Communication device and method for low-latency initial access to non-standalone 5G new radio network
地域:
CA
CA Newport Beach
摘要
A communication device initiates beam acquisition in a receive-only mode. Beam reception is set to an omni mode in which different beams of RF signals are receivable at the communication device from different directions. A primary signal synchronization (PSS) search is executed from each signal synchronization block location based on control information acquired directly from a first base station over a long-term evolution (LTE) control plane link or from a customer premise equipment (CPE) or user equipment (UE) that is in a radio resource control (RRC) connected state. The communication of the beam of RF signals that has highest received signal strength is activated in a new radio (NR) frequency to the UE or the CPE based on at least a PSS detected in the PSS search, for low-latency non-standalone access to the beam of RF signals in NR frequency at the UE or the CPE.
說(shuō)明書
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Certain embodiments of the disclosure relate to a communication device in a wireless telecommunication system. More specifically, certain embodiments of the disclosure relate to a communication device and method for low-latency initial access to non-standalone (NSA) next (5th) generation (5G) new radio network.
權(quán)利要求
What is claimed is:1. A communication device, comprising:a front-end radio frequency (RF) circuitry; a digital signal processor communicatively coupled to the front-end RF circuitry, wherein the digital signal processor is configured to:initiate beam acquisition, by use of the front-end RF circuitry, in a receive-only mode; acquire control information from at least one of a user equipment (UE) or a customer premise equipment (CPE) that is in a specified proximal range of the communication device, or directly from a first base station over a long term evolution (LTE) control plane link, wherein the UE or the CPE is in a radio resource control (RRC) connected state over a LTE network; set beam reception at the front-end RF circuitry to an omni-mode in which a plurality of different beams of RF signals are receivable at the communication device from a plurality of different directions; execute a primary signal synchronization (PSS) search from each signal synchronization block (SSB) location of a plurality of SSB locations based on the acquired control information; detect the PSS for at least one SSB location based on the executed PSS search; measure a received signal strength for each beam of the plurality of different beams of RF signals for each SSB location of the plurality of SSB locations in accordance with a PSS timing of the detected PSS; switch to a beam of RF signals that has a highest received signal strength of the received plurality of different beams of RF signals for the beam reception; and activate communication of the beam of RF signals that has the highest received signal strength in a new radio (NR) frequency to the UE or the CPE for non-standalone access to the beam of RF signals in the NR frequency at the UE or the CPE. 2. The communication device of claim 1 , wherein the communication device is at least one of an evolved-universal terrestrial radio access-NR dual connectivity (EN-DC) device, a NR-enabled relay node, or a NR-enabled repeater device, and wherein the UE or the CPE is an EN-DC device. 3. The communication device of claim 1 , wherein in the receive-only mode, a further communication of input RF signals is deactivated. 4. The communication device of claim 1 , wherein the digital signal processor is further configured to establish a short-range wireless communication link with the UE or the CPE that is in the specified proximal range of the communication device, wherein the control information from the UE or the CPE is acquired based on the established short-range wireless communication link. 5. The communication device of claim 1 , wherein the control information comprises information of one or more signal synchronization blocks (SSBs), and wherein the control information indicates a set of potential carrier frequencies shared via the LTE network. 6. The communication device of claim 1 , further comprising a phase-locked loop (PLL) circuit, wherein the digital signal processor is further configured to tune the PLL to radio burst of a signal synchronization block (SSB) for each carrier frequency of a plurality of carrier frequencies for the PSS search, based on the aquired control information, wherein the plurality of carrier frequencies corresponds to a plurality of SSB frequencies. 7. The communication device of claim 6 , wherein the digital signal processor is further configured to align a timing offset of the beam reception to a frame structure of a 5G NR radio frame based on the detected PSS for the at least one SSB location, wherein the detected PSS indicates a timing boundary of the 5G NR radio frame. 8. The communication device of claim 1 , wherein the digital signal processor is further configured to sort the received plurality of different beams of RF signals that are received at the communication device based on the measured received signal strength for each beam of the plurality of different beams, wherein the measured received signal strength is a received signal strength indicator (RSSI) measurement. 9. The communication device of claim 1 , wherein the digital signal processor is further configured to decode a physical cell identity of the beam of RF signals that has the highest received signal strength and a set of other beams of RF signals that has the received signal strength greater than a threshold signal strength value. 10. The communication device of claim 9 , further comprising a memory,wherein the digital signal processor is further configured to store, in the memory, the decoded physical cell identities (PCIs) of the beam of RF signals that has the highest received signal strength and the set of other beams of RF signals that has the received signal strength greater than the threshold signal strength value. 11. The communication device of claim 10 , wherein the digital signal processor is further configured to acquire a physical cell identity (PCI) of a new radio (NR)-enabled base station and additional carrier information from the UE or the CPE based on the communication of the beam of RF signals in the NR frequency band,wherein the PCI of the NR-enabled base station and carrier information is acquired over a short-range wireless communication link established with the UE or the CPE, and wherein the acquisition of the PCI of the NR-enabled base station and additional carrier information from the UE or the CPE indicates an assignment of the NR carrier frequency to the UE or the CPE. 12. The communication device of claim 11 , wherein the digital signal processor is further configured to compare the PCI of the NR-enabled base station acquired from the UE or the CPE with the stored PCIs in the memory. 13. The communication device of claim 12 , wherein the digital signal processor is further configured to validate the beam acquisition at the UE or the CPE for the non-standalone access to the beam of RF signals in the NR frequency band as successful based on a match of the acquired PCI of the NR-enabled base station and the PCI associated with the beam of RF signals that has the highest received signal strength. 14. The communication device of claim 13 , wherein the digital signal processor is further configured to initiate an uplink communication by application of beam reciprocity to the communicated beam of RF signals in the NR frequency band from the UE or the CPE. 15. A method, comprising:in a communication device that includes a digital signal processor:initiating, by the digital signal processor, beam acquisition in a receive-only mode; retrieving, by the digital signal processor, control information directly from a first base station over a long-term evolution (LTE) control plane link, or from at least one of a user equipment (UE) or a customer premise equipment (CPE) that is in a specified proximal range of the communication device, wherein the UE or the CPE is in a radio resource control (RRC) connected state over a LTE network; setting, by the digital signal processor, beam reception at the communication device to an omni-mode in which a plurality of different beams of RF signals are receivable at the communication device from a plurality of different directions; executing, by the digital signal processor, a primary signal synchronization (PSS) search from each signal synchronization block (SSB) location of a plurality of SSB locations based on the control information; detecting, by the digital signal processor, the PSS for at least one SSB location based on the executed PSS search; measuring, by the digital signal processor, a received signal strength for each beam of the plurality of different beams of RF signals for each SSB location of the plurality of SSB locations in accordance with a PSS timing of the detected PSS; switching, by the digital signal processor, to a beam of RF signals that has a highest received signal strength of the received plurality of different beams of RF signals for the beam reception; and activating, by the digital signal processor, communication of the beam of RF signals that has the highest received signal strength in a new radio (NR) frequency band to the UE or the CPE for non-standalone access to the beam of RF signals in the NR frequency band at the UE or the CPE. 16. The method of claim 15 , further comprising establishing, by the digital signal processor, a short-range wireless communication link with the UE or the CPE that is in the specified proximal range of the communication device, wherein the control information from the UE or the CPE is acquired based on the established short-range wireless communication link. 17. The method of claim 15 , further comprising tuning a phase-locked loop (PLL) circuit of the communication device to radio burst of a signal synchronization block (SSB) for each carrier frequency of a plurality of carrier frequencies for the PSS search, based on the control information. 18. The method of claim 15 , further comprising aligning, by the digital signal processor, a timing offset of the beam reception to a frame structure of a 5G NR radio frame based on the detected PSS for the at least one SSB location, wherein the detected PSS indicates a timing boundary of the 5G NR radio frame. 19. The method of claim 15 , further comprising validating, by the digital signal processor, the beam acquisition at the UE or the CPE for the non-standalone access to the beam of RF signals in the NR frequency band as successful based on a match of a physical cell identity (PCI) of a NR-enabled base station and the PCI associated with the beam of RF signals that has the highest received signal strength, wherein the PCI of the NR-enabled base station is acquired from the UE or the CPE over a short-range wireless communication link. 20. A method, comprising:in a communication device that includes a digital signal processor:initiating, by the digital signal processor, beam acquisition in a receive-only mode; establishing, by the digital signal processor, a short-range wireless communication link with a user equipment (UE) or a customer premise equipment (CPE) that is in a specified proximal range of the communication device; retrieving, by the digital signal processor, control information directly from a first base station over a long-term evolution (LTE) control plane link or from the UE or the CPE based on the established short-range wireless communication link, wherein the UE or the CPE is in a radio resource control (RRC) connected state over a LTE network; setting, by the digital signal processor, beam reception at the communication device to an omni-mode in which a plurality of different beams of RF signals are receivable at the communication device from a plurality of different directions; executing, by the digital signal processor, a primary signal synchronization (PSS) search from each signal synchronization block (SSB) location of a plurality of SSB locations based on the control information; detecting, by the digital signal processor, the PSS for at least one SSB location based on the executed PSS search; activating, by the digital signal processor, reception of a beam of RF signals from a (new radio (NR)-enabled base station in a new radio (NR) frequency that has the highest received signal strength in comparison to other beams of the plurality of different beams of RF signals and subsequent communication of the beam of RF signals in the NR frequency that has the highest received signal strength to the UE or the CPE; retrieving, by the digital signal processor, a physical cell identity (PCI) of a NR-enabled base station and additional carrier information from the UE or the CPE over the established short-range wireless communication link; and validating, by the digital signal processor, the beam acquisition at the UE or the CPE for a non-standalone access to the beam of RF signals in the NR frequency band as successful based on a match of the PCI of the NR-enabled base station acquired from the UE or the CPE with the PCI associated with the beam of RF signals that has the highest received signal strength.
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