Ashish Chandel’s Post

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. How do you see this advancement impacting industries that rely on real-time mobile connectivity, like autonomous vehicles or smart cities? #Connectivity #5G #Innovation #SmartMobility

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. How do you see this advancement impacting industries that rely on real-time mobile connectivity, like autonomous vehicles or smart cities? #Connectivity #5G #Innovation #SmartMobility

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. How do you see this advancement impacting industries that rely on real-time mobile connectivity, like autonomous vehicles or smart cities? #Connectivity #5G #Innovation #SmartMobility

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. How do you see this advancement impacting industries that rely on real-time mobile connectivity, like autonomous vehicles or smart cities? #Connectivity #5G #Innovation #SmartMobility

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. How do you see this advancement impacting industries that rely on real-time mobile connectivity, like autonomous vehicles or smart cities? #Connectivity #5G #Innovation #SmartMobility

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. How do you see this advancement impacting industries that rely on real-time mobile connectivity, like autonomous vehicles or smart cities? #Connectivity #5G #Innovation #SmartMobility

🌍 How do you think the world will look in 2030? From 8K virtual reality and fully autonomous vehicles to hypersonic airplanes and 3D-printed organs, the possibilities seem endless. But to make this hyper-connected world a reality, we need a giant leap forward. We're talking about 1,000 times faster connectivity than what's possible today, with data transfer speeds in terabytes per second and extremely low latency. Sounds a bit like sci-fi, right? But it's not impossible. At Capgemini, we’re thinking beyond 5G to make it happen! 🚀 👉 Read our POV on 6G for a Hyperconnected future and find out more. https://lnkd.in/gjxVWwkQ

5G has been a success in the commercial world, with its advantages of speed and low latency allowing consumers the ability to unlock more capabilities of their mobile devices than ever before. Could a new partnership bring this to the industrial world? Recent news has Rockwell Automation and Nokia joining forces to provide these capabilities to the industrial space. Rockwell bringing its expertise in industrial manufacturing and Nokia bringing its capabilities in network technology to potentially open 5G to the manufacturing space. With modern manufacturing demanding more data and more connectivity, this partnership could address a significant need in the marketplace. The biggest question will be whether companies are willing to trust their network backbone to a technology that has been typically relegated to the commercial space. One big advantage that 5G technology could have over the previous generation of commercial communications technology is the potential to run private networks. If this, along with advances in industrial cybersecurity, can convince manufacturing companies to make the leap to widespread wireless networks in their facilities, this could help to address the needs of modern manufacturing. One caveat will be, with all of this new data, how can you manage the new volume of information? This is where companies like Litmus and HighByte will be extremely helpful, organizing and applying context to the new flood of data coming from the field. #I40 #datacontextualization #5G #manufacturing https://lnkd.in/gAHiWj2t

Sidelink Technology in 5G When a mobile device communicates in a cellular network, data is typically going in both uplink (UL) and downlink (DL) directions to a transceiver entity generally known as a basestation. Starting with 4G LTE Advanced, and continuing with 5G, standards have been developed to allow devices to communicate with each other directly (Sidelink or SL), with and without the assistance of the traditional cellular network. One can immediately see the potential of this capability where infrastructure cellular coverage is poor or non-existent, e.g., in unpopulated areas or underground or where fast connectivity is needed for certain applications like autonomous vehicles. One can also anticipate the technical challenges in establishing sidelinks - search, acquisition, registration, authentication, radio resource allocation, etc. Sidelink is a 3rd Generation Partnership Project (3GPP) standardized technology that enables direct user-to-user communications, with or without the assistance of a base station. Current sidelink (Release 16) has evolved from the device-to-device communication system developed for proximity services (ProSe) targeting public safety via the emergency first responder community (e.g., FirstNet [1]). Sidelink is attractive in such uses because it provides support for users needing data connectivity with ultra-low latency and high reliability requirements. These characteristics are also useful in a variety of other scenarios – such as coverage extension to planned cellular networks, connectivity for Vehicle-to-Everything (V2X), communications for augmented/virtual reality (AR/VR) devices, and network support for intra-body sensors – leading to interests in expanding sidelink usage. In view of these emergent applications, 3GPP is currently developing Release 18 to further enhance sidelink technology. Source: www.comsoc.org

The ultra-low latency of #6G, in the microsecond range, facilitates instantaneous communication between AI systems & data centers. This is crucial for applications requiring real-time decision-making such as autonomous vehicles, #SmartCities, etc. https://rb.gy/4b9k0k