User equipment location estimation in a wireless network with base stations supporting multi-beam operation

文档序号：621177 发布日期：2021-05-07 浏览：26次中文

阅读说明：本技术 在无线网络中利用支持多波束操作的基站的用户设备定位估计 (User equipment location estimation in a wireless network with base stations supporting multi-beam operation ) 是由 P·巴苏基 A·贝里格伦于 2019-09-27 设计创作，主要内容包括：一种操作基站的方法包括：确定与由基站在多个定向波束上进行的定位参考信号(PRS)传输相关联的调度,所述多个定向波束具有与多个可配置波束方向中的至少一部分相对应的方向,所述调度是基于所述基站进行的PRS传输与所述定向波束上的来自至少一个其它基站的PRS传输的协调的；并且基于所确定的调度,在多个定向波束中的每一者上发送PRS。(A method of operating a base station comprising: determining a schedule associated with Positioning Reference Signal (PRS) transmissions by a base station on a plurality of directional beams having directions corresponding to at least a portion of a plurality of configurable beam directions, the schedule based on coordination of PRS transmissions by the base station with PRS transmissions from at least one other base station on the directional beams; and transmitting a PRS on each of the plurality of directional beams based on the determined schedule.)

1. A method of operating a base station (105a, 105b, 105c, 105d, 105e), the method comprising the steps of:

determining (400) a schedule associated with transmission of positioning reference signals, PRSs, by a base station on a plurality of directional beams having directions corresponding to at least a portion of a plurality of configurable beam directions, the schedule being based on coordination of PRS transmissions by the base station with PRS transmissions from at least one other base station on a directional beam; and is

Sending (405) the PRS on each of the plurality of directional beams based on the determined schedule.

2. The method of claim 1, wherein the base station is a first base station, wherein the at least one other base station comprises a second base station, and wherein the scheduling for PRS transmissions on each of the plurality of directional beams is determined by coordinating PRS transmissions from the first base station with PRS transmissions from the second base station that are scheduled to be transmitted on directional beams in the following manner: causing PRS transmissions from the first base station to occur within a predetermined time period from PRS transmissions from the second base station (500).

3. The method of claim 2, wherein the schedule for PRS transmissions on each of the plurality of directional beams is determined by: causing PRS transmissions sent from the first base station to be coordinated in a defined geographic area with PRS transmissions from the second base station that are scheduled to be sent on the directional beam (600).

4. The method of claim 2 or 3, wherein the scheduling for PRS transmissions on each of the plurality of directional beams is determined by: based on reducing interference between PRS transmissions sent from the first base station and PRS transmissions sent from the second base station by multiplexing a first resource associated with PRS transmissions sent from the first base station and a second resource associated with PRS transmissions sent from the second base station such that PRS transmissions sent from the first base station are coordinated with PRS transmissions from the second base station that are scheduled to be sent on the directional beam (700).

5. The method of claim 4, wherein the first resources comprise a first sub-frequency and a first time slice, and the second resources comprise a second sub-frequency and a second time slice.

6. The method of claim 3 or 4, wherein a length of the predetermined time period is based on mobility characteristics of user equipments, UEs, within the defined geographical area (800).

7. The method of claim 1 or 2, wherein determining (400) the schedule for PRS transmissions on each of the plurality of directional beams comprises:

generating (900) a schedule for PRS transmissions on each of the plurality of directional beams in order to complete PRS transmissions on each of the plurality of beams within a PRS burst interval.

8. The method of claim 7, wherein the PRS burst interval is a first burst interval of a plurality of PRS burst intervals, the method further comprising:

generating (1000) a schedule for PRS transmissions on each of the plurality of directional beams in order to complete PRS transmissions on each of the plurality of beams within each of the plurality of PRS burst intervals.

9. The method of claim 8, wherein individual ones of the plurality of PRS burst intervals are scheduled to occur periodically (1100).

10. The method of claim 8, wherein individual ones of the plurality of PRS burst intervals are scheduled to occur consecutively (1200).

11. The method according to any one of claims 1 to 10, further comprising the steps of:

assigning (1300) beam index identifications to the plurality of directional beams, respectively; and is

Wherein the scheduling is identified based on the beam index (1310).

12. The method of claim 11, further comprising the steps of:

transmitting (1500) the schedule, a number of at least a part of a plurality of configurable beam directions, a number of the plurality of configurable beam directions, the beam index identification, a bandwidth of each of the plurality of directional beams or a time domain characteristic of each of the plurality of directional beams to a positioning node.

13. The method of claim 12, wherein transmitting the schedule, a number of at least a portion of the plurality of configurable beam directions, a number of the plurality of configurable beam directions, the beam index identification, a bandwidth of each of the plurality of directional beams, or a time domain characteristic of each of the plurality of directional beams to the positioning node is performed after transmission of a Synchronization Signal Block (SSB) (1600).

14. The method of claims 1-13, wherein the schedule is a resource allocation schedule that identifies time slices and sub-frequencies used by the base station for PRS transmissions on the plurality of directional beams;

the method further comprises the steps of:

assigning (1300) beam index identifications to the plurality of directional beams, respectively, the beam index identifications corresponding to time slice and sub-frequency identification pairs, respectively;

wherein the resource allocation schedule is identified based on the beam index (1310).

15. A method of operating a user equipment, UE, the method comprising the steps of:

for each of the first and second base stations, receiving (1700), from a positioning node, information associated with positioning reference signal, PRS, transmissions on a plurality of directional beams, the information comprising a schedule based on: coordination of PRS transmissions by the first and second base stations on the plurality of directional beams, and the plurality of directional beams having directions that respectively correspond to at least a portion of a plurality of configurable beam directions; and

receiving (1705) a first PRS signal from the first base station on a first directional beam of the plurality of directional beams and a second PRS signal from the second base station on a second directional beam of the plurality of directional beams based on the scheduling, the scheduling being based on the coordination of PRS transmissions.

16. The method of claim 15, further comprising the steps of:

performing (1710) observed time difference of arrival, OTDOA, measurements based on the first PRS signal, the second PRS signal, and a third PRS signal received from a third base station; and is

Transmitting (1720) reference signal time difference measurement, RSTD, information based on the OTDOA measurements.

17. The method of claim 15 or 16, wherein the information associated with the transmission of PRS signals by the first base station on the plurality of directional beams comprises: a number of at least a portion of a plurality of configurable beam directions, a number of the plurality of configurable beam directions, a beam index identification respectively assigned to each of the plurality of directional beams, a bandwidth of each of the plurality of directional beams, or a time domain characteristic of each of the plurality of directional beams (1800).

18. The method according to claims 15 to 17, further comprising the steps of:

transmitting (1900) to the positioning node: a beam index identification assigned to a directional beam of the plurality of directional beams that received the first PRS signal, an angle of arrival AoA associated with a directional beam of the plurality of directional beams that received the first PRS signal, or an angle of departure AoD associated with a directional beam of the plurality of directional beams that received the first PRS signal.

19. The method of claim 17 or 18, wherein the schedule is a resource allocation schedule identifying time slices and sub-frequencies used by the first and second base stations for PRS transmissions on the plurality of directional beams; and is

Wherein the beam index identifications correspond to time slice and sub-frequency identification pairs, respectively.

20. A method of operating a positioning node, the method comprising the steps of:

receiving (2000) information from each of a plurality of base stations, the information comprising a plurality of configurable beam directions suitable for positioning reference signal, PRS, transmissions;

transmitting (2015), to a User Equipment (UE), for each of the plurality of base stations, a schedule associated with PRS transmissions by the respective base station on the plurality of directional beams, the schedule being based on coordination of PRS transmissions by the plurality of base stations on the plurality of directional beams; and

receiving (2020) reference signal time difference measurement, RSTD, information from the UE based on a first PRS signal transmitted by a first base station of the plurality of base stations, a second PRS signal transmitted by a second base station of the plurality of base stations, and a third PRS signal transmitted by a third base station of the plurality of base stations.

21. The method of claim 20, further comprising the steps of:

transmitting (2010), by the positioning node, the schedule to the plurality of base stations prior to transmitting the schedule to the UE;

wherein the schedule is generated by the positioning node based on information received from the plurality of base stations, and

wherein the plurality of directional beams have directions corresponding to at least a portion of a plurality of configurable beam directions.

22. The method of claim 20 or 21, wherein the received information further comprises: a number of at least a portion of a plurality of configurable beam directions, a number of the plurality of configurable beam directions, a beam index identification respectively assigned to each of the plurality of directional beams, a bandwidth of each of the plurality of directional beams, or a time domain characteristic of each of the plurality of directional beams (2100).

23. The method according to any one of claims 20 to 22, further comprising the step of:

receiving (2200), from the UE, for each of the first, second and third base stations of the plurality of base stations, the following: a beam index identification assigned to a directional beam of the plurality of directional beams that transmits the PRS signal, an angle of arrival (AoA) associated with a directional beam of the plurality of directional beams that transmits the PRS signal, or an angle of departure (AoD) associated with a directional beam of the plurality of directional beams that transmits the PRS signal.

24. The method of claim 23, further comprising the steps of:

determining (2300) an observed time difference of arrival, OTDOA, position of the UE based on the RSTD information, the respective beam index identifications, the respective AoA, or the respective AoD.

25. The method of any of claims 20 to 24, wherein the schedule is determined as follows: causing PRS transmissions by respective ones of the plurality of base stations on the plurality of directional beams to be coordinated among the respective ones of the plurality of base stations to occur within a predetermined time period (2400).

26. The method of any of claims 20 to 25, wherein the schedule is determined as follows: such that PRS transmissions by respective ones of the plurality of base stations on the plurality of directional beams are coordinated among the respective ones of the plurality of base stations in a defined geographic area (2500).

27. The method of any of claims 20 to 26, wherein the schedule is determined as follows: reducing interference between PRS transmissions by respective ones of the plurality of base stations on the plurality of directional beams and transmissions by another respective one of the plurality of base stations for each of the plurality of base stations based on multiplexing a first resource associated with PRS transmissions sent from the respective ones of the plurality of base stations and a second resource associated with PRS transmissions sent from the another respective one of the plurality of base stations such that PRS transmissions by the respective ones of the plurality of base stations on the plurality of directional beams are coordinated among the respective ones of the plurality of base stations (2600).

28. The method of claims 22-27, wherein the schedule is a resource allocation schedule identifying time slices and sub-frequencies used by PRS transmissions by the respective base stations on the plurality of directional beams; and is

Wherein the beam index identifications correspond to time slice and sub-frequency identification pairs, respectively.

29. A base station (105a, 105b, 105c, 105d, 105e), the base station comprising:

a processor (2802); and

a memory (2810), the memory (2810) coupled to the processor, and the memory (2810) comprising computer readable program code (2812) embodied in the memory, the computer readable program code (2812) executable by the processor to perform operations comprising:

determining (400) a schedule associated with positioning reference signal, PRS, transmissions by the base station on a plurality of directional beams having directions corresponding to at least a portion of a plurality of configurable beam directions, the schedule based on coordination of PRS transmissions by the base station with PRS transmissions from at least one other base station on a directional beam; and

sending (405) the PRS on each of the plurality of directional beams based on the determined schedule.

30. A user equipment, UE, device (110a, 110b, 110c), the user equipment device (110a, 110b, 110c) comprising:

a processor (3002); and

a memory (3010), the memory (3010) coupled to the processor, and the memory (3010) comprising computer readable program code (3012) embodied in the memory, the computer readable program code (3012) executable by the processor to perform operations comprising:

31. A positioning node (120), the positioning node (120) comprising:

a processor (3202); and

a memory (3210), the memory (3210) coupled to the processor, and the memory (3210) comprising computer readable program code (3212) embodied in the memory, the computer readable program code (3212) executable by the processor to perform operations comprising:

for each of the plurality of base stations, transmitting (2015) to a user equipment, UE, a schedule associated with PRS transmissions by the respective base station on the plurality of directional beams, the schedule being based on coordination of PRS transmissions by the plurality of base stations on the plurality of directional beams; and

Technical Field

The present inventive concept relates generally to wireless communication networks and, more particularly, to User Equipment (UE) location estimation in wireless communication networks.

Background

Observed time difference of arrival (OTDOA) is a positioning technology related to Radio Access Technology (RAT), which has been widely deployed in Long Term Evolution (LTE) networks. A device/User Equipment (UE) receives reference signals from a plurality of base stations (eNode-bs) and then performs time difference of arrival (TDOA) measurements. The measurement results are sent from the UE to a Location Server (LS) via the eNode-B using the LTE Positioning Protocol (LPP). The LS then performs a positioning estimation using triangulation based on measurements from at least three eNode-B facilities.

A Positioning Reference Signal (PRS) is one of the reference signals in LTE that is used to facilitate OTDOA method-based UE positioning determination. The basic operation of calculating the time of arrival (TOA) from each eNodeB may be described as follows: first, the UE receives a reference signal (e.g., PRS) and then cross-correlates with the locally generated reference signal. The cross-correlations from different transmit antennas, receive antennas, and subframes may be accumulated so that good cross-correlation peaks may be obtained. The measured time delay can be obtained from the phase information of the cross-correlation peak. The previous operations are repeated to obtain time delays from several enodebs (e.g., a reference eNodeB and a neighbor eNodeB). Reference Signal Time Difference (RSTD) measurements are obtained by subtracting the time delays of the neighbor enodebs from the time delay of the reference (serving) eNodeB. The UE may also evaluate and classify the quality of the RSTD measurements. The UE sends all RSTD measurement knots and RSTD measurement quality information to the LS, which determines a positioning estimate for the UE.

In LTE, PRSs are transmitted by an eNodeB under the assumption that the eNodeB has omni/sector antennas, but there is no indication in terms of beams of antennas used in transmitting PRSs. Similarly, it is desirable for the UE to receive a beam carrying PRS using an omni-directional or relatively wide antenna. A UE may receive a PRS when the UE is within a cell associated with an eNodeB that transmitted the PRS signal.

Disclosure of Invention

According to some embodiments of the inventive concept, a method of operating a base station comprises: determining a schedule associated with transmission of Positioning Reference Signals (PRSs) by a base station on a plurality of directional beams having directions corresponding to at least a portion of a plurality of configurable beam directions, the schedule based on coordination of PRS transmissions by the base station with PRS transmissions from at least one other base station on the directional beams; and transmitting a PRS on each of the plurality of directional beams based on the determined schedule.

In other embodiments, the base station is a first base station, wherein the at least one other base station includes a second base station, and wherein the schedule for PRS transmissions on each of the plurality of directional beams is determined by coordinating PRS transmissions from the first base station with PRS transmissions from the second base station that are scheduled to be transmitted on the directional beams in the following manner: causing a PRS transmission from the first base station to occur within a predetermined time period from a PRS transmission from the second base station.

In still other implementations, the schedule for PRS transmissions on each of a plurality of directional beams is determined as follows: such that PRS transmissions sent from a first base station are coordinated in a defined geographical area with PRS transmissions from a second base station scheduled to be sent on directional beams.

In still other implementations, the schedule for PRS transmissions on each of a plurality of directional beams is determined as follows: interference between a PRS transmission sent from a first base station and a PRS transmission sent from a second base station is reduced based on coordinating the PRS transmission sent from the first base station with a PRS transmission from the second base station that is scheduled to be sent on a directional beam by multiplexing a first resource associated with the PRS transmission sent from the first base station and a second resource associated with the PRS transmission sent from the second base station.

In still other embodiments, the first resource includes a first sub-frequency and a first time segment, and the second resource includes a second sub-frequency and a second time segment.

In still other embodiments, the length of the predetermined time period is based on mobility characteristics of User Equipments (UEs) within the defined geographic area (800).

In still other implementations, determining the schedule for PRS transmissions on each of the plurality of directional beams includes: a schedule for PRS transmissions on each of a plurality of directional beams is generated in order to complete PRS transmissions on each of the plurality of beams within a PRS burst interval.

In still other embodiments, the PRS burst interval is a first burst interval of a plurality of PRS burst intervals. The method further comprises the following steps: a schedule for PRS transmissions on each of a plurality of directional beams is generated in order to complete PRS transmissions on each of the plurality of beams within each of a plurality of PRS burst intervals.

In still other embodiments, individual ones of the plurality of PRS burst intervals are scheduled to occur periodically.

In still other embodiments, individual ones of the plurality of PRS burst intervals are scheduled to occur consecutively.

In still other embodiments, the method further comprises assigning beam index identifications to the plurality of directional beams, respectively. The scheduling is identified based on a beam index.

In still other embodiments, the positioning node is transmitted a schedule, a number of at least a portion of the plurality of configurable beam directions, a number of the plurality of configurable beam directions, a beam index identification, a bandwidth of each of the plurality of directional beams, or a time domain characteristic of each of the plurality of directional beams.

In still other embodiments, transmitting the schedule, a number of at least a portion of the plurality of configurable beam directions, a number of the plurality of configurable beam directions, a beam index identification, a bandwidth of each of the plurality of directional beams, or a time domain characteristic of each of the plurality of directional beams to the positioning node is performed after transmission of a Synchronization Signal Block (SSB).

In still other embodiments, the schedule is a resource allocation schedule that identifies time slices and sub-frequencies used by PRS transmissions by the base station on multiple directional beams. The method also includes assigning beam index identifications to the plurality of directional beams, respectively, the beam index identifications corresponding to the time slice and sub-frequency identification pairs, respectively. The resource allocation schedule is identified based on the beam index.

In some embodiments of the inventive concept, a method of operating a User Equipment (UE) comprises: for each of a first base station and a second base station, receiving, from a positioning node, information associated with Positioning Reference Signal (PRS) transmissions on a plurality of directional beams, the information comprising a schedule based on: coordination of PRS transmissions by the first and second base stations on a plurality of directional beams, and the plurality of directional beams having directions respectively corresponding to at least a portion of the plurality of configurable beam directions; and receiving, based on the scheduling, a first PRS signal from a first base station on a first directional beam of the plurality of directional beams and a second PRS signal from a second base station on a second directional beam of the plurality of directional beams, the scheduling being based on coordination of PRS transmissions.

In further embodiments, the method further includes performing an observed time difference of arrival (OTDOA) measurement based on the first PRS signal, the second PRS signal, and a third PRS signal received from a third base station; and transmitting reference signal time difference measurement (RSTD) information based on the OTDOA measurements.

In still further embodiments, the information associated with the transmission of PRS signals by the first base station on the plurality of directional beams comprises: a number of at least a portion of the plurality of configurable beam directions, a number of the plurality of configurable beam directions, a beam index identification respectively assigned to each of the plurality of directional beams, a bandwidth of each of the plurality of directional beams, or a time domain characteristic of each of the plurality of directional beams.

In still further embodiments, the method further comprises transmitting to the positioning node: a beam index identification assigned to a directional beam of the plurality of directional beams that received the first PRS signal, an angle of arrival (AoA) associated with the directional beam of the plurality of directional beams that received the first PRS signal, or an angle of departure (AoD) associated with the directional beam of the plurality of directional beams that received the first PRS signal.

In still further embodiments, the schedule is a resource allocation schedule that identifies time slices and sub-frequencies used by the first and second base stations for PRS transmissions on the plurality of directional beams, and the beam index identifications correspond to pairs of time slice and sub-frequency identifications, respectively.

In some embodiments of the inventive concept, a method of operating a positioning node comprises: receiving information from each of a plurality of base stations, the information comprising a plurality of configurable beam directions suitable for Positioning Reference Signal (PRS) transmissions; for each of a plurality of base stations, transmitting to a User Equipment (UE) a schedule associated with PRS transmissions by the respective base station on a plurality of directional beams, the schedule based on coordination of PRS transmissions by the plurality of base stations on the plurality of directional beams; and receiving reference signal time difference measurement (RSTD) information from the UE based on the first PRS signal transmitted by the first base station of the plurality of base stations, the second PRS signal transmitted by the second base station of the plurality of base stations, and the third PRS signal transmitted by the third base station of the plurality of base stations.

In other embodiments of the inventive concept, the method further comprises: transmitting, by the positioning node, the schedule to the plurality of base stations prior to transmitting the schedule to the UE. The schedule is generated by the positioning node based on information received from the plurality of base stations, and the plurality of directional beams have directions corresponding to at least a portion of the plurality of configurable beam directions.

In still other embodiments of the inventive concept, the received information further comprises: a number of at least a portion of the plurality of configurable beam directions, a number of the plurality of configurable beam directions, a beam index identification respectively assigned to each of the plurality of directional beams, a bandwidth of each of the plurality of directional beams, or a time domain characteristic of each of the plurality of directional beams.

In still other embodiments of the inventive concept, the method further comprises: for each of a first base station, a second base station, and a third base station of a plurality of base stations, receiving from a UE: a beam index identification assigned to a directional beam of the plurality of directional beams that transmits a PRS signal, an angle of arrival (AoA) associated with a directional beam of the plurality of directional beams that transmits a PRS signal, or an angle of departure (AoD) associated with a directional beam of the plurality of directional beams that transmits a PRS signal.

In still other embodiments of the inventive concept, the method further comprises determining an observed time difference of arrival (OTDOA) location of the UE based on the RSTD information, the respective beam index identification, the respective AoA, or the respective AoD.

In still other embodiments of the inventive concept, the schedule is determined as follows: PRS transmissions by respective ones of the plurality of base stations on the plurality of directional beams are coordinated among the respective ones of the plurality of base stations to occur within a predetermined time period.

In still other embodiments of the inventive concept, the schedule is determined as follows: such that PRS transmissions by respective ones of the plurality of base stations on the plurality of directional beams are coordinated among the respective ones of the plurality of base stations in the defined geographic area.

In still other embodiments of the inventive concept, the schedule is determined as follows: interference between PRS transmissions by respective ones of the plurality of base stations on the plurality of directional beams and transmissions by another respective one of the plurality of base stations is reduced for each of the plurality of base stations based on multiplexing first resources associated with PRS transmissions sent from the respective ones of the plurality of base stations and second resources associated with PRS transmissions sent from the another respective one of the plurality of base stations such that PRS transmissions by the respective ones of the plurality of base stations on the plurality of directional beams are coordinated among the respective ones of the plurality of base stations.

In still other embodiments of the inventive concept, the schedule is a resource allocation schedule that identifies time segments and sub-frequencies used by PRS transmissions by respective base stations on multiple directional beams. The beam index identifications correspond to pairs of time slices and sub-frequency identifications, respectively.

In some embodiments of the inventive concept, a base station includes a processor and a memory coupled to the processor and including computer readable program code embodied in the memory, the computer readable program code executable by the processor to perform operations comprising: determining a schedule associated with Positioning Reference Signal (PRS) transmissions by a base station on a plurality of directional beams having directions corresponding to at least a portion of a plurality of configurable beam directions, the schedule based on coordination of PRS transmissions by the base station with PRS transmissions from at least one other base station on the directional beams; and transmitting a PRS on each of the plurality of directional beams based on the determined schedule.

In some embodiments of the inventive concept, a user equipment comprises a processor and a memory coupled to the processor and including computer readable program code embodied in the memory, the computer readable program code executable by the processor to perform operations comprising: for each of the first and second base stations, receiving from a positioning node information associated with Positioning Reference Signal (PRS) transmissions on a plurality of directional beams, the information comprising a schedule based on: coordination of PRS transmissions by the first and second base stations on a plurality of directional beams, and the plurality of directional beams having directions respectively corresponding to at least a portion of the plurality of configurable beam directions; and receiving, based on the scheduling, a first PRS signal from a first base station on a first directional beam of the plurality of directional beams and a second PRS signal from a second base station on a second directional beam of the plurality of directional beams, the scheduling being based on coordination of PRS transmissions.

In some embodiments of the inventive concept, a positioning node comprises a processor and a memory coupled to the processor and including computer readable program code embodied in the memory, the computer readable program code executable by the processor to perform operations comprising: receiving information from each of a plurality of base stations, the information comprising a plurality of configurable beam directions suitable for Positioning Reference Signal (PRS) transmissions; for each of a plurality of base stations, transmitting to a User Equipment (UE) a schedule associated with PRS transmissions by the respective base station on a plurality of directional beams, the schedule being based on coordination of PRS transmissions by the plurality of base stations on the plurality of directional beams; and receiving reference signal time difference measurement (RSTD) information from the UE based on the first PRS signal transmitted by the first base station of the plurality of base stations, the second PRS signal transmitted by the second base station of the plurality of base stations, and the third PRS signal transmitted by the third base station of the plurality of base stations.

It should be noted that aspects described with respect to one embodiment may be combined in different embodiments, although not specifically described with respect thereto. That is, features of all embodiments and/or any embodiments may be combined in any manner and/or combination. Moreover, other methods, systems, articles of manufacture, and/or computer program products according to embodiments of the present subject matter will be or become apparent to one with skill in the art upon review of the following description of the drawings and detailed description. It is intended that all such additional systems, methods, articles of manufacture, and/or computer program products be included within this description, be within the scope of the present subject matter, and be protected by the accompanying claims. It is also intended that all embodiments disclosed herein can be implemented individually or in any manner and/or combination.

Drawings

Other features of the embodiments will be more readily understood from the following detailed description of the specific embodiments when read in conjunction with the accompanying drawings, in which:

fig. 1 is a block diagram of a wireless communication network including base stations supporting multi-beam operation, according to some embodiments of the present inventive concept;

FIG. 2 is a block diagram illustrating scheduling of a base station for transmitting Positioning Reference Signals (PRSs) on various beams according to some embodiments of the present inventive concept;

FIG. 3 is a message flow diagram illustrating communications between a base station, a User Equipment (UE) and a positioning node according to some embodiments of the present inventive concept;

fig. 4-27 are flowcharts illustrating operations for UE location estimation in a wireless network with base stations supporting multi-beam operation, according to some embodiments of the present inventive concept;

fig. 28 is a block diagram illustrating a base station according to some embodiments of the inventive concept;

fig. 29 is a block diagram illustrating functional modules in a base station according to some embodiments of the present inventive concept;

fig. 30 is a block diagram illustrating a UE according to some embodiments of the inventive concept;

fig. 31 is a block diagram illustrating functional modules in a UE according to some embodiments of the inventive concept;

fig. 32 is a block diagram illustrating a positioning node according to some embodiments of the inventive concept; and

fig. 33 is a block diagram illustrating functional modules in a positioning node according to some embodiments of the present inventive concept.

Detailed Description

In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of embodiments of the present disclosure. However, it will be understood by those skilled in the art that the present invention may be practiced without these specific details. In some instances, well-known methods, procedures, components, and circuits have not been described in detail so as not to obscure the present disclosure. It is intended that all embodiments disclosed herein can be implemented individually or combined in any way and/or by combination. Aspects described with respect to one embodiment may be incorporated into a different embodiment, although not specifically described with respect thereto. That is, features of all embodiments and/or any embodiments may be combined in any manner and/or combination.

In a 5G New Radio (NR) network, both a base station (e.g., a gNB) and a UE may be configured to support multi-beam operation. For example, the Synchronization Signal Block (SSB) in NR may be configured to operate with up to 64 narrow beams. Depending on the purpose (e.g., initial access, broadcast transmission), beams are typically transmitted using beam scanning to cover a portion or the entire cell, with beams being transmitted continuously in time. As a result, PRSs may also be transmitted in different beams at different points in time. Thus, each individual UE may receive PRSs of one or more beams from each gNB. The PRSs for those different beams may be transmitted at different points in time.

Some embodiments of the inventive concept derive from the following recognition: for position estimation of a UE using OTDOA, it may be desirable to receive multiple PRSs from different base stations at or near the same time, and to be able to calculate the time difference between PRSs transmitted from different base stations to estimate the position with sufficient accuracy. Without beam coordination, the following may occur: the UE cannot receive all PRSs used to obtain RSTD measurements (which the location server uses for location determination). Thus, according to some embodiments, a schedule may be generated for one or more gnbs in a 5G NR communication network for transmitting PRSs on various directional beams generated by the individual gnbs. To ensure that a UE receives a sufficient number of beams (e.g., three or more beams) within a specified time period to perform time of arrival (TOA) measurements for use in OTDOA positioning or position estimation methods, a schedule may be determined in which PRS transmissions on beams associated with different base stations are coordinated. For example, in some embodiments, all PRS transmissions from various base stations transmitted within a predetermined geographic area may be scheduled to occur within a specified time period (e.g., 0.5 ms). Another criterion used in scheduling PRS transmissions between various base stations is: interference between a base station performing PRS transmission and one or more other base stations performing beam transmission (PRS or other) within a serving or neighbor cell is minimized or reduced. In some embodiments, PRS transmissions from various base stations within a predetermined geographic area may be coordinated to ensure that a sufficient number of PRS transmissions are available for a time period for a UE is based on the mobility characteristics of the UE. For example, if a group of base stations includes beams for a highway where UEs in a vehicle may be moving at a relatively high speed, PRS transmissions from the base stations will need to occur within a short period of time, otherwise the UEs may leave a geographic area before receiving a sufficient number of PRS transmissions from different base stations.

The UE may receive multiple PRSs from respective directional beams associated with different gnbs and may generate RSTD measurements for these signals. The UE may report these RSTD measurements to a positioning node, e.g., a Serving Mobile Location Center (SMLC) or a Location Server (LS), for use in determining a location estimate for the UE using OTDOA. In addition to the RSTD measurement results, the UE may report one or more of the following to the positioning node: the identity of the particular beams from the individual base stations used in the RSTD measurements, the angle of arrival (AoA) of these beams, and the angle of departure (AoD) of these beams. The positioning node may use the AoA information and/or AoD information together with RSTD measurements when performing OTDOA position estimation of the UE.

Fig. 1 is a block diagram of a wireless communication network 100 including base stations supporting multi-beam operation, according to some embodiments of the present inventive concept. The wireless communication network 100 includes five 5G NR base stations, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e configured for multi-beam operation. In some embodiments, base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e may be configured to generate multiple directional beams transmitted at different azimuth angles. Each base station, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e, may be configured to transmit a maximum number of different directional beams, e.g., 64 total beams in some embodiments. In addition, the various base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e may be configured to use less than a maximum number of different directional beams that can be configured for operation. For example, base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d and gNB 5105 e can use 64 different directional beams, but only 16 directional beams since there is no need for transmission in certain geographical directions. Each base station, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e, may allocate one or more sub-frequency and time slices to transmit and/or receive on each beam. The individual beams are separated in time and the entire period from the first active beam to the last active beam may be referred to as a beam sweep.

Base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e may transmit PRSs on respective beams for determining a location of a UE based on OTDOA protocols. To ensure that the UE can receive PRS transmissions, schedules may be generated for the various base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e. Fig. 2 is a block diagram illustrating scheduling used by a base station for transmitting PRSs on respective beams according to some embodiments of the present inventive concept. Referring to fig. 1 and 2, base station gNB1105a transmits PRSs on beams Bm1-1 and Bm1-2, which are received by UEs 110a and 110b, respectively. Base station gNB 2105 b transmits PRSs on beams Bm2-1, Bm2-2, which are received by UEs 110a and 110c, respectively. Base station gNB 2105 b also transmits PRSs on beam Bm 2-2. Base station gNB 3105 c transmits PRSs on beams Bm3-1 and Bm3-2, which are received by UEs 110a and 110b, respectively. Base station gNB4105d transmits PRSs on beams Bm4-2 and Bm4-3, which are received by UEs 110b and 110c, respectively. Base station gNB4105d also transmits PRSs on beam Bm 4-1. Base station gNB 5105 e transmits PRS on Bm5-1, which is received by UE110 c. Base station gNB 5105 e also transmits PRSs on beam Bm 5-2. Although in fig. 1, the respective base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e are shown as transmitting PRSs on only two or three beams, it will be appreciated that base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e may transmit PRSs on more or fewer beams, in accordance with various embodiments of the present inventive concept. According to some embodiments, interference between beams within a serving cell or a neighbor cell may be mitigated. In connected mode, the UE is communicating with the serving cell but may still listen to neighbor cells for measurements. For example, referring to fig. 1, the serving base station of UE110a may be the first base station (105 a). The first base station (105a) may be configured to use beam Bm1-1, while the second base station (105b) may use beam Bm 2-2. Such scheduling reduces interference between beams within the serving cell and/or neighbor cells. That is, by multiplexing the sub-frequency and time segments used for transmission of PRS signals in the frequency domain, the time domain, or both, interference between PRS transmissions from base stations in the same cell or different cells may be reduced.

As shown in fig. 2, base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e and/or positioning node 120 coordinate PRS transmissions according to a schedule identifying the sub-frequencies (vertical axis) and time slices (horizontal axis) of the transmission. The time slots may be defined such that base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e may require an integer number (X) of time slots to perform a full beam scan (i.e., cycle through all operable directional beams). This may be referred to as a PRS burst. The PRS bursts may be repeated continuously without scheduled time delays between bursts, may be repeated periodically, and/or may be repeated asynchronously based on a request from another entity (e.g., UE110a, 110b, 110c or positioning node 120). When switching from one beam to another, a temporal switching gap may occur. This is illustrated in fig. 2, where there is a gap of a certain number M of Orthogonal Frequency Division Multiplexing (OFDM) symbols (shown as two squares in fig. 2) when switching from beam Bm2-1 to beam Bm 2-2. However, during this gap, other base stations may transmit PRSs. In the example shown in fig. 2, base stations gNB 3105 c and gNB4105d transmit during a handover gap of base station gNB 2.

Each UE110a, 110b, 110c may receive PRSs from at least three different ones of base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e, and may generate RSTD measurements for these signals. The UEs 110a, 110b, 110c may report these RSTD measurements to the positioning node 120 (e.g., Location Server (LS) or Serving Mobile Location Center (SMLC)) by way of the base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e for determining a location estimate for the UE 105a, 105b, 105c using OTDOA. In addition to RSTD measurements, the UEs 105a, 105b, 105c may report to the positioning node 120 one or more of: the identity of the particular beams from the individual base stations used in the RSTD measurements, the angle of arrival (AoA) and angle of departure (AoD) of these beams. The positioning node 120 may use AoA information and/or AoD information together with RSTD measurements when performing OTDOA position estimation for a UE110a, 110b, 110 c.

Fig. 3 is a message flow diagram illustrating communications between a base station (gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d and gNB 5105 e), a UE (110a, 110b, 110c) and a positioning node 120, according to some embodiments of the present inventive concept. As shown in fig. 3, positioning node 120 may request beam configuration and/or PRS scheduling information from one or more of base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e using LTE positioning protocol annex (LPPa). The respective base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d and gNB 5105 e respond to the positioning node 120 with the requested beam configuration and/or PRS scheduling information by means of the LPPa protocol. The positioning node 120 provides beam configuration and/or PRS scheduling information for the base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d and gNB 5105 e to the respective UEs 110a, 110b, 110c using LPP. At a later point in time, the positioning node 120 sends a request to the respective UE110a, 110b, 110c for location information, i.e. RSTD information, beam index or identification information, AoA information and/or AoD information, used in OTDOA position determination. Base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e transmit PRSs on their respective beams during beam scanning, which are received by respective UEs 110a, 110b, 110 c. The UEs 110a, 110b, 110c use the best beams from at least three different base stations (gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d and gNB 5105 e) to collect beam index identification information, AoA information and/or AoD information, along with performing OTDOA measurements, to generate RSTD information, which is then transmitted to the positioning node 120 using LPP. Positioning node 120 may use the received measurement results (RSTD information) along with beam index information, AoA information, and/or AoD information to estimate the OTDOA position of the UE.

Fig. 4-21 are flowcharts illustrating operations for UE location estimation in a wireless network with base stations supporting multi-beam operation, according to some embodiments of the present inventive concept. Referring to fig. 4, operation of a base station (such as one or more of base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e of fig. 1) may include: a schedule associated with transmission of Positioning Reference Signals (PRSs) by a base station on a plurality of directional beams having directions corresponding to at least a portion of a plurality of configurable beam directions is determined (block 400). The schedule may be generated at base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e, at location server 120, and/or partially at base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e and partially at location server. Based on the determined schedule, a PRS is sent on each of a plurality of directional beams (block 405).

Referring to fig. 5, PRS transmission scheduling along with selection of beams to be configured may be coordinated among various base stations, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e to ensure that UEs 110a, 110b, 110c may receive a sufficient number of PRS transmissions from different base stations to perform TOA measurements for use in OTDOA methods. For example, scheduling for PRS transmissions on each of a plurality of directional beams is determined as follows: a PRS transmission sent from a first base station is coordinated or scheduled (arraged) with a PRS transmission from a second base station scheduled to be sent on a directional beam within a predetermined time period (block 500).

In some embodiments, all PRS transmissions from the various base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e that are transmitted within a predetermined geographic area may be scheduled to occur within a specified time period (e.g., 0.5 ms). Thus, referring to fig. 6, scheduling for PRS transmissions on each of a plurality of directional beams is determined as follows: PRS transmissions sent from a first base station are coordinated in a defined geographic area with PRS transmissions from a second base station scheduled to be sent on directional beams (block 600).

Another criterion used in scheduling PRS transmissions between the various base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d and gNB 5105 e is: interference between a base station performing PRS transmission and one or more other base stations performing beam transmission (PRS or other) within a serving or neighbor cell is minimized or reduced. Thus, referring to fig. 7, scheduling for PRS transmissions on each of a plurality of directional beams is determined as follows: PRS transmissions sent from a first base station are coordinated with PRS transmissions from a second base station scheduled to be sent on a directional beam based on reducing interference between PRS transmissions sent from the first base station and transmissions on the directional beam from a third base station associated with a serving cell (e.g., the first base station) or based on reducing interference between PRS transmissions sent from the first base station and transmissions on the directional beam from a fourth base station associated with a neighbor cell (e.g., the first base station) (block 700).

In some embodiments, PRS transmissions from various base stations within a predetermined geographic area may be coordinated to ensure that a sufficient number of PRS transmissions are available for a time period for a UE is based on the mobility characteristics of the UE. Thus, referring to fig. 8, the length of the predetermined time period may be based on the mobility characteristics of the UEs 110a, 110b, 110c within the defined geographic area (block 800). For example, the network may configure a given time period designed to support all UEs (e.g., fast, slow, or static UEs). A UE traveling at high speed may only have an opportunity to read a small portion of a given time period X.

Referring to fig. 9, the base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB 5105 e may generate a schedule for PRS transmissions on each of a plurality of directional beams to complete the PRS transmissions on each of the plurality of beams within a PRS burst interval (block 900).

The PRS bursts may be repeated continuously without a scheduled time delay between bursts, may be repeated periodically, and/or may be repeated asynchronously based on a request from another entity (e.g., UE110a, 110b, 110c or positioning node 120). Thus, referring to fig. 10, a PRS burst interval may be the first burst interval of a plurality of PRS burst intervals. Scheduling for PRS transmissions on each of a plurality of directional beams may be configured to complete PRS transmissions on each of a plurality of beams within each of a plurality of PRS burst intervals (block 1000). Referring to fig. 11, individual ones of a plurality of PRS burst intervals may be scheduled to occur periodically (block 1100). In other embodiments, referring to fig. 12, individual ones of a plurality of PRS burst intervals may be scheduled to occur consecutively without any scheduling delay between the PRS burst intervals (block 1200).

Referring to fig. 13, in some embodiments, base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB 5105 e may assign beam index identifications to directional beams of a plurality of directional beams, respectively (block 1300). The PRS transmission schedule may be based on these beam identifications (block 1310). According to various embodiments of the inventive concept, beam identification information may be assigned in different ways. Referring to fig. 14, beam index identifications may be respectively assigned to directional beams of a plurality of directional beams based on directions associated with the directional beams of the plurality of directional beams (block 1400). This can be seen as an implicit beam identity assignment. For example, beam index 1 may be transmitted first, then beam index 2, and so on. In some embodiments, beam index 1 may be designated as a beam toward a particular direction (e.g., north), with subsequently transmitted beams being transmitted with a clockwise rotation. The PRS transmission schedule may be based on the beam identification (block 1405). In other embodiments, the beam identification assignment is an explicit identification assigned to each beam, regardless of the transmission direction of each beam. The base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB 5105 e may also transmit cell identification information along with PRS signals via respective beams.

Base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB 5105 e may communicate particular beam configuration information to positioning node 120 in communication with UEs 110a, 110b, 110c to facilitate reception of PRS signals at UEs 110a, 110b, 110 c. Referring to fig. 15, base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB 5105 e may transmit PRS transmission schedules to positioning nodes along with beam configurations including, but not limited to, information identifying: a number of at least a portion of the plurality of configurable beam directions (i.e., the running beam), a number of the plurality of configurable beam directions (i.e., a maximum number of configurable beams), a beam index identification, a bandwidth of each of the plurality of directional beams, and/or a time domain characteristic of each of the plurality of directional beams (block 1500).

Referring to fig. 16, in still other embodiments, transmitting the PRS transmission schedule to the positioning node 120 along with a beam configuration including, but not limited to, information identifying the following is performed after transmission of a Synchronization Signal Block (SSB): a number of at least a portion of the plurality of configurable beam directions (i.e., the running beam), a number of the plurality of configurable beam directions (i.e., a maximum number of configurable beams), a beam index identification, a bandwidth of each of the plurality of directional beams, and/or a time domain characteristic of each of the plurality of directional beams (block 1600).

Referring to fig. 17, operations for a UE (e.g., one or more of UEs 110a, 110b, 110c of fig. 1) to facilitate positioning estimation may include: information associated with PRS transmissions on a plurality of directional beams is received from positioning node 120 for each of a first, second, and third base station of base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e. The plurality of directional beams have directions that respectively correspond to at least a portion of the plurality of configurable beam directions (block 1700). A first PRS signal from a first base station (gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e), a second PRS signal from a second base station (gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e), and a third PRS signal from a third base station (gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e) are received on one of a plurality of directional beams (block 1701705). Although the example embodiments are described with respect to three base stations, the inventive concepts may be applied to a different number of base stations. In some embodiments, three base stations may be the minimum number of base stations to facilitate location estimation as described herein. OTDOA measurement taking is performed based on the first PRS signal, the second PRS signal, and the third PRS signal (block 1710). RSTD information is transmitted, for example, to positioning node 120 based on the OTDOA measurements (block 1720). Thus, the UE110a, 110b, 110c may take OTDOA measurements (e.g., RSTD information) during a measurement time interval, wherein the UE110a, 110b, 110c receives directional beams from at least three base stations (gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB 5105 e) configured to transmit a plurality of different directional beams, wherein one of the beams from one of the base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB4105 5105 e is used as a reference and the other beams are used to determine a time difference of arrival with respect to the beams from the reference base stations gNB1105a, gNB 2105 b, gNB 310 3105 c, gNB4105d, and/or gNB 5105 e.

Referring to fig. 18, the information received from positioning node 120 may include PRS transmission schedules along with beam configuration information for one or more of base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and/or gNB 5105 e, including but not limited to information identifying: a number of at least a portion of the plurality of configurable beam directions (i.e., the running beam), a number of the plurality of configurable beam directions (i.e., a maximum number of configurable beams), a beam index identification, a bandwidth of each of the plurality of directional beams, and/or a time domain characteristic of each of the plurality of directional beams (block 1800).

Referring to fig. 19, a UE110a, 110b, 110c may transmit the following in response to, for example, a location information request from a positioning node 120: a beam index identification assigned to a directional beam of the plurality of directional beams that received the first PRS signal, an AoA associated with the directional beam of the plurality of directional beams that received the first PRS signal, and/or an angle of departure AoD associated with the directional beam of the plurality of directional beams that received the first PRS signal (block 1900). In other embodiments, the UEs 110a, 110b, 110c may transmit beam index information, AoA information, and/or AoD information for all beams involved in the OTDOA/RSTD measurements to the positioning node 120. Cell identification information associated with beams used in OTDOA/RSTD measurements may also be transmitted to positioning node 120.

Referring to fig. 20, operations used by the positioning node 120 (e.g., LS or SMLC) of fig. 1 to facilitate positioning estimation include: information is received from each of a plurality of base stations, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e, the information comprising a plurality of configurable beam directions suitable for Positioning Reference Signal (PRS) transmission (block 2000). Based on the received information, a schedule is generated for each of the plurality of base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e. The scheduling may be associated with PRS transmissions by respective base stations on a plurality of directional beams. The plurality of directional beams may have directions corresponding to at least a portion of the plurality of configurable beam directions (block 2005). The schedule may be transmitted to multiple base stations, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e (block 2010) and to UEs 110a, 110b, 110c (block 2015). The positioning node may receive RSTD information from the UE 120 based on a first PRS signal transmitted by a first base station of the plurality of base stations, a second PRS signal transmitted by a second base station of the plurality of base stations, and a third PRS signal transmitted by a third base station of the plurality of base stations (block 2015).

Referring to fig. 21, the information received from one or more base stations (e.g., the first base station, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e) may further include: beam configuration information for each of the various base stations, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, or gNB 5105 e, including but not limited to information identifying: a number of at least a portion of the plurality of configurable beam directions (i.e., the running beam), a number of the plurality of configurable beam directions (i.e., a maximum number of configurable beams), a beam index identification, a bandwidth of each of the plurality of directional beams, and/or a time domain characteristic of each of the plurality of directional beams (block 2100).

Referring to fig. 22, the positioning node 120 may send a location information request to a UE110a, 110b, 110c and may, in response, receive the following for each of a first, second and third base station of a plurality of base stations, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d or gNB 5105 e, referred to in block 2020 of fig. 20: a beam index assigned to a directional beam of the plurality of directional beams that transmits a PRS signal identifies an AoA associated with the directional beam of the plurality of directional beams that transmits the PRS signal and/or an AoD associated with the directional beam of the plurality of directional beams that transmits the PRS signal (block 2200). Cell identification information associated with beams used in OTDOA/RSTD measurements may also be received from UEs 110a, 110b, 110 c.

Referring to fig. 23, positioning node 120 may determine an OTDOA position for UE110a, 110b, 110c based on the RSTD information, AoA information, and/or AoD information (block 2300).

Referring to fig. 24, PRS transmission scheduling along with selection of beams to be configured may be coordinated among various base stations, gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e to ensure that UEs 110a, 110b, 110c may receive a sufficient number of PRS transmissions from different base stations to perform TOA measurements for use in OTDOA methods. For example, the positioning node 120 may be used to determine the schedule in the following manner: such that PRS transmissions by respective ones of a plurality of base stations on a plurality of directional beams are coordinated among the respective ones of the plurality of base stations over a predetermined time period (block 2400).

In some embodiments, all PRS transmissions from the various base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d, and gNB 5105 e that are transmitted within a predetermined geographic area may be scheduled to occur within a specified time period (e.g., 0.5 ms). Thus, referring to fig. 25, the positioning node 120 may be used to determine the schedule in the following manner: such that PRS transmissions by respective ones of a plurality of base stations on a plurality of directional beams are coordinated among the respective ones of the plurality of base stations in a defined geographic area (block 2500).

Another criterion used in scheduling PRS transmissions between the various base stations gNB1105a, gNB 2105 b, gNB 3105 c, gNB4105d and gNB 5105 e is: interference between a base station performing PRS transmission and one or more other base stations performing beam transmission (PRS or other) within a serving or neighbor cell is minimized or reduced. Thus, referring to fig. 26, the positioning node 120 may be used to determine the schedule in the following manner: based on reducing, for each of the plurality of base stations, interference between PRS transmissions by a respective base station of the plurality of base stations on the plurality of directional beams and transmissions on the directional beam from another base station associated with a serving cell of the plurality of base stations, or reducing interference between PRS transmissions by a respective base station of the plurality of base stations on the plurality of directional beams and transmissions on the directional beam from another base station associated with a neighbor cell of the respective base station of the plurality of base stations, PRS transmissions by respective base stations of the plurality of base stations on the plurality of directional beams are coordinated among respective base stations of the plurality of base stations (block 2600).

Fig. 28 is a block diagram illustrating base stations 105a, 105b, 105c, 105d, 105e configured to perform operations according to one or more embodiments described herein. The base stations 105a, 105b, 105c, 105d, 105e include a processor circuit 2802, a memory circuit 2810, and a network interface 2820. The network interface 2820 includes a wireless transceiver 2830, the wireless transceiver 2830 configured to implement wireless communication protocols including, but not limited to, those supported by a 5G NR wireless communication network. The processor circuit 2802 may include one or more data processing circuits such as a general purpose processor and/or a special purpose processor (e.g., a microprocessor and/or a digital signal processor). The processor circuit 2802 is configured to execute the computer readable program code 2812 in the memory circuit 2810 to perform at least some of the operations described herein as being performed by the base stations 105a, 105b, 105c, 105d, 105 e.

Fig. 29 is a block diagram illustrating functional modules in the base stations 105a, 105b, 105c, 105d, 105e according to some embodiments of the present inventive concept. The base stations 105a, 105b, 105c, 105d, 105e include a beam configuration/PRS scheduling module 2920 configured to cooperate with the positioning node 120 to perform various multi-beam configuration operations and/or PRS scheduling operations described herein and a beam/PRS transmission module 2940 configured to perform PRS transmissions on operable beams to perform beam scanning as described herein.

Fig. 30 is a block diagram illustrating a UE110a, 110b, 110c configured to perform operations according to one or more embodiments described herein. The UE110a, 110b, 110c includes a processor circuit 3002, a memory circuit 3010, and a network interface 3020. Network interface 3020 includes a wireless transceiver 3030, wireless transceiver 3030 being configured to implement wireless communication protocols including, but not limited to, those supported by 5G NR wireless communication networks. The processor circuit 3002 may include one or more data processing circuits such as a general purpose processor and/or a special purpose processor (e.g., a microprocessor and/or a digital signal processor). The processor circuit 3002 is configured to execute the computer-readable program code 3012 in the memory circuit 3010 to perform at least some of the operations described herein as being performed by the UE110a, 110b, 110 c.

Fig. 31 is a block diagram illustrating functional modules in a UE110a, 110b, 110c according to some embodiments of the inventive concept. The UEs 110a, 110b, 110c comprise a beam configuration/PRS scheduling module 3120, the beam configuration/PRS scheduling module 3120 being configured to receive beam configuration information for the respective base stations 105a, 105b, 105c, 105d, 105e from the positioning node 120 and to use the information to detect transmissions of PRS signals from beams transmitted by different base stations 105a, 105b, 105c, 105d, 105 e. The UE110a, 110b, 110c further comprises an OTDOA measurement module 3140, the OTDOA measurement module 3140 being configured to perform OTDOA measurements (e.g., RSTD information), and to determine AoA, AoD and/or beam index information for individual PRSs received on different beams and report a portion or all of this information (including, for example, cell identification information) to the positioning node 120, as described herein.

Fig. 32 is a block diagram illustrating a positioning node 120 configured to perform operations according to one or more embodiments described herein. Positioning node 120 includes a processor circuit 3202, a memory circuit 3210, and a network interface 3220. The network interface 3220 includes a wireless transceiver 3230, the wireless transceiver 3230 configured to implement wireless communication protocols including, but not limited to, those supported by 5G NR wireless communication networks. In other implementations, the network interface 3220 may include a wired interface for communicating with, for example, the base stations 105a, 105b, 105c, 105d, 105e over one or more networks, which may include wireless networks and/or wired networks. The processor circuit 3202 may include one or more data processing circuits such as a general purpose processor and/or a special purpose processor (e.g., a microprocessor and/or a digital signal processor). The processor circuit 3202 is configured to execute the computer-readable program code 3212 in the memory circuit 3210 to perform at least some of the operations described herein as being performed by the positioning node 120.

Fig. 33 is a block diagram illustrating functional modules in positioning node 120 according to some embodiments of the present inventive concept. The positioning node 120 includes a beam configuration/PRS scheduling module 3320, the beam configuration/PRS scheduling module 3320 configured to receive beam configuration information from the base stations 105a, 105b, 105c, 105d, 105e and determine PRS scheduling information for coordinating PRS transmissions among the various base stations 105a, 105b, 105c, 105d, 105 e. The beam configuration information and/or PRS transmission scheduling information may be provided to the UEs 110a, 110b, 110 c. The positioning node 120 further comprises a position determination module 3340, which position determination module 3340 is configured to perform OTDOA position determinations for the UEs 110a, 110b, 110c based on the RSTD information and, in some embodiments, the AoA, AoD and/or beam index information for the respective PRS. New research has been approved to evaluate potential solutions that meet the NR positioning requirements specified in TR 38.913, TS 22.261, TR 22.872 and TR 22.804, while taking into account E911 requirements by analyzing positioning accuracy (including latitude, longitude and altitude), availability, reliability, latency, network synchronization requirements and/or UE/gNB complexity to perform positioning, and considering the preference to use existing positioning support for E-UTRAN to improve synergy (synergy) where possible.

A second goal of NR localization support studies includes:

potential solutions for positioning technologies are studied and evaluated based on the agreed (identified) requirements, evaluation scenarios/methods described above. This solution may include at least positioning related to NR-based Radio Access Technologies (RATs) to operate in both FR1 and FR2, without excluding other positioning technologies; and can support a minimum bandwidth target of NR with scalability (e.g., 5MHz) to enable universal extension to any application.

According to some embodiments, OTDOA techniques may be used as one of the potential solutions for positioning techniques in NRs.

OTDOA is a RAT-related positioning technology that has been widely deployed in LTE networks. In the basic operation of LTE, a User Equipment (UE) receives reference signals from multiple enbs, then performs time difference of arrival (TDOA) measurements for each eNB, and then calculates a Reference Signal Time Difference (RSTD). RSTD measurements are sent from the UE to a Location Server (LS) via the eNode-B using the LTE Positioning Protocol (LPP). The LS then performs a positioning estimation using triangulation based on measurements from at least three eNode-B facilities.

OTDOA is a mature positioning technology, and it has been widely used in LTE as one of the technologies related to key RATs.

In view of the maturity of OTDOA technology and adoption in LTE, OTDOA usage in LTE can be used as a baseline (baseline) for OTDOA in NR. In LTE, PRS is one of the reference signals used to facilitate UE positioning determination based on OTDOA methods. PRS have the following properties:

and (3) generating PRS:

PRSs may be generated based on specific sequence generation specified in TS 36.211. It is based on a gold sequence of length 31. The PRS sequence may depend on the cell ID and frame/slot timing information.

Resource element mapping:

PRS can be mapped to complex-valued QPSK modulation symbols and the mapping of PRS signals to resource elements is specified according to TS 36.211.

And (3) scheduling PRS:

PRS may be transmitted in dedicated subframes (referred to as PRS occasions) and may consist of several subframes. For example, the PRS occasion periods may be 160ms, 320ms, 640ms, and 1280 ms. The number of PRS subframes within a PRS time may be 1, 2, 4, and 6 subframes.

Many other PRS attributes may have been considered in LTE, such as PRS muting (PRS muting), network synchronization, etc. To use OTDOA techniques in NR positioning, the above-described PRS attributes in LTE may be re-examined to determine whether to perform full reuse or modify PRS attributes for potential positioning improvement.

According to some embodiments, OTDOA in LTE may be used as a baseline for OTDOA in NR. PRS design (e.g., sequences, resource element mapping, scheduling) in LTE may be reviewed for potential improvements.

Compared to LTE, NR rel.15 has many new physical layer features. NR can accommodate a wider bandwidth and can operate in various frequency ranges. In the 6GHz or less (FR1), the maximum bandwidth is 100MHz, and in the millimeter wave range (FR2), the maximum bandwidth is 400 MHz. The carrier aggregation operation may further extend the bandwidth. In FR2, operation using multiple beams (facilitated by a MIMO antenna scheme) may be used in some embodiments. Each beam may have a high gain narrow beam. For example, the existing NR rel.15 can accommodate up to 64 beams for Synchronization Signal Block (SSB) transmission. Given the many significant variations in NR, the NR features may be utilized for potential OTDOA positioning improvements, according to some embodiments.

In some embodiments, NR features (e.g., wider bandwidth, MIMO, multi-beam operation, dense network) may be utilized for potential OTDOA localization improvement.

In LTE, PRSs may be transmitted by an eNB under the assumption that the eNB has an omni/sector antenna. There is typically no indication of the beam aspect of the antenna used when transmitting the PRS. Similarly, it is desirable for the UE to receive a beam carrying PRS using an omni-directional or relatively wide antenna. As mentioned above, especially in NR FR2, the operation of a narrow beam or beams can be used to compensate for path loss in millimeter wave frequencies. As a result, PRS transmissions in LTE may not be fully exploited in NR. According to some embodiments, an appropriate scheduling mechanism may be determined to accommodate PRS transmissions on those multiple beams.

OTDOA techniques in the millimeter wave frequency range (FR2) may be studied to assess the impact on multi-beam operation.

NR positioning requirements can be developed for many use cases/scenarios. Multiple dimensions of the performance metric may be specified according to some embodiments (horizontal accuracy, vertical accuracy, availability, latency, etc.) and various levels of requirements (below 1m (sub-1m), 10m, 50m, etc.).

According to some embodiments, NR positioning may support various use cases with multiple dimensions of performance metrics (e.g., in horizontal accuracy, vertical accuracy, availability, and latency) and requirement levels (e.g., tens of meters, 1 meter or less).

It may be difficult to determine a technical solution that fits all use cases and scenarios. In OTDOA, precise positioning typically requires a wide bandwidth and many PRS subframes. Many PRS subframes may increase latency. However, some use cases may require high accuracy and short latency. In general, most use cases do not require high precision, but only a reasonable delay.

Based on the above observations, flexible operation of the positioning technique may be beneficial. This may be a flexible operation by means of combining RAT-related and RAT-independent technologies, according to some embodiments. Another consideration is the flexible operation of OTDOA positioning itself.

Flexible operation of OTDOA positioning can be considered to meet the stringent positioning requirements (e.g., accuracy and latency) of a few use cases and to meet the relaxed requirements of many use cases.

In still other implementations, the scheduling for PRS transmissions on each of a plurality of directional beams is determined as follows: such that PRS transmissions sent from a first base station are coordinated in a defined geographical area with PRS transmissions from a second base station scheduled to be sent on directional beams.

In still other embodiments, the first resource includes a first sub-frequency and a first time segment, and the second resource includes a second sub-frequency and a second time segment.

In still other embodiments, the length of the predetermined time period is based on mobility characteristics of User Equipments (UEs) within the defined geographic area (800).

In still other implementations, determining a schedule for PRS transmissions on each of a plurality of directional beams includes: a schedule for PRS transmissions on each of a plurality of directional beams is generated in order to complete PRS transmissions on each of the plurality of beams within a PRS burst interval.

In still other embodiments, individual ones of the plurality of PRS burst intervals are scheduled to occur periodically.

In still other embodiments, individual ones of the plurality of PRS burst intervals are scheduled to occur consecutively.

In still other embodiments, the method further comprises assigning beam index identifications to the plurality of directional beams, respectively. The scheduling is identified based on a beam index.

In some embodiments of the inventive concept, a method of operating a User Equipment (UE) comprises: for each of a first base station and a second base station, receiving, from a positioning node, information associated with Positioning Reference Signal (PRS) transmissions on a plurality of directional beams, the information comprising a schedule based on: coordination of PRS transmissions by the first and second base stations on a plurality of directional beams, and the plurality of directional beams having directions respectively corresponding to at least a portion of the plurality of configurable beam directions; and receiving, based on the scheduling, a first PRS signal from the first base station on a first directional beam of the plurality of directional beams and a second PRS signal from the second base station on a second directional beam of the plurality of directional beams, the scheduling being based on coordination of PRS transmissions. Is/are as follows

In some embodiments of the inventive concept, a method of operating a positioning node comprises: receiving information from each of a plurality of base stations, the information comprising a plurality of configurable beam directions suitable for Positioning Reference Signal (PRS) transmissions; for each of a plurality of base stations, transmitting to a User Equipment (UE) a schedule associated with PRS transmissions by the respective base station on a plurality of directional beams, the schedule being based on coordination of PRS transmissions by the plurality of base stations on the plurality of directional beams; and receiving reference signal time difference measurement (RSTD) information from the UE based on the first PRS signal transmitted by the first base station of the plurality of base stations, the second PRS signal transmitted by the second base station of the plurality of base stations, and the third PRS signal transmitted by the third base station of the plurality of base stations.

In still other embodiments of the inventive concept, the schedule is determined as follows: interference between PRS transmissions by respective ones of the plurality of base stations on the plurality of directional beams and transmissions by another respective one of the plurality of base stations is reduced for each of the plurality of base stations based on multiplexing first resources associated with PRS transmissions sent from the respective ones of the plurality of base stations and second resources associated with PRS transmissions sent from the another one of the plurality of base stations such that PRS transmissions by the respective ones of the plurality of base stations on the plurality of directional beams are coordinated among the respective ones of the plurality of base stations.

In some embodiments of the inventive concept, a user equipment comprises a processor and a memory coupled to the processor and including computer readable program code embodied in the memory, the computer readable program code executable by the processor to perform operations comprising: for each of a first base station and a second base station, receiving information associated with Positioning Reference Signal (PRS) transmissions on a plurality of directional beams from a positioning node, the information comprising a schedule based on: coordination of PRS transmissions by the first and second base stations on a plurality of directional beams, and the plurality of directional beams having directions respectively corresponding to at least a portion of the plurality of configurable beam directions; and receiving, based on the scheduling, a first PRS signal from a first base station on a first directional beam of the plurality of directional beams and a second PRS signal from a second base station on a second directional beam of the plurality of directional beams, the scheduling being based on coordination of PRS transmissions.

Other definitions and embodiments:

in the above description of various embodiments of the present disclosure, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this disclosure belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of this specification and the relevant art and will not be interpreted in an idealized or overly formal sense expressly so defined herein.

The flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to various aspects of the present disclosure. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems that perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

The terminology used herein is for the purpose of describing particular aspects only and is not intended to be limiting of the disclosure. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items. Like reference numerals refer to like elements throughout the description of the figures.

The corresponding structures, materials, acts, and equivalents of any means or step plus function elements in the claims below are intended to include any disclosed structure, material, or act for performing the function in combination with other claimed elements as specifically claimed. The description of the present disclosure has been presented for purposes of illustration and description, but is not intended to be exhaustive or limited to the disclosure in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the disclosure. The aspects of the disclosure were chosen and described in order to best explain the principles of the disclosure and the practical application, and to enable others of ordinary skill in the art to understand the disclosure for various modifications as are suited to the particular use contemplated.

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