SK Telecom, Intel develop low-latency technology for 6G core network
In collaboration with Intel, SK Telecom (SKT) has successfully developed technology to reduce communication delays necessary for the evolution of 6G Core Network Architecture. The Core network is the gateway through which all voice and data traffic generated from a customer’s mobile device passes through to access the Internet network. It is a mobile communication service system that is responsible for security and service quality through the inter-connection of various systems.
Editor’s NOTE: Of course, 6G is currently undefined with only the features and functions being defined by ITU-R WP 5D which is meeting this week in Geneva. The 6G core network specifications will be done by 3GPP and NOT ITU-T as was the case for 5G core.
…………………………………………………………………………………………………………..
The 6G Core Architecture is required to have higher flexibility and safety than previous generations of wireless communications, and to provide stable AI service quality and technologies to customers by embedding intelligent and automation technologies.
As Core network technology continues to develop, the various systems that make up the network and the detailed functions that provide various services are also explosively increasing. As network complexity continues to increase, the process of sending and receiving messages is frequently recreated. Therefore, communication delays will increase compared to before. It is difficult to address these limitations with communication standard technologies (service communication proxies) for interconnection between unit functions within the existing Core network.
Inline Service Mesh, a low latency technology the two companies developed utilizing Intel Xeon processors with built in AI, is capable of increasing the communication speed within the Core network by reducing latency between unit function without Proxy.
Through this technology development, AI, which requires a large amount of computation, can be applied to the Core network in a wider variety of models. SKT has already commercialized a technology that reduces wireless resources by 40% and improves connectivity by analyzing movement patterns of real users in real time. Through this cooperation, the two companies will be able to reduce communication delays by 70% and increase service efficiency by 33% in the Core network through the application of the 6G Core Architecture.
SKT aims to apply the results of this study to commercial equipment next year. A technical white paper has been published by Intel that describes the technology, development process and benefits.
SKT and Intel have been continuing to cooperate for research on the development of key wired/wireless mobile communication technologies for the past 10 years. Based on the results of this study, the two companies plan to continue research and development for traffic processing improvement technologies incorporating AI technology in various areas of the Core network.
“We have made another technical achievement through continuous technology development cooperation with Intel to secure leadership in 6G,” said Yu Takki, Vice President and Head of Infra Tech at SKT. “We will continue our research and make efforts to commercialize AI-based 6G Core Architecture.”
“Our research and development efforts with SK Telecom continue to deliver innovations that have been deployed by Communications Service Providers worldwide”, said Dan Rodriguez, Corporate Vice President of Intel Network & Edge Solutions Group. “By leveraging the latest Intel Xeon processors with built in AI features, our companies are able to drive both performance and efficiency improvements that will be vital to the future Core networks.
Last March, SKT and NTT DOCOMO released a white paper addressing the requirements for future 6G networks.
The South Korean carrier said the new white paper contains its views on 6G key requirements and 6G evolution methodology, along with its opinions on the latest trends in frequency standardization. The 6G white paper also provides analysis, development directions and methodologies pertaining to promising 6G use cases, technology trends as well as and candidate frequencies.
The 6G White Paper reviews the following:
- Performance requirements and implementation scenarios for each frequency band, taking into account the characteristics of each frequency
- Issues concerning coverage and devices in high-frequency bands
- Standardization for migration to 6G architecture and application of cloud-native / open architecture
References:
https://www.sktelecom.com/en/press/press_detail.do?idx=1597¤tPage=1&type=&keyword=
NTT DOCOMO & SK Telecom Release White Papers on Energy Efficient 5G Mobile Networks and 6G Requirements
https://www.docomo.ne.jp/english/corporate/technology/rd/docomo6g/whitepaper_dcmskt.html#title02
Research on 6G is gaining momentum, and governments worldwide are contemplating how this next-generation mobile standard aligns with their broader technology roadmaps.
China outlined its vision in a 6G white paper published back in 2021 titled, “6G Vision and Candidate Technologies,” targeting a 2030 launch. In 2023, the government of India announced plans to prepare the operators for commercial 6G by 2030.
The South Korean government aims to have commercial 6G networks operational by 2028, two years ahead of the International Telecommunication Union’s scheduled approval for the 6G standard. As the industry grapples with defining the roles of AI, Cloud radio access network (RAN), automation and ESG in the 6G era, we will stay away from the shiny objects and focus on the basics: what spectrum will be utilized for 6G and why ongoing RF innovation is crucial for transforming 6G from a concept into reality within the next five to six years.
The journey toward 5G-Advanced and eventually 6G will not be trivial. It depends on a confluence of factors, with the type of spectrum being one of the more critical unknowns that can completely change the trajectory and velocity of the entire 6G ramp. After all, the 5G capital expenditure (capex) envelope would look entirely different if not for the large swaths of spectrum in the upper mid-band, coupled with mMIMO.
Figure 1
Figure 2 5G/6G spectrum chart.
Presently, the prevailing notion is that the 6 GHz band and the centimeter wave (cmWave) spectrum will play pivotal roles as anchor bands in the 6G era with frequencies spanning from 6.4 to 15.3 GHz. This band will be akin to the functions carried out by the C-Band in the 5G era. Concurrently, the mmWave spectrum transitions from a backseat position in 5G to a potential passenger seat with 6G in this multi-layered spectrum approach, encompassing new and existing sub-7 GHz, cmWave and mmWave spectrum.
However, achieving economic viability for the broader 6G coverage layer complicates the situation and poses challenges with small cell infrastructure. Consequently, the 6 to 15 GHz base stations will need to make use of the existing macro grid. Ideally, future mmWave systems will also increasingly leverage the macro infrastructure for MBB applications.
As the saying goes, nothing in this world can be said to be certain, except death, taxes and the inevitability of greater propagation losses with rising frequencies. According to the Hata model for a medium-sized city, the received power drops by approximately 7 dB when comparing the 6 GHz band with the C-Band. Another loss of approximately 7 dB occurs at 12 GHz in comparison to 6.5 GHz.
In essence, RF innovation becomes crucial for operators aiming to deploy large bandwidth and wide area 6G in new spectrum. At a broader level, there are three main efforts already part of the 5G journey, including boosting the RF output power, adding more transceivers and incorporating more antenna elements. For 6G deployments within the upper 6 to 15 GHz range, advancing mMIMO becomes indispensable to achieve equivalent upper mid-band coverage. Leading vendors are currently exploring configurations such as 128T/128R or 256 transceiver channels to compensate for different loss parameters. Though it is still early days, preliminary testing shows promise. For instance, Huawei has verified in small-scale tests that the propagation delta between the 6 GHz and C-Band is manageable with higher-order MIMO.
So far, mmWave deployments have primarily centered around FWA and low-mobility MBB applications, partly due to challenges related to coverage and performance degradation in higher-mobility scenarios. In response, technology leaders are now boosting the EIRP to tackle coverage limitations. One of the suppliers has already verified that co-site deployments with macros using 70 dBm+ EIRP and intra-band coordination with sub-6 GHz spectrum, can deliver Gbps performance throughout the cell. More innovation is also required to smooth out the handovers. Notably, the UL is typically the limiting factor and more work is needed to address the approximately 20 dB gap between the mmWave bands and the C-Band.
https://www.microwavejournal.com/articles/41451-6g-and-the-long-rf-journey-ahead#new_tab
Wireless network operators would merely be substituting one vendor for another, rather than expanding the selection, if latency was reduced. The consolidation that occurred years ago demonstrated that the global RAN market, which supported low-cost mobile utilization at scale, could not accommodate more than a few vendors. Today, there are only a handful, which are: Huawei, Ericsson, Nokia, ZTE, and Samsung. Fujitsu and NEC have market share in Japan but few other countries.
https://techblog.comsoc.org/2024/08/19/delloro-ran-market-still-declining-with-huawei-ericsson-nokia-zte-and-samsung-top-vendors/