current US healthcare spend could be virtualized.

Based on data from FAIR Health from December of 2020, a nonprofit manages the nations largest database of privately billed healthcare insurance claims, telehealth claimincreased 2,980% nationally from September 2019 to September 2020, albeit from a small base (0.16% in 19 of total claims to 5.07% in 20). According to Center of Disease Control and Prevention (CDC) data, during the beginning stages of the pandemic last March, telehealth visits increased 154% compared to same period in 2019. CDC used data collected from the major participants in the space such as Teladoc (Ticker: TDOC), Amwell (Ticker: AMWL), MDLive and Doctor On Demand.

With accelerating adoption, a fast and reliable network that can support near real-time, HD video without congestion has become pertinent. Todays broadband speeds and coverage are sufficient to address the majority of the use cases within the population. Remote areas and physicians, however, will need access to reliable connections sooner rather than later. As applications and technical requirements in telemedicine grow more robust, 5G will play a critical role in enabling the need for speed and applications at the edge.

Carrier efforts:

In addition to providing the connectivity part of telemedicine carriers have introduced solution suites to make the experience more seamless for end users.

Verizon announced BlueJeans Telehealth in April 2021. The platform offers a holistic suite of telehealth solutions that will address two key concerns which are 1) ease of use, and 2) security (i.e. HIPPA compliance and more)The platform offers a one-click, download-free telehealth platform that powers the patient experience from onboarding to education.

AT&T’s Business segment has announced a partnership with VitalTech, a virtual care and remote patient monitoring company. The partnership offers 60 days of free telehealth services through VitalCare to AT&T business customers, such as hospitals, to support physicians and patients.

Empowering the Internet of Medical Things (IoMT):

What is the Internet of Medical Things? It is a blanket term for all medical devices and applications that can be connected to healthcare ITThe adoption of connected medical devices is becoming embedded in healthcare providers buying decisions at the marginOne trend in the healthcare space is the blossoming of outcome-based contracts (OBC). According to an industry survey done by Avalere Health, 59% of payers executed an OBC in 2019 vs. 24% in 2017. In this type of contract, med-tech buying agreements will be tied to whether specific clinical or economic outcomes are met, with provisions for profit sharing. In some cases, the agreement may be priced on the value provided for the patient (i.e. treatment outcome vs. cost of delivering the respective outcome).

Remote patient monitoring is expected to grow at a CAGR of 19.7% through 2028

It is expected to reach $4b by 2028

In $ millions

Exhibit 7: For an accessible version Merrill clients call 800-637-7455; Merrill Edge Self-Directed clients call 877-653-4732

Source: Grand View Research Report from January 2021


Beyond patient monitoring, an increasing number of connected medical devices are enabling the ability to generate, collect, analyze and transmit health care data and images to healthcare providers. PTC, a major player in the IoT space, sells ThingWorx, an IoT platform that can be embedded into virtually any medical device. The possibilities are endless. As an example, Sysmex, a manufacturer of hematology analyzers, wanted to create a smaller, faster and more agile blood analyzer.

Leveraging PTCs ThingWorx, Sysmex created Sysmex XW-100, a smart, connected blood analyzer that not only is smaller and more easily deployable, it also enables blood test results to be delivered for same day diagnosis and rapid response.

The broad adoption of IoMT would lead to more accurate diagnoses, fewer mistakes and a lower cost-of-care in the long term. 5G and edge computing are essential for accommodating the volume of data generated by IoMT devices as the number sensors and endpoints increases alongside adoption among care providers and patients alike.

Other use cases for 5G in healthcare:

The examples shared above are the most concrete and immediately monetizable market opportunities in 5G-powered healthcare solutions thus far. There are additional emerging opportunities that will require the capacity and low-latency that 5G can provide including the following.

Healthcare AR/VR: 5G will enable VR/AR clinician training and patient care. As an example, AT&T is collaborating with VITAS Healthcare to study the effect of 5G-enabled AR/VR on hospice patients. By using calming content via 5G-enabled VR/AR, the study tested whether certain patients were able to experience lower pain and anxiety.

Transferring and processing of ultra-high resolution medical imageryPET scans can generate up to 1GB of information per patient per study. 5G networks will enable instantaneous transmission of large data sets generated from MRIs and PET scans.

Robotic surgery (?)There are many benefits to robotic surgeries, especially in the case of minimally invasive procedures. Robotic surgery is done with more precision, smaller incisions, reduced blood loss, less pain, and quicker healing time. The global robotic surgery market is expected grow at 14.79% CAGR from 2020 to reach $6.5b by 2024, with a focus on developing low-cost robotic surgical systems. At the scale it operates today, it is still relatively costly compared to traditional methods. 5Gs ultra-low latency is crucial (with zero margin for error), however, in enabling robotic surgeries as they will require massive data transmission, image processing and analysis across large distances at very low latency.

5G transforming industrials

Enterprise 5G applications can provide proactive asset management to directly create value for manufacturers. 5G may be used to connect low-power sensors to machinery and machinery parts, enabling factories, airlines, automakers, and other industrial operators to proactively monitor and manage equipment repairs and replacements. Data collected from the sensors is transmitted via the 5G network to processors with machine learning algorithms to predict the future behavior of the equipment. For example, if a tractors engine begins overheating, sensors would sense the rising temperature and relay the message to the monitoring processors, which would then alert the operator of a potential breakdown before any serious damage occurs. Proactive management of assets can reduce total capex spending in the long run by extending the life of assets.

Why not WiFi? A McKinsey study found that within factories and plants generally speaking, currently available connectivity option have several major shortfalls, making 5G necessary in order to implement the next generation of technology and Fourth Industrial Revolution (4th IR) use cases. Wi-Fi networks often experience interference, especially when sensors and agents grow in mass quantities. Wired connections, while reliable, are not as agile.

A recent survey conducted by Nokia where it interviewed a thousand key stakeholders in IT across the US and UK found that in terms of 5G functionality, video-related use cases are the most common across various business to business (B2B) and business to consumer (B2C) verticals. For example, 75% of businesses surveyed are currently using video for monitoring purposes. With 5G, each end point could be empowered and connected with video and analytics functions. Simple as that sounds, video married to analytics can function as a sensor to detect defects in a factory or monitor any industrial operation via real-time detection of objects, risks, and incidents. As the number of endpoints grow, 5G will be the critical backbone due to the need for uninterrupted connectivity that can handle massive amounts of data traffic.

The manufacturing vertical currently has one of the highest awareness level of 5G and has ventured into advance uses cases such as remote machine control and robotics, a trend that has been accelerated due to the COVID-19 pandemic. In Exhibit 8 below, we see how 5G enables the fourth industrial revolution across a range of applications within industrials by satisfying the applications technical requirements across reliability, security, speed, latency, data volume, and density.

5G, AI, and IoT will transform factory floors with predictive maintenance

Minimizing downtime is a huge part of cost control for manufacturers. Furthermore, unplanned downtime can cost up to 9x more than planned downtime. Imagine a scenario where a machine in a high speed assembly line breaks down, the entire production line will halt until the machine is fixed. Studies shows that the cost of machine failing in such a scenario can be more than $10,000 per minute.

The historical way of preventing unplanned downtime was to schedule routine maintenance which also incurs spending in the form of maintenance costs rather than repair costs. This is where advanced predictive maintenance powered by 5G would solve both problems.

By equipping the factory floor with sensors and agents at each endpoint, machine conditions may be monitored in real time and advanced diagnostics may be run to both avoid break-fix events but also unnecessary preventative maintenance spending. 5G is critical to power these sensors because advance analytics will run along dozens of parameters when monitoring assets such as temperature, vibration, humidity, pressure, and many more. The data needs to be holistic and complete in order for connected devices to accomplish whats promised making the size of the data a challenge to transmit and process in real time, necessitating the promise of 5G.

Ericsson is one of the most advanced 5G users in manufacturing. In 2018, Ericsson partnered with Audi to roll out and run field tests for various industrial applications in the Audimanufacturing headquarters in Ingolstadt, Germany in a smart factory named the Audi Production LabIn Ericssons factory in Nanjing, the company has approximately 1,000 high-precision screwdrivers that require routine calibration and lubrication based on utilization. This has been a high-touch manual process historically which required manual documentation. By fitting these tools with real time motion sensors that analyze collected data, the factory was able to replace manual tracking with an automated solution to cut the manual workload by 50% and is planning on phasing out manual tracking entirely in the future.


5G can enable precision manufacturing like never before

The availability of advanced, predictive analytics in machinery extends an assets life and lowers the cost for factories, but the real lever for increasing productivity is precision monitoring and control enabled by 5G. With this technology, the entire production process is monitored in real time. 5G connectivity will allow machines to feed real time data back to applications that have machine learning and AI functionality to analyze an item currently in production and compare it to the planned model for any discrepancies. By recognizing when a machine is not working optimally and re-calibrating accordingly to maintain cycle speeds, based on research done by a survey done by STL Partners with manufacturers in August of 2019, manufacturers believe machine productivity could improve by 15% on average.

The concept of precision monitoring is easy to grasp and can transform the way factories run quality control. In order for this model to work properly, ultra-low latency is required (sub 10 milliseconds) due to the need for constant data collection and comparison to the digitally planned model at each sensor endpoint.


This BofA research report continues, but we will end here in deference to BofA clients.

For more information on BofA Global Research:

For another analyst firm point of view:


Russia Joint Venture with Beeline, Rostelecom and Megafon to focus on 5G spectrum

Russian network operators Beeline, Rostelecom and Megafon have agreed they will own own equal stakes in their joint venture New Digital Technologies. The joint venture will focus on the release of spectrum for 5G services, including 694-790 MHz, 3.4-3.8 GHz, 4.4-4.99 GHz and 24.25-29.5 GHz bands.

The agreement was signed under the framework of the St Petersburg International Economy Forum.  See hyperlink to 5G Russia video below.

Russia’s Federal Antimonopoly Service (FAS) had given ‘preliminary consent’ to this agreement as reported on May 12th.  In a disclosure on its website, the FAS said:

The agreement on joint activities, if implemented, stipulates equal access to radio frequencies for all participants in the mobile wireless communication.

In particular, the mobile network operators involved in the transaction will develop and agree with the antimonopoly authority on the conditions for the use of the infrastructure and/or the joint use of radio frequencies and the conditions for the provision of infrastructure for mobile virtual network operators*.

Taking into account the guarantees provided for the access of mobile network operators to the released radio frequency spectrum, the FAS Russia approved the transaction.

According to the antimonopoly authority, the access to the released radio frequency spectrum for construction of the 5G networks and the subsequent provision of 5G mobile wireless communications is an opportunity to provide a new generation of communication services on the territory of the Russian Federation.

* A mobile network operator that implements the business model of mobile wireless communications using the nodal elements of the communication network of other mobile network operators.

Russian network operator MTS will not participate in this joint project.  However, MTS has launched its pilot 5G network in St Petersburg. Broadband at up to 1.5 Gbps speed is available at 16 crowded locations in the city, as well as in the town of Kronshtadt in the St Petersburg region.


You can watch a June 3rd video (no sound for 1st 7 1/2 minutes) of “5G: The Architecture Backbone of Russia’s Digitalization” from the St Petersburg Forum  here.

One speaker said that 5G will have a very long time horizon. In Moscow, 5G will have a circle of people or narrow audience which will help pay for the 5G infrastructure buildout.  Also, private 5G industrial solutions will develop in the largest Russian companies.  Global competition will drive those companies to offer 5G.   We’ll see…


Separately, Rostelecom has opened a new data center located in the Kalininsky district of St. Petersburg, the 4,000 sq m (43,000 sq ft) facility is built to Tier-III standards and has a total capacity of 800 racks and a capacity of 7.4MW.

The company said the facility will offer hosting, cloud services, as well as redundancy and disaster recovery services in tandem with its data centers in Moscow and Udomlya.







Posted in 5G

AWS deployed in Digital Realty Data Centers at 100Gbps & for Bell Canada’s 5G Edge Computing

I.  Digital Realty, the largest global provider of cloud- and carrier-neutral data center, colocation and interconnection solutions, announced today the deployment of Amazon Web Services (AWS) Direct Connect 100Gbps capability at the company’s Westin Building Exchange in Seattle, Washington and on its Interxion Dublin Campus in Ireland, bringing one of the fastest AWS Direct Connect [1.] capabilities to PlatformDIGITAL®.  Digital Realty’s platform connects 290 centers of data exchange with over 4,000 participants around the world, enabling enterprise customers to scale digital business and interconnect distributed workflows on a first of its kind global data center platform.

Note 1. AWS Direct Connect is a cloud service solution that makes it easy to establish a dedicated network connection from your premises to AWS. This can increase bandwidth throughput and provide a more consistent network experience than internet-based connections.


As organizations bring on new technologies and solutions such as artificial intelligence (AI) and IoT at scale, the explosive growth of digital business is posing new challenges, as data takes on its own gravity, becoming heavier, denser, and more expensive to move.

The new AWS Direct Connect 100Gbps is tailored to providing easy access to larger data sets, enabling high availability, reliability and lower latency.  As a result, customers will be able to move bandwidth-heavy workloads seamlessly – and break through the barriers posed by data gravity.  Customers gain access to strategic IT infrastructure that can aggregate and maintain data with less design time and spend, enabling access to AWS with one of the fastest and highest quality AWS network connections available.

As an AWS Outposts Ready Partner, Digital Realty’s global platform is optimized to support the needs of data-intensive, secure hybrid IT deployments.  Digital Realty supports AWS Outposts deployments by enabling access to more than 40 AWS Direct Connect locations globally to address local processing, compliance, and storage requirements, while optimizing cost and performance. When coupled with the availability of AWS Direct Connect 100Gbps connections, the Westin Building Exchange and Interxion Dublin campuses become ideal meeting places for customers to tackle data gravity challenges and unlock new opportunities with their AWS Outposts deployments.

“As emerging technologies such as AI, VR and blockchain move from the margins to the mainstream, enterprises need new levels of performance from their hybrid solutions,” said Tom Sly, General Manager, AWS Direct Connect.  “Deploying AWS Direct Connect at 100Gbps at Digital Realty facilities in Seattle and Dublin is critical to our strategy of helping customers build more sophisticated applications with increased flexibility, scalability and reliability.  We’re excited to see the value Digital Realty’s PlatformDIGITAL® delivers for our mutual customers.”

The Westin Building Exchange serves as a primary interconnection hub for the Pacific Northwest, linking CanadaAlaska and Asia along the Pacific Rim.  The building is one of the most densely interconnected facilities in North America, and is home to leading global cloud, content and interconnection providers, housing over 150 carriers and more than 10,000 cross-connects, giving Amazon customers low-latency access to the largest companies and services representing the digital economy.  The 34-story tower is adjacent to Amazon’s existing 4.1 million square foot campus in Seattle.

Digital Realty offers six colocation data centers in the Irish capital, which forms a strategic bridge between Europe and the U.S.  Ireland has particular significance as a global trading hub and provides the headquarters location for several global multinationals within the software, finance and life science industries.  Multiple transatlantic cables also land in Ireland before continuing to the UK or continental Europe, making Interxion Dublin a prime location for the new AWS Direct Connect 100Gbps at the heart of a vibrant connected data community.

“Today’s announcement of the opening of AWS Direct Connect 100Gbps on-ramps significantly expands opportunities for customers to scale their digital transformation through our global PlatformDIGITAL®,” added Digital Realty Chief Technology Officer Chris Sharp.  “AWS serves some of the world’s most innovative and demanding customers, from start-up to enterprise, that are looking to drive the digital economy forward.  Our platform expands the coverage, capacity, and next-generation connectivity that AWS customers need to extend workloads to the cloud rapidly.  We are honored to open up next-generation access in collaboration with AWS and specifically at the heart of the rich digital communities at the Westin Building Exchange and on our Interxion Dublin campus.”

The new deployments create centers of data exchange in Network Hubs deployed on PlatformDIGITAL®, enabling distributed workflows to be rapidly scaled and securely interconnected – reducing operating costs, enhancing visibility, saving time and improving compliance.  The new capability also gives AWS customers instant access to a growing list of powerful AWS services such as Blockchain, Machine Learning, IoT and countless others – all over a direct, private connection optimized for high performance and security.

AIB, Inc., a leading data exchange and management firm with a software as a service platform deployed at over 1,600 automotive industry customers, recognized the value of deploying a physical Network Hub on PlatformDIGITAL® coupled with a virtual direct interconnection to AWS to enable flexibility in its hybrid IT environment.

“Our Texas-based operations required new cloud zone diversity solutions for our cloud native national vision.  Digital Realty provided an innovative and comprehensive solution for AWS cloud access through PlatformDIGITAL®,” said Kellen Dunham, CTO, AIB, Inc.

Digital Realty’s global platform enables low-latency access to both the nearest AWS Region as well as a wide array of options to connect edge deployments or devices.  Customers can securely connect to their desired AWS Region using both physical and virtual connectivity options.  Globally, PlatformDIGITAL® offers access to more than 40 AWS Direct Connect locations, including 11 in EMEA, providing secure, high-performance access to numerous AWS Outposts-Ready data centers around the world.  In addition, the Digital Realty Internet Exchange (DRIX) supports AWS Direct Peering capabilities and dedicated access to multiple third-party Internet Exchanges on PlatformDIGITAL®, providing a direct path from on-premise networks to AWS.  The solution is part of PlatformDIGITAL®’s robust and expanding partner community that solves hybrid IT challenges for the enterprise.

About Digital Realty:
Digital Realty supports the world’s leading enterprises and service providers by delivering the full spectrum of data center, colocation and interconnection solutions.  PlatformDIGITAL®, the company’s global data center platform, provides customers a trusted foundation and proven Pervasive Datacenter Architecture (PDx™) solution methodology for scaling digital business and efficiently managing data gravity challenges.  Digital Realty’s global data center footprint gives customers access to the connected communities that matter to them with 290 facilities in 47 metros across 24 countries on six continents.  To learn more about Digital Realty, please visit or follow us on LinkedIn and Twitter.

Additional Resources:


II.  Bell Canada today announced it has entered into an agreement with Amazon Web Services, Inc. (AWS) to modernize the digital experience for Bell customers and support 5G innovation across Canada. Bell will use the breadth and depth of AWS technologies to create and scale new consumer and business applications faster, as well as enhance how its voice, wireless, television and internet subscribers engage with Bell services and content such as streaming video. In addition, AWS and Bell are teaming up to bring AWS Wavelength to Canada, deploying it at the edge of Bell’s 5G network to allow developers to build ultra-low-latency applications for mobile devices and users. With this rollout, Bell will become the first Canadian communications company to offer AWS-powered multi-access edge computing (MEC) to business and government users.

“Bell’s partnership with AWS further heightens both our 5G network leadership and the Bell customer experience with greater automation, enhanced agility and streamlined service options. Together, we’ll provide the next-generation service innovations for consumers and business customers that will support Canada’s growth and prosperity in the years ahead,” said Mirko Bibic, President and CEO of BCE and Bell Canada. “With this first in Canada partnership to deploy AWS Wavelength at the network edge, where 5G’s high capacity, unprecedented speed and ultra low latency are crucial for next-generation applications, Bell and AWS are opening up all-new opportunities for developers to enhance our customers’ digital experiences. As Canada recovers from COVID-19 and looks forward to the economic, social and sustainability advantages of 5G, Bell is moving rapidly to expand the country’s next-generation network infrastructure capabilities. Bell’s accelerated capital investment plan, supported by government and regulatory policies that encourage significant investment and innovation in network facilities, will double our 5G coverage this year while growing the high-capacity fibre connections linking our national network footprint.”

The speed and increased bandwidth capacity of the Bell 5G network support applications that can respond much more quickly and handle greater volumes of data than previous generations of wireless technology. Through its relationship with AWS, Bell will leverage AWS Wavelength to embed AWS compute and storage services at the edge of its 5G telco networks so that applications developers can serve edge computing workloads like machine learning, IoT, and content streaming. Bell and AWS will move 5G data processing to the network edge to minimize latency and power customer-led 5G use cases such as immersive gaming, ultra-high-definition video streaming, self-driving vehicles, smart manufacturing, augmented reality, machine learning inference and distance learning throughout Canada. Developers will also have direct access to AWS’s full portfolio of cloud services to enhance and scale their 5G applications.

Optimized for MEC applications, AWS Wavelength minimizes the latency involved in sending data to and from a mobile device. AWS delivers the service through Wavelength Zones, which are AWS infrastructure deployments that embed AWS compute and storage services within a telecommunications provider’s datacenters at the edge of the 5G network so that data traffic can reach application servers within the zones without leaving the mobile provider’s network. Application data need only travel from the device to a cell tower to an AWS Wavelength Zone running in a metro aggregation site. This results in increased performance by avoiding the multiple hops between regional aggregation sites and across the internet that traditional mobile architectures require.

Outside of the AWS Wavelength deployment, Bell is also continuing to evolve its offerings to enhance its customers’ digital experiences. From streaming media to network performance to customer service, Bell will leverage AWS’s extensive portfolio of cloud capabilities to better serve its tens of millions of customers coast to coast. This work will allow Bell’s product innovation teams to streamline and automate processes as well as adapt more quickly to changing market conditions and customer preferences.

“As the first telecommunications company in Canada to provide access to AWS Wavelength, Bell is opening the door for businesses and organizations throughout the country to combine the speed of its 5G network with the power and versatility of the world’s leading cloud. Together, Bell and AWS are bringing the transformative power of cloud and 5G to users all across Canada,” said Andy Jassy, CEO of Amazon Web Services, Inc. “Cloud and 5G are changing the business models for telecommunications companies worldwide, and AWS’s unmatched infrastructure capabilities in areas like machine learning and IoT will enable leaders like Bell to deliver new digital experiences that will enhance their customers’ lives.”

Launched in June 2020, Bell’s 5G network is now available to approximately 35% of the Canadian population. On February 4, Bell announced it was accelerating its typical annual capital investment of $4 billion by an additional $1 billion to $1.2 billion over the next 2 years to rapidly expand its fibre, rural Wireless Home Internet and 5G networks, followed May 31 by the announcement of a further up to $500 million increase in capital spending. With this accelerated capital investment plan, Bell’s 5G network is on track to reach approximately 70% of the Canadian population by year end.

5G will support a wide range of new consumer and business applications in coming years, including virtual and augmented reality, artificial intelligence and machine learning, connected vehicles, remote workforces, telehealth and Smart Cities, with unprecedented IoT opportunities for business and government. 5G is also accelerating the positive environmental impact of Bell’s networks. The Canadian Wireless Telecommunications Association estimates 5G technology can support 1000x the traffic at half of current energy consumption over the next decade, enhancing the potential of IoT and other next-generation technologies to support sustainable economic growth, and supporting Bell’s own objective to be carbon neutral across its operations in 2025.

About Bell Canada:
The Bell team builds world-leading broadband wireless and fiber networks, provides innovative mobile, TV, Internet and business communications services and delivers the most compelling content with premier television, radio, out of home and digital media brands. With a goal to advance how Canadians connect with each other and the world, Bell serves more than 22 million consumer and business customer connections across every province and territory. Founded in Montréal in 1880, Bell is wholly owned by BCE Inc. (TSX, NYSE: BCE). To learn more, please visit or

Bell supports the social and economic prosperity of our communities with a commitment to the highest environmental, social and governance (ESG) standards. We measure our progress in increasing environmental sustainability, achieving a diverse and inclusive workplace, leading data governance and protection, and building stronger and healthier communities. This includes confronting the challenge of mental illness with the Bell Let’s Talk initiative, which drives mental health awareness and action with programs like the annual Bell Let’s Talk Day and Bell funding for community care, research and workplace programs nationwide all year round.


Comment and Analysis:

AWS already has an edge compute footprint that covers parts of Asia, Europe and North America. AWS, Google Cloud and Microsoft Azure increasingly (unsurprisingly) look like the real power brokers and empire builders in multi-access/mobile edge computing.  Rogers and Telus, Bell’s two main rivals. will likely contract with one of the three big cloud service providers for their 5G edge computing needs.