Intel corporation (20240340774). CHANNEL RASTER AND SYNCHRONIZATION SIGNAL RASTER FOR OPERATING IN THE 57 GHZ TO 71 GHZ BAND simplified abstract
Contents
CHANNEL RASTER AND SYNCHRONIZATION SIGNAL RASTER FOR OPERATING IN THE 57 GHZ TO 71 GHZ BAND
Organization Name
Inventor(s)
Prerana Rane of Newark CA (US)
Aida Vera Lopez of Hillsboro OR (US)
CHANNEL RASTER AND SYNCHRONIZATION SIGNAL RASTER FOR OPERATING IN THE 57 GHZ TO 71 GHZ BAND - A simplified explanation of the abstract
This abstract first appeared for US patent application 20240340774 titled 'CHANNEL RASTER AND SYNCHRONIZATION SIGNAL RASTER FOR OPERATING IN THE 57 GHZ TO 71 GHZ BAND
The abstract describes a user equipment (UE) configured for operating in a fifth-generation (5G) New Radio (NR) system, which searches for a 5G NR cell at synchronization signal (SS) block frequency positions associated with SS raster values. The UE detects a synchronization signal block (SSB) at one of the SS block frequency positions and derives a cell reference frequency corresponding to a NR Absolute Radio Frequency Channel Number (NR ARFCN) value for the 5G NR cell from system information, including a channel bandwidth. The frequency positions associated with the SS raster values are based on Global Synchronization Channel Number (GSCN) values selected for the FR2 operating band N263. The cell reference frequency corresponds to one of a plurality of NR ARFCN values selected for the FR2 operating band N263.
- The UE is designed to search for 5G NR cells using SS block frequency positions and SS raster values.
- It detects SSBs at specific frequency positions and derives cell reference frequencies based on NR ARFCN values.
- The frequency positions are determined by GSCN values selected for the FR2 operating band N263.
- This technology allows for efficient cell search and identification in a 5G NR system.
Potential Applications: - 5G network infrastructure - Mobile telecommunications - Internet of Things (IoT) devices
Problems Solved: - Streamlining cell search processes in 5G NR systems - Enhancing network efficiency and performance
Benefits: - Faster and more accurate cell identification - Improved connectivity for UE devices - Optimal utilization of 5G network resources
Commercial Applications: Title: "Enhanced Cell Search Technology for 5G NR Systems" This technology can be utilized by telecommunications companies to improve the performance and efficiency of their 5G networks, leading to better connectivity for users and enhanced network capabilities. It can also benefit manufacturers of UE devices by providing them with advanced features for seamless integration into 5G networks.
Questions about Enhanced Cell Search Technology for 5G NR Systems:
1. How does this technology improve the efficiency of 5G network operations? This technology streamlines the cell search process in 5G NR systems, leading to faster and more accurate cell identification, which ultimately enhances network performance and efficiency.
2. What are the potential implications of this technology for the future of mobile telecommunications? This technology has the potential to revolutionize the way 5G networks operate, offering improved connectivity for users and enabling the seamless integration of IoT devices into the network ecosystem.
Original Abstract Submitted
a user equipment (ue) configured for operating in a fifth-generation (5g) new radio (nr) system may search for a 5g nr cell at synchronization signal (ss) block frequency positions associated with synchronization signal (ss) raster values. the ue may detect a synchronization signal block (ssb) at one of the ss block frequency positions and may derive a cell reference frequency corresponding to a nr absolute radio frequency channel number (nr arfcn) value for the 5g nr cell from system information including a channel bandwidth. the frequency positions associated with the ss raster values are based on one or more global synchronization channel number (gscn) values selected for the fr2 operating band n263. the cell reference frequency corresponds to one of a plurality of nr arfcn values selected for the fr2 operating band n263.
