Wireless, 5G
Article | May 18, 2023
5G small cells form the backbone of the modern wireless networks. Learn more about this technology is revolutionizing 5G deployment and enabling various use cases across industries in this article.
Contents
1 Introduction to 5G Small Cells for Modern Businesses
2 5G Small Cells: Overview
2.1 Characteristics of 5G Small Cells
2.2 How Small Cells Fit into 5G Architecture
3 Benefits of 5G Small Cells for Businesses
3.1 Improved Coverage and Capacity
3.2 Enhanced Network Performance
3.3 Lower Latency
3.4 Cost-effectiveness
4 Use Cases for 5G Small Cells
4.1 Urban Areas
4.2 Rural Areas
4.3 Indoor Environments
5 Conclusion
1 Introduction to 5G Small Cells for Modern Businesses
Small cells are low-power radio access nodes that operate in licensed and unlicensed spectrum bands and are typically deployed in areas with high demand for wireless connectivity. They are a vital component of the 5G wireless network architecture and are designed to complement traditional cell towers, providing improved coverage, network capacity, and faster data speeds. Small cells come in several types, including femtocells, picocells, and microcells, and can be deployed according to the use case.
2 5G Small Cells: Overview
2.1 Characteristics of 5G Small Cells
5G small cells are characterized by small form factors and are designed to be compact and discreet for deployment in various settings, such as urban areas, rural areas, indoor environments, and public spaces. In addition, they consume less power than traditional cell towers, making them more energy-efficient. They also operate on high-frequency bands, which enables them to provide faster data speeds and lower latency than traditional cell towers, which makes small cells essential for 5G.
The 5G small cell architecture can be deployed in dense networks, providing better coverage and capacity in areas where traditional cell towers may not be able to reach. Also, a 5G small cell antenna can be configured to provide seamless handoffs between cells, ensuring users have a consistent and uninterrupted wireless experience. These characteristics make them ideal for specific 5G use cases, which will be explored further in the article.
2.2 How Small Cells Fit into 5G Architecture
Small cells and 5G evolution are closely linked, and this technology is an ideal solution for future wireless networks. They offer greater capacity, coverage, and flexibility than traditional cell towers, allowing them to meet the demands of an increasingly connected world.
By operating on high-frequency bands and being deployed in dense networks, small cells in 5G can provide faster data speeds, lower latency, and better coverage than previous generations of wireless networks. Additionally, their small form factor and flexible deployment options allow for use cases like private 5G networks that revolutionize industries.
3 Benefits of 5G Small Cells for Businesses
5G networks will support a massive increase in connected devices, including smartphones, IoT sensors, and other devices. Small cells are critical for achieving the full potential of 5G networks and the exciting new applications and services they will enable.
3.1 Improved Coverage and Capacity
5G small cells offer improved coverage over traditional cell towers in certain situations, particularly in urban areas. Buildings and other obstacles interfere with wireless signals, so the connection quality decreases in areas with such infrastructure. By deploying small cells closer to users, the network can provide better coverage and capacity in these areas.
Small cells can also be deployed indoors, providing better coverage and capacity in buildings and other enclosed spaces. This is important due to poor wireless range, signal interference from walls, and other obstacles. By deploying small cells indoors, the network can provide better coverage and capacity in these areas, improving the overall wireless experience for users.
3.2 Enhanced Network Performance
The deployment of small cells enables network densification, which allows several devices to connect to the network simultaneously. This can help reduce network congestion and improve overall network performance, particularly in urban areas. They can also be configured to provide seamless handoffs between cells, ensuring that users have a consistent and uninterrupted wireless experience. This is important because users often move between different areas with different coverage levels and capacities, providing a streamlined experience.
3.3 Lower Latency
Small cells are designed to operate on high-frequency bands, which enables them to provide faster data speeds and lower latency than prior generations of wireless networks. This is especially important for applications that require real-time communication, such as virtual reality, autonomous vehicles, and remote surgery. By providing faster data speeds and lower latency, small cells can help enhance these applications' performance, providing a better overall user experience.
3.4 Cost-effectiveness
Small cells offer a cost-effective alternative to traditional cell towers, particularly in urban areas with high land and real estate costs. By mounting 5G small cell antennas on existing infrastructure, such as lampposts and buildings, deployment costs can be lowered. Additionally, small cells can be deployed in a modular fashion, allowing for targeted and cost-effective expansion based on the required coverage and capacity. This approach avoids large-scale and expensive deployments of new infrastructure. Moreover, small cells can be powered by low-cost, low-power sources like solar panels or batteries, reducing ongoing operational costs. Furthermore, small cells consume less power than traditional cell towers, resulting in lower energy costs.
4 Use Cases for 5G Small Cells
4.1 Urban Areas
As discussed previously, small cell radio antennas in 5G can improve networks in dense urban environments, alleviating network congestion and improving data speeds. In addition, by deploying small cells in areas with high user demand, network operators can provide targeted coverage and capacity improvements to specific areas, ensuring that users have fast and reliable connectivity.
4.2 Rural Areas
Small cells can be used to extend coverage to underserved or unserved areas by traditional cell towers. They can fill in coverage gaps, providing reliable connectivity to users in rural areas that may not have access to high-quality wireless services. This will enable use cases such as remote workforces in rural areas, smart agriculture, and distance education and training.
4.3 Indoor Environments
Traditional cell towers may not be able to provide reliable connectivity indoors due to physical barriers such as thick walls and ceilings. Small cells can provide targeted coverage and capacity to specific areas, such as conference rooms or shopping malls, where users require high-quality wireless connectivity. In addition to improving range, small cells can help alleviate network congestion and improve data speeds in high-traffic indoor environments.
5 Final Thoughts
Small cells are a crucial element in developing and implementing 5G technology. By leveraging a small form factor and high-frequency band usage, small cells facilitate the deployment of 5G networks in a more cost-effective and targeted manner than traditional cell towers. They support a wide range of use cases by providing reliable and high-quality wireless connectivity to a growing number of devices. They will continue to be a critical technology for businesses and organizations seeking to leverage the benefits of 5G technology.
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Network Infrastructure, Network Management
Article | July 10, 2023
Applications and workloads have been moving to the cloud for some time. This transition has been putting a lot of pressure on IT organizations to support the trend by extending their networks to support cloud connectivity.
Cisco SD-WAN enables your hybrid connectivity to the cloud
We at Cisco have innovated on multiple fronts to help our customers with this transition by providing a deep level of integration with many of the leading cloud service providers (CSPs), including Amazon Web Services (AWS), Microsoft Azure, and Google Cloud. Here, we highlight one key aspect of this innovation that allows private cloud links to be available as part of the SD-WAN network, enabling hybrid connectivity to the cloud and multicloud. Now our customers can benefit from all the rich features that our Cisco SD-WAN solution offers including application-aware routing, intent-based path selection, and security policy enforcement.
Private direct cloud connectivity to CSPs such as AWS Direct Cloud Connect, Google Cloud Interconnect, and Azure ExpressRoute are becoming popular lately, as they provide customers with optimal connectivity similar to what MPLS did in the past, but in a more agile and on-demand fashion. The only problem is those services are normally acquired separately and customers must determine how to manage them as part of a larger WAN solution including configuration, monitoring, and so on. The on-demand nature of these circuits provides customers with major savings, but also turns automation into a key requirement for management.
Enter Cisco SD-WAN release 20.6
Beginning with Cisco SD-WAN release 20.6, a Cisco SD-WAN customer may use Cloud OnRamp for Mutlicloud to automate and simplify cloud connectivity across private and public transports. What is great is this task, that used to require hours and days to setup, now only takes minutes as outlined by the following integration documents for AWS, Azure and Google Cloud respectively:
Configure AWS Direct Connect as a Transport with SD-WAN in a Click
Configure Azure Express Route as Transport with SD-WAN in a Click
Configure Google Cloud Interconnect as a Transport with Cisco SD-WAN in a Click
Once a customer implements such connectivity, they will have the ability to steer any type of traffic through it with a customizable and flexible SD-WAN policy. This solution also allows customers to eliminate some limitations imposed on them by the CSPs, such as restricting the number of prefixes advertised via BGP over private links, thus providing better scalability and control.
For customers who already use Cisco SD-WAN Cloud Interconnect at middle-mile POPs, such as with Equinix or Megaport, rolling out this solution as a test can be extremely simple given the automation discussed above. The best way to find out how easy this solution is, is to try it.
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Enterprise Mobility, Mobile Infrastructure
Article | June 16, 2023
The next phase of our newly redesigned Tableau Partner Network is officially here. Originally announced during the Global Partner Summit at Tableau Conference 2019, and launched in September 2020, we built the Tableau Partner Network (TPN) to enable our global ecosystem to meet evolving customer needs and deliver exceptional customer experiences. The Tableau Partner Network is an analytics-focused ecosystem that complements Salesforce’s partner ecosystem.
With this latest phase, we’ve unlocked new partner branding to showcase our partners’ commitment and expertise. Customers now have a more transparent view of the commitment and quality level of Tableau’s partners by business model track (Reseller, Services, and Technology) and performance level (Premier, Select, and Member), as well as by country groupings versus a single global qualification. These changes make it easier for customers to find and confidently work with the right Tableau partner, knowing they meet Tableau’s standards and are local if desired.
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5G
Article | June 9, 2022
Emerging virtual and hybrid private 5G solutions are enabling communication service providers (CSPs) to address a large number of new consumer and enterprise edge use cases. Each of these edge use cases will require a specific network deployment model and edge user plane connectivity. That’s why we’ve designed our 5G edge user plane to tackle five distinct key capabilities: support of flexible network deployments, 3GPP dual-mode support, integrated Gi LAN services, integrated probing with edge analytics and edge exposure enablement. Let’s dive into this blog post to learn how the powerful 5G edge user plane is unlocking new 5G edge use cases.
How technological innovation creates value and benefits society has always interested me, influencing my work as a mobile network technologist and sales professional. Since mobile data was introduced in late 90s, both mobile network technology and mobile consumer use cases have evolved enormously. Indeed, a rapid increase in connectivity speed and the introduction of smartphones have pushed the market to adopt mobile web and video and create thousands of new applications. However, sometimes ‘killer use cases’ require both business case and application ecosystem maturity. One example is video conferencing, one of the key services 3G was designed for but was only introduced when the over-the-top (OTT) vendors disrupted the content provider market and popularized social media. Creation of mobile technology has indeed its own innovation cycles and research feeds and therefore can't depend on market pull, but you can draw the conclusion that the time to value greatly benefits when the broad business and technology ecosystem in the value chain collaborate and co-create solutions.
Precisely, what’s really exciting about 5G is that it coincides with the maturity of other two disruptive technology enablers for end applications: artificial intelligence (AI) and cloud edge computing. It also comes at a moment when there’s both an urgent need and huge financial support to digitalize society and industry. In fact, more than ever, we are witnessing a close collaboration between technology and business ecosystems. Over the past few years, there have been a large number of public-private consortiums to feed service requirements into 5G standards, explore and validate the value of 5G technology. For example, just to name few, the 5G alliance for connected Industries and automation (5G-ACIA) or European 5G infrastructure Public Private Partnership (PPP) projects. For years, 3GPP standards have been preparing to define advanced 5G connectivity solutions for edge computing and vertical digitalization use cases. In addition, all sorts of consumer and enterprise edge applications are being developed at the same pace in many areas such advanced video processing, AI analytics, immersive gaming, smart grid applications, automated guided vehicles (AGVs) controls or industry automation.
The edge ecosystem is particularly complex and involves different players. One key pillar is the wireless connectivity service CSPs offer. 5G-ACIA introduced the concept of virtual private and hybrid private 5G solutions, two emerging solutions that CSPs are exploring to complement their private 5G network offerings. Such solutions allow CSPs to leverage their existing public networks and offer new services in an agile and cost-effective manner using new 5G capabilities such as network slicing. In order to address edge use cases, virtual and hybrid private 5G solutions need to bring the user plane connectivity to the edge by deploying 5G edge user plane functions.
The 5G edge user plane supports flexible network deployments
One key learning from industry experimentation with 5G is that each use case brings a unique combination of connectivity requirements, in terms of end-to-end performance (uplink and downlink latency, jitter, packet loss and throughput), data privacy and security, robustness, wide vs local area coverage and mobility.
Latency and security requirements drive the selection of the edge location, which can be the enterprise premise, CSP access or regional data center or even the extended public edge such as content delivery networks (CDN) content provider or a hyper cloud provider’s (HCP) edge data center. For example, a mobile gaming application can be located in the CSP regional data center or HCP edge, whereas video processing and AI for a factory automation application is located on the factory premise. Also edge distribution can be accounted by CSP for those use cases which produce significant amount of data such as fixed wireless access (FWA) to optimize backhaul costs.
Ericsson has a vast experience supporting and driving the ecosystem to realize time critical communication use cases at scale and has conducted detailed latency analysis for different type of deployments. The RAN deployment needs to be carefully planned according to the specific use case performance characteristics. Some use cases can be achieved with existing macro RAN environment -4G or non-standalone 5G-, with macro RAN standalone 5G with or without dedicated quality of service (QoS) profiles or even may require network slicing to partition macro RAN. In contrast, some other use cases will need dedicated RAN deployments. In addition, most use cases will benefit from a dedicated edge user plane function, as it provides a higher level of performance and robustness.
In summary, the concrete edge use cases to be offered and CSP’s own solution preferences drive the type of network solution and deployment, which can be a private 5G network, a virtual or a hybrid 5G private network using existing macro or dedicated RAN, with or without network slicing.
The edge 5G user plane function should allow for such deployment flexibility and enable the different edge use cases characteristics. Ericsson Local Packet Gateway (LPG) addresses this by:
Supporting any access technology, radio deployment model and RAN vendor
Seamlessly integrating with Ericsson’s existing dual-mode 5G Core. which is prepared for slicing, efficient routing to edge (also called edge breakout) and advanced QOS and many other 5G edge features described in more detail in next section.
Supporting a fast time to service, deployment simplicity and a very low footprint enabling deployment at scale in any type of edge location, up to on enterprise premises. See our previous LPG 5G edge user plane: key requirements for success for details.
Providing a high level of robustness and failure resilience by means of a cloud native user plane application designed for high availability and fault resilience, support of geo-redundancy and support of 3GPP control plane and user plane split (CUPS) interface which can be deployed in full mesh with multiple control planes. User plane can also be deployed as a dedicated function within a slice to secure further characteristics and isolation or as a shared function for various slices.
5G edge user plane should enable transition from 4G to more sophisticated 5G connectivity
Most of CSPs are embracing edge opportunities. They are viewing the opportunities as an evolution of their existing offerings rather than a revolution, meaning existing 4G enterprise use cases will still need to be supported for some time as the ecosystem matures to support time-critical communications type of use cases. This means 5G edge user plane should be dual-mode and support such a wide breadth of technology.
5G edge user plane should support both 3GPP compliant serving/packet gateway user function (S/PGW-U) and user plane function (UPF) and evolve with advanced UPF features for time-critical communications, such as more stringent end to end QoS and transmission robustness for ultra-reliable low latency communications (URLLC) or Ethernet connectivity for advanced edge industrial use cases. It should also support 5G peak rates and do not degrade use cases performance characteristics. It should also support dynamic edge routing solutions which are efficient, deployable by multipurpose terminals and mobility proof such as dynamic network slice selection which is preferrable to UPF as uplink classifier as starting solution until standardization evolves.
5G edge user plane should work in conjunction with the CSP’s dual-mode core system, which supports dynamic slicing orchestration, dynamic slice selection, ultra-reliable low latency communications and advanced 5G edge connectivity features such as different service continuity and user plane re-anchoring modes depending on mobility and application resilience needs. Ericsson’s dual-mode 5G Core with Local Packet Gateway provides such advanced 5G connectivity in a pre-verified manner. In fact, the Ericsson Local Packet Gateway Cloud Native Function (CNF) is based on the same software as the Ericsson Packet Core Gateway (PCG), the market leading cloud-native user plane, which is deployed in 5G live networks today.
Such deployment flexibility in edge user plane allows CSP to offer distinct use cases. For example, CSPs can offer mobile gaming service by deploying a cloud virtual reality (VR) gaming center application in their regional data centers. Connectivity with guaranteed low latency QoS can be provided by a dedicated 5G network slice with the dedicated Ericsson Local Packet Gateway, deployed close to the gaming application and connected to the CSP’s existing central core network. The mobile gaming application can use a portable device such as VR glasses or use a multi-purpose smartphone or tablet that supports dynamic slice selection. CSP can reuse their existing public network and macro 5G RAN. As another example, CSP can offer 5G edge connectivity to factories or logistic centers for augmented reality (AR) quality inspection. The AR application is deployed on the factory premise and needs an ultra-reliable and low-latency QoS connection to process in real time all the factory images. This is provided by a dedicated Ericsson Local Packet Gateway with ultra-reliable low latency QoS and redundant configuration being deployed on premises.
Edge use cases will require user plane services beyond 3GPP
There is a set of non-standardized user plane functions deployed in today’s networks (also called GI/N6 LAN functions) for mobile broadband service that would be also relevant for edge use cases. These functions can be categorized as:
Traffic acceleration and optimization of access resources e.g., transport layer optimizers or advanced video traffic shapers
Network services e.g., carrier grade NAT devices or external load balancers
Service aware traffic monitoring and enforcements needed to realize customized CSP charging data plans or comply with some country regulatory such as content filters
Network security functions protecting CSP infrastructure and UEs of security attacks such as subscriber firewalls or distributed denial (DDoS) mitigation systems, and
Service chain policers and forwarders to chain and offload these GI/N6 LAN functions. Those can be integrated with operator policy framework to compose and program a unique data pipeline which addresses the specific connectivity needs of a given subscriber and application in the context of a certain use case
The current GI/N6 LAN market is very fragmented and addressed by many different vendor specific user plane functions. These functions are deployed as separate appliances or virtualized functions, each with their management system, policy integration and cloud orchestration system which significantly increases CSP’s total cost of ownership (TCO) when deploying and managing them. As CSPs start their edge journey they will need to bring some of these GI/N6 functions to the edge. A very simple and cost-efficient strategy to consolidate these functions in one single edge user plane function. This approach is being adopted by Ericsson Local Packet Gateway: it integrates these functions, including advanced integrated Packet Core Firewall, together with the UPF/S/PGW-U functions. This dramatically reduces the TCO and provides a single hop to the end application, which reduces further the latency. Ericsson Local Packet Gateway also allows to compose and tune the set user plane functions applied to a given traffic in one configuration click, which allows to customize the connectivity for each edge use case.
Another consideration is that these GI/N6 functions were designed for legacy mobile broadband. This means they will need to evolve to support 5G peak user throughput rates and new 5G segment requirements, e.g., traffic optimizations should focus on optimizing the throughput of uplink transmissions and reducing the overall jitter and latency. Service aware charging models will evolve as 5G gets monetized, security for edge enterprise connectivity will keep evolving as well. Technological innovation in this space is a must for any edge user plane vendor and should be holistic considering the entire ecosystem and end-to-end solution behavior. As one example, edge user plane can leverage 3GPP exposure interfaces for application detection, use collaborative solutions with content providers or RAN to optimize traffic delivery or even adapt traffic optimizations to new end to end rate adaptation mechanisms such as low latency low loss scalable throughput (L4S). Ericsson, as an end-to-end network provider and key contributor to 5G standardization, is working actively in this space.
Edge connectivity needs to be monitored and assured
CSPs need to monitor, troubleshoot, and assure the edge user plane connectivity. In many cases the CSP organizations dealing with enterprises services have their own analytic and management systems. Those systems need to evolve to provide visibility of the 5G encrypted communication, up to on enterprise premise and without compromising 5G security and provide advanced insights to meet the stringent service level agreements of edge use cases. Example of user plane data feeds are traffic packet and patterns statistics, key performance indicators at transport level or service quality of experience estimates per application, area of interest, slice and subscriber type. CSP analytic use cases will also evolve, meaning network assurance and service experience management use cases will increasingly adopt AI/ML models with distinct and very demanding UP data sets running in parallel.
External probing solutions were not designed for these requirements. The cost of evolving and deploying such solutions to thousands of edges is unaffordable. Ericsson Local Packet Gateway addresses this challenge by supporting integrated dual-mode probing capabilities which includes rich, granular data with pre-processed data and advanced data collection profiles avoiding the need of deploying external taps, packet broker and probes at edge. Software probes are a unique Ericsson dual mode 5G Core feature – a feature that’s very popular with our customers for public network and enterprise solutions.
CSP will also introduce network data analytics function (NWDAF) function to enable 5G analytics for further 5G automation, new exposure APIs for verticals and data efficiency. An NWDAF can collect edge user plane and public network data to provide real time analytics which can be consumed by the network functions or by the end edge application to improve further the edge connectivity. Example of those analytics are user mobility, network congestion, quality of service, service experience or abnormal user behavior. Ideally, the NWDAF should be distributed at the edge and deployed co-located to the edge user plane for data efficiency, security and lower actuation latency.
Ericsson NWDAF supports such distributed and co-located deployment and analytics and can collect pre-standard data from the Local Packet Gateway data until 3GPP rel-18 specifies UPF event exposure.
Edge exposure for advanced edge connectivity
Exposure through APIs on the edge is becoming increasingly important for CSPs to enable new services, increase their relevance in the 5G ecosystem and become more attractive partners for hyperscale cloud providers, application ecosystems and other players.
Edge applications will be able to consume network capabilities and data to provide advanced services and innovate. Data extracted from edge user plane function will be of high value. For example, to determine the exact UE sessions being anchored by a given edge user plane, the actual monitored QoS, etc. Such exposure capabilities in edge user plane allows application to adapt the content delivery or reconfigure dynamically the connectivity, e.g., change dynamically the negotiated QoS or influence edge routing. As mentioned previously, NWDAF user plane analytics can be also exposed for advanced edge use cases.
Ericsson is already working with our customers to create new edge use cases using Ericsson Local Packet Gateway and Edge Exposure Server. Stay tuned!
Summary:
In this blog post we’ve explained the different considerations that need to be taken into account when selecting the 5G edge user plane, and how it enables flexible virtual private and hybrid 4G private solution deployments and address the user experience idiosyncrasy of myriads of edge use cases. The 5G edge user plane has to be small, cost efficient, easy to deploy but still extremely powerful and advanced in terms of dual connectivity and added value features.
Ericsson Local Packet Gateway is designed with all these capabilities in mind and integrates seamlessly with existing CSP dual-mode 5G Core, delivering edge use cases was never that easy.
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