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Standalone #5G could change the game with its promises of ultra-low latency and faster speeds. In our latest webinar, we discuss what’s behind sluggish deployments and how this technology will transform connectivity. Read our blog for more, including the full webinar on-demand: https://ookla.d.pr/cZSEGe

5G LTM | L1/L2 Mobility ------------------------- LTM is a procedure in which a gNB receives L1 measurement report(s) from a UE, and on their basis the gNB changes UE serving cell by a cell switch command signaled via a MAC CE. The cell switch command indicates an LTM candidate configuration that the gNB previously prepared and provided to the UE through RRC signaling. Then the UE switches to the target configuration according to the cell switch command. The LTM procedure can be used to reduce the mobility latency. https://lnkd.in/gWe8-RaF  #3GPPRelease18 #5gHandover #5Gmobility #L1L2intercellmobility #lowerlayertriggermobilityMAC #handoverreduced #interruptiontimesURLLC

Fixed-wireless access through 5.5G, or 5G-Advanced, promises much faster speeds but demands more spectrum.

RSI stands for Received Signal Strength Indication. RSI is a metric used to quantify the strength of the signal received by a receiver, such as a mobile device, from a transmitter, such as a base station or access point. Here are some key uses of Received Signal Strength Indication (RSI) in telecom: https://lnkd.in/gnX8cTk4 Subscribe YouTube Channel 1. **Network Coverage**: RSI is used to determine the coverage area of a cell within a cellular network. By measuring the RSI at various locations, network operators can assess signal strength levels and identify areas with weak coverage that may require optimization or additional infrastructure. 2. **Handover Optimization**: In mobile networks, RSI is crucial for facilitating seamless handovers between cells as a user moves within the network. By monitoring the RSI of neighboring cells, a mobile device can determine when to switch to a different cell to maintain a strong and reliable connection. 3. **Location Estimation**: RSI data can be used for location estimation in wireless networks. By analyzing the RSI measurements from multiple access points or base stations, algorithms can triangulate the position of a mobile device with respect to the signal sources, enabling location-based services and tracking. 4. **Quality of Service (QoS) Monitoring**: RSI measurements are used to assess the quality of service provided to mobile users in terms of signal strength. Network operators can use RSI data to monitor and optimize network performance to ensure consistent and reliable connectivity for subscribers. 5. **Interference Management**: RSI data helps in identifying and mitigating sources of interference in wireless networks. High levels of interference can degrade signal quality and impact network performance. By analyzing RSI measurements, operators can detect interference sources and take corrective actions to improve network efficiency. 6. **Network Planning**: RSI measurements play a vital role in network planning and optimization. By conducting RSI surveys and analysis, network planners can determine optimal antenna placements, power levels, and coverage patterns to maximize signal strength and coverage while minimizing interference. 7. **Device Power Management**: Mobile devices use RSI measurements to adjust their transmit power levels efficiently. By monitoring the RSI from the serving cell and neighboring cells, devices can optimize their power consumption to maintain a reliable connection while conserving battery life. 8. **Capacity Planning**: RSI data is essential for capacity planning in telecom networks. By analyzing RSI trends and patterns, operators can determine areas of high demand and adjust network resources accordingly to ensure sufficient capacity for voice and data traffic. https://lnkd.in/gnX8cTk4

🚀 Unlocking the Power of 5G: An In-Depth Introduction 📱 We're excited to share our latest YouTube video, "Introduction to 5G," where we delve into the transformative potential of 5G technology. In this video, we cover: 🌐 Objectives: Understand the driving goals behind 5G and how it's set to revolutionize connectivity. 📡 Frequency Spectrum: Explore the diverse frequency bands that 5G operates on and their unique advantages. 🔍 Services: Discover the innovative services enabled by 5G, from enhanced mobile broadband to critical communications. 🏗️ Architecture: Learn about the cutting-edge architecture that supports 5G’s robust performance. 🔒 Security: Discuss the essential security measures designed to protect data in the 5G era. Join us as we navigate the future of connectivity and technology. Don't miss out on understanding how 5G will reshape our digital landscape! 👉 Watch the Video and stay updated with the latest in tech! https://lnkd.in/dXvc2CkG #5G #Technology #Innovation #MobileTech #FutureOfConnectivity #Telecommunications

How timing and synchronization improve 5G spectrum efficiency https://lnkd.in/e4Js2dp6

📈 #5G capabilities continue to evolve. 📶 Efficient spectrum utilization is crucial to maximize the return on this investment. Time and phase synchronization plays a key role in optimizing 5G spectrum utilization, with a focus on time division duplexing (TDD), carrier aggregation (CA) and synchronization strategies supported by the O-RAN Alliance. 👉 Although 5G is already widely deployed around the world, the #technology still has great untapped potential. Thanks to the collaboration of different technology and #telecommunications experts, this is becoming possible, increasing network efficiency and offering a greater number of capabilities for the industry. 🔎 Read the full article: https://ow.ly/jKO450TMG5j

➡️ Did you know that traditional handover procedures can lead to connection interruptions of up to 90 ms? 🤔 That’s a long time in the fast-paced world of mobile communication! ❗❗ The newly introduced L1/L2 Triggered Mobility (LTM) in 5G Advanced significantly reduces this interruption time to just 20-30 ms! 💥 This innovative approach not only enhances user experience but also supports the growing demand for high-speed data services. 📶 LTM operates by leveraging lower-layer signaling, allowing mobile devices to maintain a connection with the source cell while preparing to switch to a target cell. This method optimizes the handover process, ensuring that services remain uninterrupted even as users move between different coverage areas. 😀 In fact, the first version of LTM, released in December 2023, is set to revolutionize mobility management by allowing for high bitrate services that demand low latency. 🚀 👉 Ericsson #️⃣ #Ericsson #Research #Mobile #Connectivity #5G #Innovation #SmartMobility #3GPP #Industries #AutonomousVehicles #SmartCities #EricssonResearch #Technology #TeamEricsson

In the era of burgeoning private 5G networks, understanding the complexities of RF environments becomes crucial. Dean Bubley's blog looks at the growth of private networks and the emerging challenges of maintaining interference-free operations as these networks proliferate, especially in close proximity to one another. It's an insightful read for anyone interested in the future of private 5G deployment and the importance of efficient spectrum monitoring. https://hubs.la/Q02m-hV_0 #5Gnetwork #RFsensor #RFtechnology #CRFS

If you want to know some answers on Why Timing & Synchronization is a key question in 5G and Critical Networks.