SK Telecom and Deutsche Telekom Cooperate on 5G/ICT to combat COVID-19 Pandemic

SK Telecom held a video conference with Deutsche Telekom to deepen the two companies’ cooperation in information and communication technologies (ICT) to alleviate challenges caused by the coronavirus (COVID-19) pandemic.

Several executives of the two companies gathered for a video conference on Wednesday and discussed their cooperation on 5G network, mobile edge computing and artificial intelligence technology.   SK Telecom said it would also share its experience of COVID-19 countermeasures, including remote work solutions and online recruitment procedures.

The South Korean telecom firm added that it was going to dispatch a group of engineers to Germany to share their know-how in managing 5G network infrastructure, as well as measures to handle heavy traffic loads on communications networks. The two companies also discussed measures to improve cloud-delivered solutions to prepare for the post-coronavirus world.

SK Telecom and Deutsche Telekom have been working closely since 2016 to lead innovations in ICT. SK Telecom has been sharing its diverse fixed and wireless technologies with Deutsche Telekom.

Especially, with the outbreak of the novel coronavirus throughout the globe, network infrastructure and online solutions are becoming ever more important to seamlessly support people’s new way of living. In response to this, executives from SK Telecom and Deutsche Telekom discussed detailed plans to utilize their innovative ICT, including 5G, artificial intelligence (AI) and mobile edge computing (MEC), to help improve the current situation and thoroughly prepare for the post-coronavirus era.

SK Telecom CEO Park Jung-ho poses for pictures after the video conference between the South Korean telecom firm and Deutsche Telekom on Wednesday last week. (SK Telecom)

SK Telecom CEO Park Jung-ho poses for pictures after the video conference with  Deutsche Telekom 

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On April 29, 2020, the two companies signed a term sheet for a technology joint venture that will launch within this year. Through this joint venture, SK Telecom and Deutsche Telekom will collaborate to expand the global 5G ecosystem by accelerating 5G deployment in Europe.  SK Telecom has already provided its 5G repeaters to Deutsche Telekom to support its customer trial for 5G indoor coverage in Germany and plans to promote the adoption of its 5G repeaters in Europe. The two companies will also develop diverse MEC use cases and AI-powered solutions including immersive video calling and smart meeting solutions.

Moreover, SK Telecom and Deutsche Telekom agreed to exchange their technological expertise through Network Engineer Exchange Program once the situation improves. Through the program, SK Telecom’s network engineers will be dispatched to Germany to share their knowhow in 5G network commercialization and operation, as well as their experience in handling data traffic surges caused by a dramatic increase in the number of people working or learning from home.

The two companies also decided to increase Deutsche Telekom Capital Partners’ investment in Korean 5G startups as well as global ventures with competitive online solutions such as video conferencing platforms and cloud call centers.

“The current global crisis can be effectively addressed if we, ICT companies, join forces with our technology and expertise,” said Park Jung-ho, President and CEO of SK Telecom. “SK Telecom will continue to work closely with Deutsche Telekom to flawlessly support our customers in this new normal era brought by the coronavirus.”

About SK Telecom

SK Telecom is Korea’s leading ICT company, driving innovations in the areas of mobile communications, media, security, commerce and mobility. Armed with cutting-edge ICT including AI and 5G, the company is ushering in a new level of convergence to deliver unprecedented value to customers. As the global 5G pioneer, SK Telecom is committed to realizing the full potential of 5G through ground-breaking services that can improve people’s lives, transform businesses, and lead to a better society.

SK Telecom boasts unrivaled leadership in the Korean mobile market with over 30 million subscribers, which account for nearly 50 percent of the market. The company now has 47 ICT subsidiaries and annual revenues approaching KRW 17.8 trillion.

For more information, please contact [email protected] or visit the Linkedin page www.linkedin.com/company/sk-telecom.

Media Contact

Irene Kim

SK Telecom Co., Ltd.

+ 82 2 6100 3867

[email protected]

Reference:

http://www.koreaherald.com/view.php?ud=20200503000101

 

 

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Empowering Low-Power Wide-Area Networks to Meet the IoT Challenge

by Swarun Kumar, PhD, Assistant Professor – Electrical and Computer Engineering,  Carnegie Mellon University (CMU)

Introduction:

The Internet of Things (IoT) is rapidly expanding to connect everyday objects in homes, office buildings, retail stores and factories, impacting sectors as diverse as manufacturing, agriculture and public governance.

While conversations around “5-G and beyond” traditionally focus on faster wireless networks, it is inevitable that the majority of devices connected to future cellular networks will be IoT endpoint.  This is primarily due to their sheer scale of deployment. Indeed, massive Machine Type Communications (mMTC) that seeks to connect billions of low-power IoT devices to the cellular network is a pivotal thrust of the 5G vision.  It is one of three 5G use cases for IMT 2020, the soon to be completed ITU st of standards for 5G radio (ITU-R) and non radio aspects (ITU-T).

Low-Power Wide-Area Networks (LP-WANs) are a leading approach to achieve this objective [1]. LP-WANs allow extremely low power devices connected by 10-year AA batteries to transmit at low speeds (few kbps) to cellular base stations as far as 10 kilometers away. 3GPP’s Narrow Band IoT (NB-IoT) is a leading LP-WAN technology being rapidly deployed for cellular networks.  It has been accepted by ITU-R WP5D as part of the IMT 2020 RIT/SRIT submissions from 3GPP, China, Korea, and TSDSI (India).  Other other LP-WAN technologies in the unlicensed bands such as LoRa and SIGFOX have also attained strong market traction.

WiTech Lab Project: Pushing the Limits of LP-WANS. Photo credit: Carnegie Mellon University

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LP-WAN Performance Analysis:

In reality, there remains a large gap between the promised performance of LP-WANs in theory and their performance on the field, particularly in city environments. At Carnegie Mellon University (CMU), we have built a wide-area LP-WAN testbed in our campus and surrounding neighborhoods, spanning much of the City of Pittsburgh [2].

Our findings show that the range of LP-WANs is significantly impacted by large buildings and obstructions, to often less than a kilometer, providing performance significantly below the 10 kilometer performance advertised in more suburban and rural spaces. More problematic is that LP-WAN performance is further degraded by severe collisions between radios deployed at large scale as they are too energy-starved to coordinate prior to transmission. Further, even minor changes to configuration such as choice of transmit frequency can severely degrade device battery-life if not carefully explored and chosen.  That in and of itself is a battery-intensive task.

Across all these diverse challenges a common thread emerges – devices in LP-WANs are too simple and energy-starved to make complex Physical layer decisions that impact their performance, scalability and battery life.  That includes capabilities that have been taken for granted in the traditional mobile phone context.

Our work at the Emerging Wireless Technologies Lab (WiTech) lab at CMU has sought to build next-generation LP-WANs that obtain substantial improvements in range, scale and battery life. Our strategy has been to push complex Physical layer functionalities from the end-user devices to the base station infrastructure and the cloud.

We maintain that redirection of Physical layer functions benefits LP-WANs in three pivotal ways:

  • First, it frees low-power clients from the burden of signal processing, simplifying their design and reaping associated battery benefits.
  • Second, it allows advanced signal processing and machine learning to be implemented at the much more capable cloud in ways previously never possible at the clients, directly improving end-to-end system performance metrics such as range, scale and battery life.
  • Third, it creates the opportunity for programmability – allowing for new optimizations and new services such as location-tracking, sensing, data analytics and beyond to be implemented as software updates in the cloud rather than requiring the deployment of new hardware.

Our results on a 10 square kilometer testbed in the City of Pittsburgh [2] have demonstrated several benefits of our methodology over the years to tackle diverse and fundamental problems in LP-WANs, which have greatly improving scale (by 6x [4]), range (by 3x [1]) and battery life (by 3x [5]) when compared to the state-of-the-art.

Our research work has resulted in several publications [2,3,4,5] at top research venues, including two best paper award winners [2,3].

Expanding the Range Limits of LP-WANs:

Our approach is best understood by focussing our attention on a specific problem – how do we expand the range of LP-WANs particularly in urban settings where their range is extremely limited by buildings that heavily attenuate wireless signals?

The fundamental problem is that the LP-WAN signals from clients deep inside buildings are too weak to decode at any base station, even if within close proximity. Our solution relies on the multiplicity of LP-WAN gateways, specifically with the rapid deployment of femtocells in the cellular context, on street lamps and traffic lights and beyond.

We seek to transfer received signals across base stations to the cloud.  Those signals may be individually weak, yet can collectively be coherently combined at the cloud to result in a much stronger signal that can be decoded.

This principle closely mirrors the CloudRAN model which seeks to offload computation at the base stations to the cloud. Yet, a key problem remains in the low-power IoT context – how do base stations know which signals to ship to the cloud if an LP-WAN signal is too weak and noisy to be detected at any base station?

Simply transmitting all received signals to the cloud will be expensive in terms of backhaul bandwidth and immensely wasteful. Our scheme is to build a mechanism to make more intelligent predictions about the presence of weak LP-WAN signals buried underneath the noise at the base stations. We do this by looking for unique and telltale patterns in the noise that correspond to the signal structure of LP-WAN packets. Different from prior work that only looks for these patterns in the preamble (i.e. the beginning) of LP-WAN transmissions, our solution scans the entire packet resulting in greater accuracy.

We further improve our methodology by letting base stations collaboratively share news about packet detection. For instance, if a weak signal from a transmitter is detected by the base station, it alerts its neighbors to transmit signals received at about the same time to the cloud.

Our experiments revealed significant improvements in the range of LP-WANs by a factor of 3x through a wide-area demonstration at Pittsburgh. [That work received the best paper award at ACM/IEEE IPSN 2018 [2] – a major international conference.]

Scaling LP-WAN Deployments:

Beyond physical range, LP-WANs also need to perform at massive scale.  ITU has set lofty goals for mMTM communications of as many as a million devices per square kilometer. At these massive scales, LP-WAN devices are likely to interfere with each other rampantly, causing massive data loss.

In part, this is because inexpensive and battery-hungry devices traditionally do not take the classic “listen before you transmit” approach to take turns and therefore lack a mechanism to realize that they are producing interference.

Our solution to address this challenge of rampant interference in LP-WANs at scale turns the low cost of LP-WAN hardware to our advantage. Specifically, we observe that the transmissions from cheap LP-WAN devices often have unique imperfections, such as shifts in frequency or time, depending on hardware manufacturing defects. These defects can then be used as filters to separate signals from multiple devices that interfere with each other.

Given the traditionally narrow bandwidth of LP-WANs, this approach allows us to massively scale up the number of devices that can concurrently transmit. Our paper in SIGCOMM 2017 reports an overall 6-fold improvement in the scale of LP-WAN networks compared to the state-of-the-art.

Maximizing the Battery Life of LP-WAN Devices:

Perhaps the most important requirement of LP-WANs is the need to maximize battery-life. A key selling point of LP-WAN is the ten-year battery life that allows for most consumers of IoT devices to simply not worry about maintenance or recharging of batteries through the lifetime of the device.

Our research has shown that this battery-life cannot be taken for granted, even if the devices are installed statically at a fixed location for the duration of its life. For instance, our work in NSDI 2020 [5] has shown that carefully selecting the frequency of operation of a device can substantially improve the battery life of a device, by 230%, rather than choosing a default frequency.

We presented a method and mechanism to intelligently configure LP-WAN devices using intelligence at the cloud, without requiring any advanced computation at the devices themselves, barring the occasional transmission of a beacon packet. Our award-winning paper at IPSN 2020 [3] also showed how teams of individually wimpy LP-WAN devices can collectively convey useful information without draining the battery of each device significantly.

More importantly, such information can be conveyed very quickly within the duration of one LP-WAN packet to then be processed by machine learning algorithms running on cloud resident compute servers. We showed how such a system could have wide-ranging applications from diagnosis of faults in sensor networks to rapid and large-scale spatial tracking of wildfires.

The Future of IoT is in the services it enables:

While much of our research to date has focussed on delivering the energy consumption and communication performance that LP-WANs promise, we believe that LP-WANs can play a pivotal role in shaping the applications that IoT will enable in the future.

Imagine, a postage-stamp sized device that can be used to track the physical location of packages deployed anywhere in the world. Consider how swarms of IoT devices deployed in the city can collectively measure and model vibrations from earthquakes.

Future Work of CMU WiTech lab:

Funded by the prestigious CAREER award from the National Science Foundation, we at the CMU WiTech lab are currently working on intelligently processing LP-WAN signals in the cloud to take a step toward these applications and beyond. We are further devising mechanisms to improve the security and privacy of user data in a world where IoT devices are everywhere around you.

More broadly, we believe that next-generation cellular networks, beyond serving as communication pipes, have the potential to actively shape the applications of the future in the emerging IoT era.

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References:

[1] LPWAN to Application standardization within the IETF, Alan J Weissberger, 2019,
https://techblog.comsoc.org/category/lpwans/
[2] Charm: Exploiting Geographical Diversity Through Coherent Combining in Low-Power
Wide-Area Networks , Adwait Dongare, Revathy Narayanan, Akshay Gadre, Artur Balanuta,
Anh Luong, Swarun Kumar, Bob Iannucci, Anthony Rowe, IPSN 2018 (Best Paper Award)
[3] Quick (and Dirty) Aggregate Queries on Low-Power WANs, Akshay Gadre, Fan Yi, Anthony
Rowe, Bob Iannucci and Swarun Kumar, IPSN 2020 (Best Paper Award)
[4] Empowering Low-Power Wide Area Networks in Urban Settings , Rashad Eletreby, Diana
Zhang, Swarun Kumar, and Osman Yagan, SIGCOMM 2017
[5] Frequency Configuration for Low-Power Wide-Area Networks in a Heartbeat, Akshay Gadre,
Revathy Narayanan, Anh Luong, Swarun Kumar, Anthony Rowe and Bob Iannucci, NSDI 2020

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About Swarun Kumar:

Swarun Kumar, PhD is an Assistant Professor at Carnegie Mellon University’s ECE department.  His research builds next-generation wireless network protocols and services. Swarun leads the Emerging Wireless Technologies (WiTech) lab at CMU.  He is a recipient of the NSF CAREER and Google Faculty Research awards.

Dr. Kumar received the George Sprowls Award for best Ph.D thesis in Computer Science at MIT and the President of India gold medal at IIT Madras.

Photo of Swarun Kumar, PhD and Assistant Professor at CMU

 

China Mobile and Huawei deploy 5G base station at 6,500m on Mt Everest!

China Mobile and Huawei have together built the highest elevation 5G (or any other) base station on this planet– at 6500 meters (21,300 feet) at Mount Everest where there are no roads or trails. [Note that the summit is 8,848 meters, but will be measured again this year].

The base station along with two others at lower elevations, will enable China Mobile to run its 5G wireless network on the world’s highest mountain.  It will surely be a great aid to climbers which had to previously use satellite phones for ultra high altitude communications with their high camps.

Zhou Min, general manager of Tibet branch of China Mobile, said the facility will ensure reliable telecommunication for the activities of mountain climbing, scientific research, environmental monitoring and high-definition live streaming. The building of 5G infrastructure is in tandem with the measuring of the height of the peak, which officially started on Thursday.

“It comes on the 60th anniversary of the first successful ascent of Mount Everest from the northern slope and the 45th anniversary of China’s first official accurate measurement of Mount Everest,” declared the press release. “Significantly, the 5G network on Mount Everest will provide communication services for the 2020 Mount Everest re-measurement.”

How high is Mount Everest in meters, feet, km & miles

The base station launch marks the 60th anniversary of the first successful ascension of Mount Everest from the northern slope. Base stations are now at the Mount Everest Base Camp at 5,300 metres, the Transition Camp at 5,800 metres, and the Forward Camp at 6,500 meters.

A China Mobile technician told state media that the new 5G network is fast enough for climbers and scientists to have 4K and VR live streaming on the mountain.

Huawei’s 5G AAU and SPN technologies were applied at the base stations, managed and maintained by a dozen network specialists stationed there 24/7 at altitudes of 5,300 meters and above.

Huawei claims that its 5G AAU is highly integrated into a compact size, making it easy for deployment and installation and it fits particularly well for infrastructure in extreme environments such as Mount Everest. In this project, a network in the “stand-alone plus non-stand alone” (SA+NSA) mode connects five 5G base stations.Meanwhile, the 5G connectivity is achieved by Huawei’s Massive MIMO technology.

Huawei’s Massive MIMO comes with three-dimensional narrow beams. At an altitude of 5,300 meters, the 5G download speed exceeded 1.66 Gbps, where the upload speed tops 215 Mbps, claims Huawei. Some of the other technologies being employed by the Chinese telecom equipment giant are Intelligent OptiX Network and HoloSens intelligent video surveillance system.  The 5G base station at Everest base camp includes a Gigabit ONT, Huawei’s 10G PON OLT and 200G ultra-high-speed transmission platform, and the HoloSens intelligent video surveillance system.

Pictures of 5G Base station at 6500 meters   Photo credits: Huawei

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The press release concluded as follows:

Huawei strongly believes that technology means to make the world better.  The beauty of Mount Everest can be displayed via 5G high-definition video and VR experience, which also provides further insights for mountaineers, scientists and other specialists into the nature. The ground-breaking establishment on Mount Everest once again proves that 5G technology connect mankind and the Earth harmoniously.

References:

https://www.huawei.com/en/press-events/news/2020/4/china-mobile-huawei-deliver-world-highest-5g

https://www.bloombergquint.com/technology/5g-signal-now-available-on-mount-everest-peak

https://timesofindia.indiatimes.com/gadgets-news/china-mobile-and-huawei-establish-worlds-highest-5g-site-on-mount-everest/articleshow/75493507.cms

 

 

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