How To Build and Operate At The Edge for CSPs

Edge computing is poised to significantly reshape telecom networks. Beyond changing the ways communications service providers (CSPs) operate, it also holds huge potential for capturing much more of the enterprise market. TM Forum’s analysts surveyed communications service providers to learn more about their edge computing plans and deployment experiences.

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GROUPE INFODIS

Founded in 1985, Infodis Group operates dynamically on the market of high technologies through two complementary and expert subsidiaries Infodis IT and Visualdis, which combine a sharp expertise and recognized. Bringing together 265 employees for 26 M € turnover, Infodis Group is a sustainable and financially independent group, led by its managing shareholders. The business model ensures stable support, agile and sustainable..

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Data Center Networking

Key Network Performance Metrics to Improve Efficiency

Article | July 5, 2023

Discover key network performance metrics to enhance user experience. Explore in-depth latency, throughput, jitter, packet loss, VOIP quality, and MOS score to optimize network performance analysis. Contents 1. Importance of Network Performance Metrics for Performance Analysis 2. Critical Key Network Performance Metrics to Monitor 2.1 Latency 2.2 Throughput 2.3 Jitter 2.4 Packet Loss 2.5 VOIP Qualiy 2.6 MOS Score 3. Steps to Monitor and Measure Network Performance 4. Significance of Monitoring Metrics in Network Troubleshooting 4.1 Provides Network Visibility 4.2 Prevents Network Downtime 4.3 Observe Bandwidth Usage 5. Overcome Monitoring Challenges in Network Performance Metrics 6. Key Takeaway 1. Importance of Network Performance Metrics for Performance Analysis Network performance involves analyzing and evaluating network statistics to determine the quality of services provided by the underlying computer network. Considering various key network metrics, it is primarily measured from the end-users’ perspective. Measuring these metrics, analyzing performance data over time, and understanding the impact on the end-user experience is essential to assess network performance. Measuring network performance requires considering factors such as the location and timing of measurements. For instance, network performance may differ when comparing paths between cities or during periods of varying user demands throughout the day. Therefore, a comprehensive approach to monitoring network performance involves identifying these variables and identifying areas for improvement. Network performance metrics offer valuable insights into any network infrastructure and services. These metrics provide real-time information on potential issues, outages, and errors, allowing one to allocate IT resources efficiently. Understanding end-user demands can create an adaptive network to meet future business needs. However, comprehensive monitoring requires an advanced network monitoring tool to gather, analyze, and interpret data effectively, optimizing network performance. Leveraging relevant metrics can improve network performance, help make informed decisions, enhance network reliability, and deliver a superior user experience. 2. Critical Key Network Performance Metrics to Monitor 2.1 Latency Latency, or network delay, is a crucial performance metric in network monitoring and management. It quantifies the time required to transmit data between destinations. Factors like packet queuing and fiber optic cabling affect network latency. Consistent delays or sudden spikes in latency indicate significant network performance issues. Monitoring and minimizing latency are essential for ensuring optimal network performance. By actively tracking latency, organizations identify and address issues that may cause delays in data transmission, thereby improving overall network responsiveness and minimizing disruptions for end-users. 2.2 Throughput Throughput metrics for network monitoring enable measurement of the data transmission rate across various network segments. Unlike bandwidth, which represents the theoretical data transfer limit, throughput reflects the successful delivery of data packets to their destination. Variations in throughput can occur across different network areas. A low throughput indicates the presence of dropped packets requiring retransmission, and highlights potential performance issues that need attention. Monitoring throughput is crucial for effective network management. By monitoring this performance metric, organizations can gain insights into the actual data transmission rate, ensuring that it aligns with expected levels. 2.3 Jitter Jitter, a key performance metric in network monitoring, refers to the variation in delay between packets, measured as the difference between expected and actual arrival times. It results due to network congestion, routing issues, or other factors, leading to packet loss and degraded application performance. Jitter disrupts the standard sequencing of data packets and can arise due to network congestion or route changes. Monitoring jitter is crucial for identifying and addressing network stability issues and ensuring reliable data transmission. By actively monitoring this performance metric, organizations can address variations in packet delay, mitigating issues that leads to packet loss and enabling proactive troubleshooting. 2.4 Packet Loss Packet loss, a performance management network monitoring metric, represents the number of data packets lost during transmission. It directly affects end-user services, leading to unfulfilled data requests and potential disruptions. Packet loss can arise from various factors, including software problems, network congestion, or router performance issues. Monitoring the entire process precisely to detect and address packet loss, ensures reliable data transmission and optimal network performance. Monitoring packet loss with the right network monitoring software enables timely troubleshooting and optimization of network infrastructure, ultimately enhancing overall network reliability and performance. 2.5 VOIP Quality VoIP (Voice over Internet Protocol) quality is a crucial network performance metric. It refers to the overall performance of a VoIP system in delivering clear and reliable voice communications over the Internet, replacing traditional phone lines. Factors influencing VoIP quality include network bandwidth, latency, packet loss, jitter, and the quality of end-user devices. Monitoring VoIP quality ensures optimal system functionality and high-quality voice communications. Key performance indicators (KPIs) such as mean opinion score (MOS), jitter, latency, packet loss, and call completion rates are utilized to assess and optimize VoIP quality. 2.6 MOS Score Mean opinion score (MOS) is a vital performance metric in network monitoring, rating the perceived quality of a voice call on a scale of 1 to 5. It is a standardized measurement developed by the ITU, an international agency focused on enhancing communication networks. Initially designed for traditional voice calls, the MOS has been adapted to evaluate Voice over IP (VoIP) calls. The MOS score considers various factors, including the specific codec employed for the VoIP call, providing a comprehensive assessment of voice calls quality in network monitoring. 3. Steps to Monitor and Measure Network Performance Step 1: Deploy a Software for Network Monitoring To effectively measure network performance, deploying dedicated network monitoring software is crucial. While temporary tools like traceroutes and pings can provide insights into ongoing problems, they are insufficient for troubleshooting intermittent network issues. Relying on periodic tools for intermittent issues is reliant on chance, as it may only detect problems when they occur during tool usage. By implementing comprehensive network monitoring software, one can proactively monitor and analyze network metrics, historical data, and performance, allowing for timely detection and resolution of both ongoing and intermittent network issues. Step 2: Distribute Monitoring Agents For comprehensive network performance measurement, businesses must distribute monitoring agents strategically across key network locations. These specialized software agents continuously monitor network performance using synthetic traffic, simulating and assessing the end-user perspective. By distributing Monitoring Agents, organizations can: • Measure key network metrics, including jitter, packet loss, and throughput. • Identify and troubleshoot intermittent network issues that are challenging to pinpoint. • Receive alerts regarding any performance degradation, ensuring a timely response. • Collect valuable data for in-depth troubleshooting and analysis, facilitating proactive network management and optimization. Step 3: Measure Network Metrics After deploying the monitoring agents, they continuously exchange synthetic User Datagram Protocol (UDP) traffic, forming a network monitoring session. During this session, the agents measure network performance by evaluating key metrics and conducting network traffic analysis. The metrics used in the analysis include specific parameters, and the results of these measurements are presented in a network response time graph, providing a visual representation of the network's performance characteristics. Monitoring and analyzing these metrics enable organizations to gain valuable insights into network performance, facilitating informed decision-making and convenient network performance troubleshooting. 4. Significance of Monitoring Metrics in Network Troubleshooting 4.1 Provide Network Visibility Monitoring metrics plays a vital role in network troubleshooting by offering network visibility. They enable the identification of performance bottlenecks, configuration problems, and security vulnerabilities that detrimentally affects network performance. These issues can be addressed through targeted troubleshooting efforts, resulting in improved network performance and enhanced end-user experience. Organizations identify and resolve network issues by monitoring metrics, ensuring optimal network functionality and overall business productivity. 4.2 Prevent Network Downtime Effective monitoring metrics are instrumental in preventing network downtime, a costly concern for businesses. Swift identification and resolution of network issues through proactive network performance troubleshooting help minimize downtime, ensuring uninterrupted business operations. By promptly addressing potential problems, network troubleshooting safeguards against lost productivity, revenue, and customer dissatisfaction. Maintaining a proactive approach to monitoring and resolving network issues to enhance network reliability and business continuity. 4.3 Observe Bandwidth Usage Monitoring metrics are essential in network troubleshooting as they enable the observation of bandwidth usage. This allows organizations to detect abnormal or excessive utilization, pinpoint key performance issues and ensure optimal resource allocation. It allows for identifying critical bandwidth-hogging applications or network intrusions, helping experts take immediate action to mitigate risks, safeguard data, and protect the overall network integrity. Additionally, experts can optimize network performance and ensure a seamless user experience for organizations relying on efficient network infrastructure. 5. Overcome Monitoring Challenges in Network Performance Metrics Enterprises seeking to ensure optimal network performance and improve overall business operations must overcome network monitoring obstacles. Effectively monitoring, tracking, and improving network performance requires a strategic combination of skilled personnel, advanced technologies, and well-defined strategies. Failing to address these requirements results in various challenges that hinder the ability to enhance network performance effectively. The challenges that businesses often encounter include managing scalability, handling massive data volumes, achieving real-time monitoring, dealing with multi-vendor environments, addressing network security and privacy concerns, and adapting to evolving network demands. Each obstacle presents unique complexities that require tailored approaches and expert insights. To overcome these challenges, enterprises must invest in comprehensive monitoring tools capable of handling the scalability demands of growing networks. These tools should provide real-time network visibility, robust analytics capabilities, and intelligent data filtering mechanisms to extract meaningful insights from vast network data. Establishing clear monitoring objectives aligned with business goals and defining key performance indicators (KPIs) are essential in effectively addressing network performance challenges. 6. Key Takeaway Monitoring network performance metrics is crucial for assessing the quality of services a computer network provides from an end-user perspective. It involves continuously tracking and analyzing key metrics such as latency, throughput, jitter, packet loss, VOIP quality, and MOS score. Organizations can actively monitor and assess performance, proactively identify intermittent issues, and collect valuable data for in-depth analysis by implementing dedicated network monitoring software and strategically deploying monitoring agents across the network. In addition, it is imperative to emphasize the significance of monitoring metrics in mitigating the potential financial impact of network downtime, enhancing the utilization of available bandwidth resources, and efficiently tackling the complexities inherent in scaling operations, real-time monitoring, diverse vendor ecosystems, security concerns, and the ever-evolving requirements of modern networks.

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Unified Communications, Network Security

How service providers can unlock the coveted SME market

Article | July 10, 2023

For communications service providers, questions still loom over how 5G will be monetized. Many have voiced the view that the enterprise segment is where 5G will make its money, with potential use cases across a breadth of verticals including the automotive, manufacturing and utilities industries to name a few. However, if service providers focus more on delivering 5G business use cases to small and midsized enterprises (SMEs), this market segment could prove to be a fruitful source of revenue. As 5G deployments continue to roll-out globally, CSPs are focused on deriving value from projects and partnerships with large multinational enterprises. And they are eager to do so quickly to assure payback from their $1trillion investments in the next generation network. However, are CSPs blinkered in their approach to generating ROI from 5G? Are they limiting themselves by focusing too much on a small segment of the enterprise market, that to date has limited CSPs' involvement in early 5G projects, reducing them to mere providers of connectivity?

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5G

5G Trends That Will Shape the Future of Technology

Article | May 18, 2023

5G trends are shaping the future of various technologies, from the Internet of Things to Virtual Reality. Learn more about the top trends in 5G to stay ahead of the competition in this sector. Contents 1 The Value of 5G for Businesses 2 5G Trends to Watch in 2023 2.1 Shift to Standalone 5G 2.2 Edge Computing for IoT 2.3 Adoption of Private 5G Networks 2.4 General Availability of 5G 2.5 Partnerships for Rapid Deployments 3 Conclusion 1 The Value of 5G for Businesses The fifth-generation network technology, or 5G, promises to revolutionize the way businesses communicate and operate. It offers lower latency, faster data transfer speeds, more robust security, and new and enhanced experiences. These capabilities enable 5G to support high-quality video conferencing, real-time collaboration, immersive virtual experiences, and more. By investing in 5G, businesses can stay competitive and meet the evolving needs of their employees and customers. With the growing adoption and use cases of this technology, keeping up with the technology trends in 5G is essential for staying ahead in today's business landscape. 2 5G Trends to Watch in 2023 2.1 Shift to Standalone 5G The rapid deployment of 5G across the world has been made possible due to the existence of an already-established 4G infrastructure. This has allowed operators to concentrate on developing the radio access network components while relying on 4G networks as a failsafe. This approach has enabled operators to deploy 5G networks at a faster pace, thereby allowing the benefits of this technology trend to reach a wider audience. The integration of a 5G core and radio forms the backbone of 5G infrastructure, enabling the 5G stand-alone network to achieve its full potential. Wireless providers have been actively promoting the key features of 5G, such as ultra-low latency and complete network slicing, which are exclusively available through the stand-alone version of this advanced technology. By utilizing this emerging technology, businesses can unlock an entirely new level of performance, allowing them to deliver innovative and immersive services to their end-users. Stand-alone 5G is also a necessity for certain unique use cases, and many 5G trends in 2023 will rely on its capabilities. It is essential for businesses to understand the benefits of this advanced technology and adopt it to remain competitive in the ever-evolving digital landscape. 2.2 Edge Computing for IoT The convergence of 5G technology and IoT is transforming how businesses operate across industry verticals. This 5G trend enables edge computing for the IoT by providing low-latency and high-bandwidth connectivity. With 5G, data can be transmitted and processed at the edge of the network, closer to the source of the data, rather than being sent to a central data center for processing. While extensive IoT fleets can operate on a 4G network, a 5G network will improve upon those capabilities with massive multiple-input, multiple output capabilities, enabling an increased number of devices to connect with the cell tower. This is especially useful in IIoT, where a large number of IoT devices are present within a small area, which requires this level of connectivity. The low latency and high bandwidth offered by 5G infrastructure also support innovative IoT solutions, such as integrating artificial intelligence, by enabling real-time processing of data and faster response times. Edge computing allows IoT devices to perform complex processing tasks and make decisions locally, rather than relying on a centralized cloud server. Businesses that operate in industries that require real-time processing will especially benefit from the digital transformation through 5G. 2.3 Adoption of Private 5G Networks Private wireless networks are suitable for many industrial applications, and the market for private 5G networks is set to expand rapidly. Private 5G networks offer greater cybersecurity, control, and reliability, making them ideal for mission-critical applications that require high levels of security and privacy. This is one of the key 5G trends because it is applicable to industries such as manufacturing, healthcare, and finance, where IoT devices collect and share sensitive data that requires greater cybersecurity. Businesses can also utilize private 5G networks to benefit from higher bandwidth, lower latency, and greater flexibility compared to public networks. Private 5G networks can be customized and tailored to meet the specific requirements of each application, making them ideal for specialized functions. As more enterprises look to benefit from network-intensive technologies such as artificial intelligence, virtual reality, and big data, the demand for private wireless networks will continue to rise. Network operators are also more willing to offer private 5G networks because they represent a new revenue stream and a growth opportunity while also allowing them to provide a more personalized service to their customers. 2.4 General Availability of 5G The 5G trends have moved towards access to 5G across the world, with 5G now available in 95 countries and reaching to more than 1.2 billion people. 5G networks are becoming more widespread in 2023, and as a result, many 5G trends and technologies are expected to emerge. Furthermore, 5G has become standard across all premium devices and many mid-range ones, making it an attractive option for consumers. For businesses, this means a whole new world of possibilities. 5G networks offer faster speeds, higher bandwidth, and lower latency, enabling businesses to offer more innovative products and services. With the increased availability of 5G, businesses can develop and deploy emerging technologies like artificial intelligence and machine learning, augmented reality, and virtual reality. Remote work and related use cases will also rise in popularity as 5G becomes more common. However, the distribution of 5G networks differs by region. 5G trends indicate that urban populations will likely be the first beneficiaries of public 5G rollouts and will benefit the most from 5G capabilities such as network densification and massive MIMO. With the deployment of 5G small cells for connectivity, 5G networks will support new use cases and faster, more reliable connectivity for the general public, especially in urban areas. 2.5 Partnerships for Rapid Deployments By connecting disjointed B2B and B2C networks with ecosystems, service providers can become service enablers, working with businesses, consumers, and even competitors to create unique 5G offerings. Digital transformation is possible through new approaches to partnerships, through which service providers manage commoditization pressures and a hyper-competitive market. Partnerships also provide businesses with access to industry skill sets that are in high demand, such as cloud, cybersecurity, and automation. By partnering with players who are already experts, cellular network providers offer specialized solutions to their customers that they may not have been able to provide otherwise. Hosted labs also help to speed ecosystem validation of use cases and new technology, ensuring that solutions are effective and efficient. Furthermore, partnerships enable service providers to create products with global scale, as demonstrated by SAP, IBM, ServiceNow, and Deutsche Telekom, which have collaborated to create global connectivity offerings ranging from 5G to software-defined networks. In the race to increase revenue and control costs in the 5G industry, collaborating with industry experts and integrating solutions will become one of the key 5G technology trends. Through collaboration, service providers can offer unique solutions to their customers, access necessary industry skill sets, and create products with global scale. These partnerships are necessary for businesses to remain competitive in an ever-changing market. 3 Conclusion The ongoing rollout of 5G networks is set to transform businesses across all industries, bringing faster speeds, lower latency, and the ability to connect more devices than ever before. As technology continues to evolve, businesses need to stay up-to-date with the future trends in 5G in order to take advantage of its full potential. The growing demand for low latency and massive connectivity due to new use cases such as edge computing and the IoT is driving the growth of 5G networks. These trends will enable businesses to create new products and services, increase efficiency and productivity, and ultimately transform the way they operate. As 5G networks continue to mature, businesses that invest in this technology will have a competitive advantage over those that do not. They will be able to deliver faster, more reliable services to customers, streamline operations, and reduce costs. With the right approach, organizations can capitalize on the latest trends in 5G and unlock new opportunities for growth and innovation in the years to come.

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5G

Edge use cases need a 5G and beyond user plane

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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Spotlight

GROUPE INFODIS

Founded in 1985, Infodis Group operates dynamically on the market of high technologies through two complementary and expert subsidiaries Infodis IT and Visualdis, which combine a sharp expertise and recognized. Bringing together 265 employees for 26 M € turnover, Infodis Group is a sustainable and financially independent group, led by its managing shareholders. The business model ensures stable support, agile and sustainable..

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Network Security

Ampliphae, HPE Athonet and Arqit deliver Quantum-Safe Private 5G using Symmetric Key Agreement

PR Newswire | January 19, 2024

Arqit Quantum Inc, a leader in quantum-safe encryption, and Ampliphae Ltd (Ampliphae), a leader in network cyber security solutions, have today announced successful completion of a project that will deliver enhanced quantum-safe security for Private 5G networks. The Security Enhanced Virtualised Networking for 5G (SEViN-5G) project, funded by Innovate UK, the UK Government’s innovation agency, leveraged Ampliphae’s network security analytics technology and Arqit’s Symmetric Key Agreement Platform to deliver a quantum-secure Private 5G testbed that can protect against both current and future cyber threats. Athonet, a Hewlett Packard Enterprise acquisition, provided the Radio Access Network (RAN) equipment for the project with a cloud core hosted on AWS. Private enterprise networks based on 5G cellular technology are accelerating digital transformation across industries including manufacturing, healthcare, defence and smart cities. Private 5G gives enterprises access to high-speed, massively scalable, and ultra-reliable wireless connectivity, allowing them to implement innovative IoT and mobile solutions that enhance productivity, drive automation and improve customer engagement. The security of these networks will be paramount as they will support safety-critical infrastructure and carry highly sensitive data. But like any new technology, 5G comes with potential new threats and security risks including the threat from quantum computing. The project finished in December 2023 and customer engagement has already begun. David Williams, Arqit Founder, Chairman and CEO said: “Enterprises want to deploy Private 5G networks with complete confidence that they will be safe from both current and future cyber threats including from quantum computers. Working alongside Ampliphae, we have shown that a quantum-safe Private 5G network is deliverable using Arqit’s unique encryption technology.” Trevor Graham, Ampliphae CEO said: “Private 5G can be hosted partly or completely in the Cloud, giving enterprises the opportunity to rapidly set up their own cellular networks customised to support their operations. With Ampliphae and Arqit they can now be certain that those Private 5G networks are monitored and secure against eavesdropping and disruption.” Nanda Menon, Senior Advisor Hewlett Packard Enterprise said: “In an era where security is paramount, the completion of the SEViN-5G project is a significant milestone. The delivery of a quantum-secure Private 5G testbed, achieved where Athonet have combined the Athonet core with CableFree radios, underscores the commitment to innovation and reinforces the confidence enterprises can have in deploying networks that are both cutting-edge and secure from both present and future threats.” About Arqit Arqit Quantum Inc. (Nasdaq: ARQQ, ARQQW) (Arqit) supplies a unique encryption Platform as a Service which makes the communications links of any networked device, cloud machine or data at rest secure against both current and future forms of attack on encryption – even from a quantum computer. Compliant with NSA standards, Arqit’s Symmetric Key Agreement Platform delivers a lightweight software agent that allows devices to create encryption keys locally in partnership with any number of other devices. The keys are computationally secure and operate over zero trust networks. It can create limitless volumes of keys with any group size and refresh rate and can regulate the secure entrance and exit of a device in a group. The agent is lightweight and will thus run on the smallest of end point devices. The Product sits within a growing portfolio of granted patents. It also works in a standards compliant manner which does not oblige customers to make a disruptive rip and replace of their technology. Recognised for groundbreaking innovation at the Institution of Engineering and Technology awards in 2023, Arqit has also won the Innovation in Cyber Award at the National Cyber Awards and Cyber Security Software Company of the Year Award at the Cyber Security Awards. Arqit is ISO 27001 Standard certified. www.arqit.uk About Ampliphae Ampliphae’s distributed network analytics technology provides insight into how networks are used to support enterprise operations at every level. A graduate of the prestigious LORCA cyber accelerator in London, and the AWS European Defence Accelerator, Ampliphae’s technology is already used by enterprises across multiple verticals to discover, analyse and secure the network traffic that supports their key applications and business processes. Ampliphae’s Encryption Intelligence product operates at enterprise scale to discover devices and applications that use cryptography, analysing their encryption capabilities to detect risks, including assets that are vulnerable to future quantum computer attack. Using Encryption Intelligence, the organisation can gather effective operational intelligence about their encryption landscape, both within and outside the organisation, and build an effective mitigation program to address current and future vulnerabilities.

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Network Security

Cato Networks Introduces World's First SASE-based XDR

PR Newswire | January 25, 2024

Cato Networks, the leader in SASE, announced the expansion of the Cato SASE Cloud platform into threat detection and incident response with Cato XDR, the world's first SASE-based, extended detection and response (XDR) solution. Available immediately, Cato XDR utilizes the functional and operational capabilities of the Cato SASE Cloud to overcome the protracted deployment times, limited data quality, and inadequate investigation and response experience too often associated with legacy XDR solutions. Cato also introduced Cato EPP, the first SASE-managed endpoint protection platform (EPP/EDR). Together, Cato XDR and Cato EPP mark the first expansion beyond the original SASE scope pioneered by Cato in 2016 and defined by industry analysts in 2019. SASE's security capabilities encompassed threat prevention and data protection in a common, easy-to-manage, and easy-to-adopt global platform. With today's announcement, Cato is expanding SASE into threat detection, incident response, and endpoint protection without compromising on the architectural elegance captured by the original SASE definition. "Cato SASE continues to be the antidote to security complexity," says Shlomo Kramer, CEO and co-founder of Cato Networks. "Today, we extend our one-of-a-kind SASE platform beyond threat prevention and into threat detection and response. Only Cato and our simple, automated, and elegant platform can streamline security this way." An early adopter of Cato XDR is Redner's Markets, an employee-owned supermarket chain headquartered in Reading, Pennsylvania, with 75 locations. Redner's Markets' vice president of IT and Infrastructure, Nick Hidalgo, said, "The Cato platform gave us better visibility, saved time on incident response, resolved application issues, and improved network performance ten-fold." (Read more about Redner's Markets and Cato in this blog. "The convergence of XDR and EPP into SASE is not just another product; it's a game-changer for the industry," said Art Nichols, CTO of Windstream Enterprise, a Cato partner. "The innovative integration of these capabilities brings together advanced threat detection, response capabilities, and endpoint security within a unified, cloud-native architecture—revolutionizing the way enterprises protect their networks and data against increasingly sophisticated cyber threats." (Read more about what Cato partners are saying about today's news in this blog.) Platform vs. Product: The Difference Matters Cato XDR takes full advantage of the enormous benefits of the Cato SASE Cloud platform, the first platform built from the ground up to enable enterprises to connect, secure, and manage sites, users, and cloud resources anywhere in the world. Unlike disjointed point solutions and security appliances, Cato capabilities are instantly on, always available at scale, and fully converged, giving IT teams a single, shared context worldwide to understand their networks, prevent threats, and resolve problems. As an autonomous platform, Cato SASE Cloud sustains its evolution, resiliency, optimal performance, and security posture, saving enterprises the operational overhead of maintaining enterprise infrastructure. Enterprises simply subscribe to Cato to meet their business needs. Cato's cloud-native model revolutionized security and networking operations when it was introduced in 2016, a fact validated three years later in 2019 when the Cato approach was formally recognized by the industry as SASE. Breach Times Still Too Long; Limitations of Legacy XDR Cato is again revolutionizing cybersecurity with the first SASE platform to expand into threat detection, empowering security teams to become smarter and remediate incidents faster. The flood of security alerts triggered by network sensors, such as firewalls and IPS, complicates threat identification. In 2023, enterprises required 204 days on average to identify breaches.1 XDR tools help security analysts close this gap by ingesting, correlating, and contextualizing threat intelligence information with the data from native and third-party sensors. However, legacy XDR tools suffer from numerous problems relating to data quality. Sensor deployment extends the time-to-value as IT must not only install the sensors but also develop a baseline of specific organizational activity for accurate assessments. Data quality is also compromised when importing and normalizing third-party sensor data, complicating threat identification and incident response. Security analysts waste time sorting through incident stories to identify the ones most critical for immediate remediation. Once determined, incident remediation is often hampered by missing information, requiring analysts to master and switch between disparate tools. No wonder in 2023, average breach containment required more than two months.1 Cato XDR and Cato EPP Expands the Meaning of SASE Cato XDR addresses legacy XDR's limitations. Instantly activated globally, Cato XDR provides enterprises with immediate insights into threats on their networks. Incident detection is accurate due to Cato's many native sensors – NGFW, advanced threat prevention (IPS, NGAM, and DNS Security), SWG, CASB, DLP, ZTNA, RBI, and now EPP/EDR. Powered by Bitdefender's world-leading malware prevention technology, Cato EPP protects endpoints from attack – in the Cato way. Endpoint threat and user data are stored in the same converged Cato data lake as the rest of the customer's network data, simplifying cross-domain event correlation. The result is incredibly high-quality data that improves the incident identification and remediation process. Cato AI uses the data to accurately identify and rank incidents, empowering analysts to focus critical resources on an organization's most important remediation cases. Cato AI is battle-tested and proven across years of threat hunting and remediation handling by Cato MDR service agents. Remediation times reduce as detected incident stories contain the relevant information for in-depth investigation. Cato's tools sit in the same console as the native engines, enabling security analysts to view everything in one place -- the current security policy and the reviewed story. Finally, incident reporting is simplified with generative AI. Purpose-built for investigations, this natural language engine provides human-readable explanations of incident stories. Analysts save time sharing incident information with other teams and reporting to their managers.

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Network Infrastructure

DISH Wireless Awarded $50 Million NTIA Grant for 5G Open RAN Integration and Deployment Center

PR Newswire | January 16, 2024

DISH Wireless, a subsidiary of EchoStar, was awarded a historic $50 million grant from the U.S. Department of Commerce's National Telecommunications and Information Administration (NTIA) to establish the Open RAN Center for Integration & Deployment (ORCID). ORCID will allow participants to test and validate their hardware and software solutions (RU, DU and CU) against a complete commercial-grade Open RAN network deployed by DISH. "The Open RAN Center for Integration and Deployment (ORCID) will serve a critical role in strengthening the global Open RAN ecosystem and building the next generation of wireless networks," said Charlie Ergen, co-founder and chairman, EchoStar. "By leveraging DISH's experience deploying the world's first standalone Open RAN 5G network, ORCID will be uniquely positioned to test and evaluate Open RAN interoperability, performance and security from domestic and international vendors. We appreciate NTIA's recognition of DISH and ORCID's role in driving Open RAN innovation and the Administration's ongoing commitment to U.S. leadership in wireless connectivity." To date, this grant represents NTIA's largest award under the Public Wireless Supply Chain Innovation Fund (Innovation Fund). ORCID will be housed in DISH's secure Cheyenne, Wyoming campus and will be supported by consortium partners Fujitsu, Mavenir and VMware by Broadcom and technology partners Analog Devices, ARM, Cisco, Dell Technologies, Intel, JMA Wireless, NVIDIA, Qualcomm and Samsung. NTIA Administrator Alan Davidson and Innovation Fund Director Amanda Toman will join EchoStar Co-Founder and Chairman Charlie Ergen, EchoStar CEO Hamid Akhavan, EVP and Chief Network Officer Marc Rouanne and other stakeholders to announce the grant and tour a DISH 5G Open RAN cell site later today in Las Vegas. During this event, DISH will outline ORCID's unique advantages, including that it will leverage DISH's experience as the only operator in the United States to commercially deploy a standalone Open RAN 5G network. DISH and its industry partners have validated Open RAN technology at scale across the country; today DISH's network covers over 246 million Americans nationwide. At ORCID, participants will be able to test and evaluate individual or multiple network elements to ensure Open RAN interoperability, performance and security, and contribute to the development, deployment and adoption of open and interoperable standards-based radio access networks. ORCID's "living laboratory" will drive the Open RAN ecosystem — from lab testing to commercial deployment. Below are highlights of ORCID: ORCID will combine both lab and field testing and evaluation activities. ORCID will be able to test elements brought by any qualified vendor against DISH's live, complete and commercial-grade Open RAN stack. ORCID will use DISH's spectrum holdings, a combination of low-, mid- and high-band frequencies, enabling field testing and evaluation. ORCID will evaluate Open RAN elements through mixing and matching with those of other vendors, rather than validating a single vendor's stack. DISH's experience in a multi-vendor environment will give ORCID unique insights about the integration of Open RAN into brownfield networks. ORCID's multi-tenant lab and field testing will occur in DISH's secure Cheyenne, Wyoming facility, which is already compliant with stringent security protocols in light of its satellite functions. About DISH Wireless DISH Wireless, a subsidiary of EchoStar Corporation (NASDAQ: SATS), is changing the way the world communicates with the Boost Wireless Network. In 2020, the company became a nationwide U.S. wireless carrier through the acquisition of Boost Mobile. The company continues to innovate in wireless, building the nation's first virtualized, Open RAN 5G broadband network, and is inclusive of the Boost Infinite, Boost Mobile and Gen Mobile wireless brands.

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Network Security

Ampliphae, HPE Athonet and Arqit deliver Quantum-Safe Private 5G using Symmetric Key Agreement

PR Newswire | January 19, 2024

Arqit Quantum Inc, a leader in quantum-safe encryption, and Ampliphae Ltd (Ampliphae), a leader in network cyber security solutions, have today announced successful completion of a project that will deliver enhanced quantum-safe security for Private 5G networks. The Security Enhanced Virtualised Networking for 5G (SEViN-5G) project, funded by Innovate UK, the UK Government’s innovation agency, leveraged Ampliphae’s network security analytics technology and Arqit’s Symmetric Key Agreement Platform to deliver a quantum-secure Private 5G testbed that can protect against both current and future cyber threats. Athonet, a Hewlett Packard Enterprise acquisition, provided the Radio Access Network (RAN) equipment for the project with a cloud core hosted on AWS. Private enterprise networks based on 5G cellular technology are accelerating digital transformation across industries including manufacturing, healthcare, defence and smart cities. Private 5G gives enterprises access to high-speed, massively scalable, and ultra-reliable wireless connectivity, allowing them to implement innovative IoT and mobile solutions that enhance productivity, drive automation and improve customer engagement. The security of these networks will be paramount as they will support safety-critical infrastructure and carry highly sensitive data. But like any new technology, 5G comes with potential new threats and security risks including the threat from quantum computing. The project finished in December 2023 and customer engagement has already begun. David Williams, Arqit Founder, Chairman and CEO said: “Enterprises want to deploy Private 5G networks with complete confidence that they will be safe from both current and future cyber threats including from quantum computers. Working alongside Ampliphae, we have shown that a quantum-safe Private 5G network is deliverable using Arqit’s unique encryption technology.” Trevor Graham, Ampliphae CEO said: “Private 5G can be hosted partly or completely in the Cloud, giving enterprises the opportunity to rapidly set up their own cellular networks customised to support their operations. With Ampliphae and Arqit they can now be certain that those Private 5G networks are monitored and secure against eavesdropping and disruption.” Nanda Menon, Senior Advisor Hewlett Packard Enterprise said: “In an era where security is paramount, the completion of the SEViN-5G project is a significant milestone. The delivery of a quantum-secure Private 5G testbed, achieved where Athonet have combined the Athonet core with CableFree radios, underscores the commitment to innovation and reinforces the confidence enterprises can have in deploying networks that are both cutting-edge and secure from both present and future threats.” About Arqit Arqit Quantum Inc. (Nasdaq: ARQQ, ARQQW) (Arqit) supplies a unique encryption Platform as a Service which makes the communications links of any networked device, cloud machine or data at rest secure against both current and future forms of attack on encryption – even from a quantum computer. Compliant with NSA standards, Arqit’s Symmetric Key Agreement Platform delivers a lightweight software agent that allows devices to create encryption keys locally in partnership with any number of other devices. The keys are computationally secure and operate over zero trust networks. It can create limitless volumes of keys with any group size and refresh rate and can regulate the secure entrance and exit of a device in a group. The agent is lightweight and will thus run on the smallest of end point devices. The Product sits within a growing portfolio of granted patents. It also works in a standards compliant manner which does not oblige customers to make a disruptive rip and replace of their technology. Recognised for groundbreaking innovation at the Institution of Engineering and Technology awards in 2023, Arqit has also won the Innovation in Cyber Award at the National Cyber Awards and Cyber Security Software Company of the Year Award at the Cyber Security Awards. Arqit is ISO 27001 Standard certified. www.arqit.uk About Ampliphae Ampliphae’s distributed network analytics technology provides insight into how networks are used to support enterprise operations at every level. A graduate of the prestigious LORCA cyber accelerator in London, and the AWS European Defence Accelerator, Ampliphae’s technology is already used by enterprises across multiple verticals to discover, analyse and secure the network traffic that supports their key applications and business processes. Ampliphae’s Encryption Intelligence product operates at enterprise scale to discover devices and applications that use cryptography, analysing their encryption capabilities to detect risks, including assets that are vulnerable to future quantum computer attack. Using Encryption Intelligence, the organisation can gather effective operational intelligence about their encryption landscape, both within and outside the organisation, and build an effective mitigation program to address current and future vulnerabilities.

Read More

Network Security

Cato Networks Introduces World's First SASE-based XDR

PR Newswire | January 25, 2024

Cato Networks, the leader in SASE, announced the expansion of the Cato SASE Cloud platform into threat detection and incident response with Cato XDR, the world's first SASE-based, extended detection and response (XDR) solution. Available immediately, Cato XDR utilizes the functional and operational capabilities of the Cato SASE Cloud to overcome the protracted deployment times, limited data quality, and inadequate investigation and response experience too often associated with legacy XDR solutions. Cato also introduced Cato EPP, the first SASE-managed endpoint protection platform (EPP/EDR). Together, Cato XDR and Cato EPP mark the first expansion beyond the original SASE scope pioneered by Cato in 2016 and defined by industry analysts in 2019. SASE's security capabilities encompassed threat prevention and data protection in a common, easy-to-manage, and easy-to-adopt global platform. With today's announcement, Cato is expanding SASE into threat detection, incident response, and endpoint protection without compromising on the architectural elegance captured by the original SASE definition. "Cato SASE continues to be the antidote to security complexity," says Shlomo Kramer, CEO and co-founder of Cato Networks. "Today, we extend our one-of-a-kind SASE platform beyond threat prevention and into threat detection and response. Only Cato and our simple, automated, and elegant platform can streamline security this way." An early adopter of Cato XDR is Redner's Markets, an employee-owned supermarket chain headquartered in Reading, Pennsylvania, with 75 locations. Redner's Markets' vice president of IT and Infrastructure, Nick Hidalgo, said, "The Cato platform gave us better visibility, saved time on incident response, resolved application issues, and improved network performance ten-fold." (Read more about Redner's Markets and Cato in this blog. "The convergence of XDR and EPP into SASE is not just another product; it's a game-changer for the industry," said Art Nichols, CTO of Windstream Enterprise, a Cato partner. "The innovative integration of these capabilities brings together advanced threat detection, response capabilities, and endpoint security within a unified, cloud-native architecture—revolutionizing the way enterprises protect their networks and data against increasingly sophisticated cyber threats." (Read more about what Cato partners are saying about today's news in this blog.) Platform vs. Product: The Difference Matters Cato XDR takes full advantage of the enormous benefits of the Cato SASE Cloud platform, the first platform built from the ground up to enable enterprises to connect, secure, and manage sites, users, and cloud resources anywhere in the world. Unlike disjointed point solutions and security appliances, Cato capabilities are instantly on, always available at scale, and fully converged, giving IT teams a single, shared context worldwide to understand their networks, prevent threats, and resolve problems. As an autonomous platform, Cato SASE Cloud sustains its evolution, resiliency, optimal performance, and security posture, saving enterprises the operational overhead of maintaining enterprise infrastructure. Enterprises simply subscribe to Cato to meet their business needs. Cato's cloud-native model revolutionized security and networking operations when it was introduced in 2016, a fact validated three years later in 2019 when the Cato approach was formally recognized by the industry as SASE. Breach Times Still Too Long; Limitations of Legacy XDR Cato is again revolutionizing cybersecurity with the first SASE platform to expand into threat detection, empowering security teams to become smarter and remediate incidents faster. The flood of security alerts triggered by network sensors, such as firewalls and IPS, complicates threat identification. In 2023, enterprises required 204 days on average to identify breaches.1 XDR tools help security analysts close this gap by ingesting, correlating, and contextualizing threat intelligence information with the data from native and third-party sensors. However, legacy XDR tools suffer from numerous problems relating to data quality. Sensor deployment extends the time-to-value as IT must not only install the sensors but also develop a baseline of specific organizational activity for accurate assessments. Data quality is also compromised when importing and normalizing third-party sensor data, complicating threat identification and incident response. Security analysts waste time sorting through incident stories to identify the ones most critical for immediate remediation. Once determined, incident remediation is often hampered by missing information, requiring analysts to master and switch between disparate tools. No wonder in 2023, average breach containment required more than two months.1 Cato XDR and Cato EPP Expands the Meaning of SASE Cato XDR addresses legacy XDR's limitations. Instantly activated globally, Cato XDR provides enterprises with immediate insights into threats on their networks. Incident detection is accurate due to Cato's many native sensors – NGFW, advanced threat prevention (IPS, NGAM, and DNS Security), SWG, CASB, DLP, ZTNA, RBI, and now EPP/EDR. Powered by Bitdefender's world-leading malware prevention technology, Cato EPP protects endpoints from attack – in the Cato way. Endpoint threat and user data are stored in the same converged Cato data lake as the rest of the customer's network data, simplifying cross-domain event correlation. The result is incredibly high-quality data that improves the incident identification and remediation process. Cato AI uses the data to accurately identify and rank incidents, empowering analysts to focus critical resources on an organization's most important remediation cases. Cato AI is battle-tested and proven across years of threat hunting and remediation handling by Cato MDR service agents. Remediation times reduce as detected incident stories contain the relevant information for in-depth investigation. Cato's tools sit in the same console as the native engines, enabling security analysts to view everything in one place -- the current security policy and the reviewed story. Finally, incident reporting is simplified with generative AI. Purpose-built for investigations, this natural language engine provides human-readable explanations of incident stories. Analysts save time sharing incident information with other teams and reporting to their managers.

Read More

Network Infrastructure

DISH Wireless Awarded $50 Million NTIA Grant for 5G Open RAN Integration and Deployment Center

PR Newswire | January 16, 2024

DISH Wireless, a subsidiary of EchoStar, was awarded a historic $50 million grant from the U.S. Department of Commerce's National Telecommunications and Information Administration (NTIA) to establish the Open RAN Center for Integration & Deployment (ORCID). ORCID will allow participants to test and validate their hardware and software solutions (RU, DU and CU) against a complete commercial-grade Open RAN network deployed by DISH. "The Open RAN Center for Integration and Deployment (ORCID) will serve a critical role in strengthening the global Open RAN ecosystem and building the next generation of wireless networks," said Charlie Ergen, co-founder and chairman, EchoStar. "By leveraging DISH's experience deploying the world's first standalone Open RAN 5G network, ORCID will be uniquely positioned to test and evaluate Open RAN interoperability, performance and security from domestic and international vendors. We appreciate NTIA's recognition of DISH and ORCID's role in driving Open RAN innovation and the Administration's ongoing commitment to U.S. leadership in wireless connectivity." To date, this grant represents NTIA's largest award under the Public Wireless Supply Chain Innovation Fund (Innovation Fund). ORCID will be housed in DISH's secure Cheyenne, Wyoming campus and will be supported by consortium partners Fujitsu, Mavenir and VMware by Broadcom and technology partners Analog Devices, ARM, Cisco, Dell Technologies, Intel, JMA Wireless, NVIDIA, Qualcomm and Samsung. NTIA Administrator Alan Davidson and Innovation Fund Director Amanda Toman will join EchoStar Co-Founder and Chairman Charlie Ergen, EchoStar CEO Hamid Akhavan, EVP and Chief Network Officer Marc Rouanne and other stakeholders to announce the grant and tour a DISH 5G Open RAN cell site later today in Las Vegas. During this event, DISH will outline ORCID's unique advantages, including that it will leverage DISH's experience as the only operator in the United States to commercially deploy a standalone Open RAN 5G network. DISH and its industry partners have validated Open RAN technology at scale across the country; today DISH's network covers over 246 million Americans nationwide. At ORCID, participants will be able to test and evaluate individual or multiple network elements to ensure Open RAN interoperability, performance and security, and contribute to the development, deployment and adoption of open and interoperable standards-based radio access networks. ORCID's "living laboratory" will drive the Open RAN ecosystem — from lab testing to commercial deployment. Below are highlights of ORCID: ORCID will combine both lab and field testing and evaluation activities. ORCID will be able to test elements brought by any qualified vendor against DISH's live, complete and commercial-grade Open RAN stack. ORCID will use DISH's spectrum holdings, a combination of low-, mid- and high-band frequencies, enabling field testing and evaluation. ORCID will evaluate Open RAN elements through mixing and matching with those of other vendors, rather than validating a single vendor's stack. DISH's experience in a multi-vendor environment will give ORCID unique insights about the integration of Open RAN into brownfield networks. ORCID's multi-tenant lab and field testing will occur in DISH's secure Cheyenne, Wyoming facility, which is already compliant with stringent security protocols in light of its satellite functions. About DISH Wireless DISH Wireless, a subsidiary of EchoStar Corporation (NASDAQ: SATS), is changing the way the world communicates with the Boost Wireless Network. In 2020, the company became a nationwide U.S. wireless carrier through the acquisition of Boost Mobile. The company continues to innovate in wireless, building the nation's first virtualized, Open RAN 5G broadband network, and is inclusive of the Boost Infinite, Boost Mobile and Gen Mobile wireless brands.

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Events