Over the years we have looked at the standards development, infrastructure development and even country specific mission critical solutions development in various blog posts. In this post we are sharing this short new tutorial by Mpirical on mission critical services in LTE and 5G. The video is embedded below:
At DEF CON 31 last year, Tracy Mosley, Vulnerability Researcher at Trenchant presented a talk titled "Nothin’ but a G Thang - The Evolution of Cellular Networks" (background of title). The abstract of the talk says:
In this talk we will walk through each step of cellular evolution, starting at 2G and ending at 5G. The never-ending attack and defend paradigm will be clearly laid out. In order to understand the attack surface, I’ll cover network topology and protocol. For each cellular generation, I will explain known vulnerabilities and some interesting attacks. In response to those vulnerabilities, mitigations for the subsequent cellular generation are put in place. But as we all know, new mitigations mean new opportunities for attackers to get creative. While I will explain most cellular-specific terminology, a familiarity with security concepts will help to better understand this talk. Basic foundations of communications systems, information theory or RF definitely make this talk more enjoyable, but are absolutely not necessary. It’s a dense topic that is highly applicable to those working on anything that touches the cellular network!
PAULEY are a dynamic UK-based SME at the forefront of the exciting emerging market in big data and interactive tools for business. Pioneers in Spatial Computing, our specialist team are working with clients operating in key industries and sectors including transport, safety critical industries and the education and training sector, to embed innovative digital technology into their business processes.
At Athonet's Uptime 2022 conference, Phil Pauley, CEO at Pauley Interactive, spoke about real-life deployment of Digital Twin and Private Cellular at St Pancras railway station. His talk is embedded below:
There is another playlist shared on PAULEY's YouTube channel that us embedded below:
The Project Coordination Group (PCG) of 3GPP recently approved a new logo for use on specifications for 6G, during their 52nd PCG meeting, hosted by ATIS in Reston, Virginia. As with previous logos, surely people in general will use them not just for 3GPP 6G compliant products, but for all kinds of things.
Over the years many people have reached out to me to ask for 3GPP logos, even though they are available publicly. All 3GPP logos, from 3G to 6G is available in the Marcoms directory here. In addition to the logo, each directory also lists guidance for use of the logos. For example, 3GPP does not allow the use of the logo as shown on the left in the image on top of the post while the one on the right is okay.
Surely there isn't an issue for general use but for anyone wishing to use the logos for their products, equipment, documentation or books, they will have to strictly comply with the rules.
theNetworkingChannel hosted another interesting webinar recently exploring the topic of how Quantum Internet is emerging and has many open directions, from disruptive and long-term ideas to concrete applications that can be explored with real devices today.
The panel consists of distinguished experts, including:
Bernardo Huberman – Fellow and Vice President of Next – Gen Systems – CableLabs – USA
Marcello Caleffi – Professor – University of Naples “Federico II” – Italy
Stephan Ritter – Director of Applications of Quantum Technologies – TOPTICA Photonics AG – Germany
Stefano Pirandola – Founder and CEO – nodeQ – Professor – University of York – UK
The webinar description stated:
As Quantum Key Distribution (QKD) technology approaches maturity, the scientific community is now turning its attention to more advanced applications of quantum networks at metropolitan and international scales, such as distributed/delegated quantum computing and quantum sensor networks, requiring end-to-end entanglement of qubits, quantum memories, and varying degrees of fault tolerance. To make a leapfrogging advance, the co-existence of upcoming quantum networks with classical networks is also becoming more focal, with a significant impact at the physical level (i.e., the sharing of a telco fiber or rack space in an exchange point) and from a logical perspective (i.e., the integration with control/management planes of an Internet Service Provider or the interplay with classical jobs to be executed in a High-Performance Computing infrastructure). In this panel, we will discuss the research and development trends currently occupying the top positions of the priority list to make the Quantum Internet a real thing, with a tangible impact on industry, science, and society.
Key Takeaways:
The webinar looked at Quantum physics principles, such as superposition and entanglement, underlie the technology and have led to exciting developments, including the potential for quantum computers to solve complex problems and enable secure communication. Quantum entanglement can be used to coordinate parties without communication, enabling secure auctions and frequency hopping spread spectrum technology, which has been around since the 1950s.
Early Applications and Challenges:
Frequency hopping, used for secure communications since the 1950s, faces issues with machine learning-based attacks due to predictable sequences.
QKD offers a solution by enabling Alice and Bob to coordinate using truly random, provably secure sequences.
Despite its potential, building a quantum internet faces practical hurdles, including high implementation costs.
Quantum Internet Architecture: Revolution Over Evolution:
The panel debated whether the Quantum Internet should evolve from classical networks or be a complete revolution. The consensus leaned toward a full redesign, requiring a new protocol stack rather than incremental updates.
Entanglement is the core resource, unlike classical information, as it requires coordinated multi-node operations.
Technologies and Prototypes:
Quantum memories rely on specific lasers to manipulate qubits, and wavelength conversion techniques are being developed for compatibility.
A prototype network is under construction, aiming to demonstrate teleportation and blind quantum computation by the decade’s end.
The Quantum Internet Alliance (QIA) launched the QIA Technology Forum (QIATF) to foster collaboration among academia, industry, and ecosystem partners.
Quantum Teleportation and Distributed Computing:
Quantum teleportation enables remote quantum computers to exchange qubits by sharing entangled states.
This is fundamental for distributed quantum computing, where multiple machines collaborate remotely.
Achieving a hybrid Quantum Internet will require interfaces (e.g., electro-optical converters) to connect diverse quantum systems like photonic, superconducting, and solid-state qubits.
Commercialisation and Future Outlook
Quantum-secured communications for military use could emerge in 10–15 years.
A full-fledged Quantum Internet could take 25 years, comparable in scale to the classical internet.
Gradual progress is expected, with significant quantum computing milestones in 5–10 years.
While the slides have not been shared, the video of the webinar is embedded below:
I am fascinated by and have previously written blog posts about transparent antennas. Back in 2019 NTT Docomo announced that they have been working with glass manufacturer AGC to create a new transparent antenna that can work with a base station to become an antenna. Then in 2021, NTT Docomo and AGC announced that they have developed a prototype technology that efficiently guides 28-GHz 5G radio signals received from outdoors to specific locations indoors using a film-like metasurface lens that attaches to window surfaces. Transparent antennas/lens are one of the pillars of Docomo’s 6G vision as can be seen here.
I succeeded in my quest to find a wow product finally at #MWC24. Wavethru by AGC is an amazing solution for densification by providing coverage inside-out. Lookout for a post on the Telecoms Infrastructure blog in a few weeks time #3G4G5Gpic.twitter.com/RmuD1NQ7nS
Every year at Mobile World Congress I look for a wow product/demo. While there were some that impressed me, the suite of products from Wave by AGC (WAVEANTENNA, WAVETHRU and WAVETRAP) blew me away. Let’s look at each of them briefly:
WAVEANTENNA is the transparent glass antenna which is generally installed indoors, on a window or a glass pane. It can be used to receive signals from outdoors (as in case of FWA) or can be used to broadcast signal outdoors (for densification based on inside-out coverage). In the newer buildings that has thermal insulation films on the glass, the radio signals are highly attenuated in either direction, so this solution could work well in that scenario in conjunction with WAVETHRU.
The WAVETHRU process applies a unique laser pattern to the glazing with 30 µm laser engraved lines that are nearly invisible to the naked eye. Treatment is so gentle, it does not affect the physical properties of the glazing, which remain the same. This radio-friendly laser treatment improves the indoor radio signal by around 25 dB, to achieve almost the same level of performance as the street signal. Just 20% to 30% of the window and floors 0 to 4 need to be treated to improve the indoor signal on all frequency ranges under 6GHz.
In case of coverage densification by providing inside-out radio signals, WAVETRAP can be used for EM wave shielding by stopping back-lobes within the building.
This video from WAVE by AGC explains the whole densification solution:
Now the question is, why was I impressed with this solution? Regular readers of this and the Telecoms Infrastructure Blog will have noticed the various solutions I have been writing about for mobile network densification in downtown areas and historic cities with listed buildings where limited space for infrastructure deployment presents several challenges.
In brief, we can categorise these challenges as follows:
Physical Space Constraints like lack of space or strict regulations as in case of listed buildings and heritage sites.
Aesthetics and Visual Impact could be an important consideration in certain historic city centres. Deploying large antennae or towers can clash with the architectural character and heritage of the area and may require concealing antennae within existing structures like chimneys, bus shelters, phone boxes & lampposts, or using disguised designs like fake trees to minimize visual impact.
Technical Challenges can arise in dense urban environments due to interference from neighbouring cells, unreliable backhaul connectivity, interruptions in the power supply due to siphoning, etc.
Community Engagement and Perception is another important area to consider. There is no shortage of NIMBY (Not in my back yard) activists that may oppose new infrastructure due to health concerns, aesthetics, or fear of property devaluation. Engaging with the community, providing accurate information about EMF exposure, and addressing misconceptions are crucial.
Regulatory and Permitting Hurdles that may arise due to many cities and councils imposing zoning and permits requirements. Obtaining permits for infrastructure deployment involves navigating local regulations, zoning laws, and historic preservation boards. There may also be height restrictions that may hinder optimal antenna placement.
Finally, Cost and ROI are important consideration factors as all of the above increases the costs as well as the time required. Customized designs, site acquisition, and compliance with regulations are one of the major factors that not only increase costs but also delays infrastructure rollouts. Operators often weigh the benefits of improved coverage and capacity against all the expenses and headaches of infrastructure deployment and then decide on what to deploy and where.
A solution like WAVEANTENNA in conjunction with WAVETHRU and WAVETRAP can significantly reduce the hurdles and improve coverage significantly.
While I have talked about the solution in general, it can also be applied indoors to Wi-Fi, in addition to 4G/5G. This may be useful in case of Enterprise Networks where appearance is of importance and probably not of much use in case of warehouses or Industrial/Factory Networks.
It's been a while since we covered V2X as a topic on this blog. If you are not well versed with CAVs and V2X, we recommend you to watch our tutorials on the 3G4G page here.
The networking channel hosted a seminar on 'Vehicular networking' last month. Quoting from the webinar preview:
Looking back at the last decade, one can observe enormous progress in the domain of vehicular networking. Many ongoing activities focus on the design of cooperative perception, distributed computing, and novel safety solutions. Many projects have been initiated to validate the theoretic work in field tests and protocols are being standardized. We are now entering an era that might change the game in road traffic management. Many car makers already supply their recent brands with cellular and Wi-Fi modems, also adding C-V2X and ITS-G5 technologies. We now intend to shift the focus from basic networking principles to open challenges in cooperative computing support and even on how to integrate so-called vulnerable road users into the picture. Edge computing is currently becoming one of the core building blocks of cellular networks, including 5G, and it is necessary to study how to integrate ICT components of moving systems. The panellists will discuss from an industrial perspective the main research challenges for the advancement of vehicular networking and the novelties that we can expect to see coming in the short term. Panellists with extensive experience in Internet measurements, networks related to sustainable development goals, and highly-localized earth observation networks will discuss these topics and participate in a Q&A session with the audience.
The presentations were not shared but the video of the panel discussion is as follows:
The following speakers presented the following talks:
Vehicular Networking? by Onur Altintas, Toyota North America R&D (0:04:55)
Collaborative Perception Sharing for Connected Autonomous Vehicles by Fan Bai, General Motors Global R&D (0:15:00)
The future of vehicular networking by Frank Hofmann, Robert Bosch GmbH (0:23:25)
The future of vehicular networks and path to 6G by Dr.-Ing. Volker Ziegler, Nokia (0:35:15)
Peter Rysavy is the president of Rysavy Research LLC, the consulting firm that he has led since 1993, focusing on computer networking, wireless technology, and mobile computing. Recently he did a presentation for Oregon Chapter of IEEE Communications Society (ComSoc). The abstract of the talk states:
Wireless communication is fundamental to our digital society, with radio spectrum the key enabling resource. Understanding the critical role of spectrum provides deep insight into how wireless technologies function and how they will evolve. This enlightening talk delves into the ingenious advancements in Wi-Fi and cellular networks to harness spectrum, including increasing efficiency, deploying new bands, aggregating channels, and dynamically sharing spectrum. Despite huge progress, formidable challenges remain in meeting soaring demands for capacity, achieving global harmonization, and ensuring coexistence with existing services.
Key takeaways:
There is increasing demand for wireless spectrum from technologies like WiFi and 5G cellular networks, but the amount of usable spectrum is finite.
Different spectrum bands have tradeoffs between coverage, capacity, and ability to support new technologies. The mid-band spectrum between 2 and 6 GHz is well-suited for 5G.
Technologies are evolving to use spectrum more efficiently through techniques like carrier aggregation, advanced modulation, massive MIMO, and puncturing in WiFi 7.
The US lacks a clear long-term national spectrum strategy and roadmap, putting it at a disadvantage compared to countries like China, which plan spectrum allocations years in advance.
Spectrum sharing is complex with no one-size-fits-all solution, though approaches like beamforming, dynamic spectrum access databases, and sensing show promise if challenges are addressed.
Harmonizing spectrum use globally through conferences helps drive economies of scale in devices and supports roaming, though the US diverges in some bands like 6 GHz assigned solely to WiFi.
Critical infrastructure requires precise timing to operate. This reliance makes the infrastructure vulnerable to disruptions in timing that can be either intentional or unintentional. Intentional disruptions can be caused by GNSS jamming or spoofing or network attacks.. Unintentional disruptions are usually caused by equipment failures or acts of nature.
Back in April 2022, Alliance for Telecommunications Industry Solutions (ATIS) hosted a webinar on this topic, a precursor to the Annual Workshop on Synchronization and Timing Systems (WSTS). The webinar featured top industry experts delivering insight into the latest techniques for adding resilience and robustness to timing infrastructure. It covered the most critical topics in timing resilience, including:
Redundancy
Holdover
Management
Monitoring
Alternative reference time sources
Examples address networks used for critical industry applications such as:
Power grids
Telecommunications
Finance systems
Broadcast/media
The video of the webinar as follows:
Experts participating in the webinar and their presentations are as follows:
I have been asked about the UE Assistance Information (UAI) RRC message a few times before. Generally I have always pointed people back to the LTE/5G specifications but here is a concise video that the telecoms technology training company Mpirical have shared recently:
If you want to dig further into details then please see the RRC specifications: 36.331 for LTE and 38.331 for 5G.
Over the years I have added quite a few short tutorials from Mpirical on this blog, do check them out below.
