JP2022533683A - NPRS measurement method, terminal and computer readable storage medium - Google Patents

Abstract

The present application discloses an NPRS measurement method, a terminal and a computer readable storage medium. The NPRS measurement method includes obtaining terminal NPRS configuration information including at least one carrier corresponding to a different cell and a carrier cycle corresponding to each carrier; grouping the at least one carrier in the information; measuring the NPRS of the carriers from the group with the shortest carrier period in the grouping result, and determining the NPRS that satisfies a predetermined error requirement based on the measured NPRS; and removing from the grouping result all carriers of cells in which corresponding carriers exist.

Description

This application claims priority from a Chinese patent application numbered 201910824812.0 filed with the Chinese Patent Office on September 02, 2019, the entire content of which is incorporated herein by reference.

TECHNICAL FIELD The present disclosure relates to the technical field of Narrowband Internet of Things (NBIoT), for example, a Narrowband Positioning Reference Signal (NPRS) measurement method, a terminal, and a computer-readable storage medium. Regarding.

NBIoT is an important technology area of the Internet of Things, with advantages such as low power consumption, wide coverage, low cost and large capacity. In some situations, such as logistics tracking, bicycle sharing, etc., it is necessary to measure the position of the terminal through the NBIoT network. Therefore, the 3rd Generation Partnership Project (3GPP) Release 14 (R14) protocol specifically defines a reference signal called NPRS that is used for positioning of NBIoT terminals.

NPRS performs positioning based on the principle of Observed Time Difference of Arrival (OTDOA). The NBIot terminal measures the value of the signal arrival time difference between a plurality of adjacent cells and one reference cell by NPRS and reports it to the base station positioning server, and the base station positioning server further reports to the base station where the plurality of cells are located. Estimate the location coordinates of this NBIot terminal based on the location of and the reported difference value. The NPRS cell that the base station configures in the terminal includes one reference cell and a neighbor cell list that can include up to 72 cells. A maximum of five carriers can be set in one NPRS cell, each carrier includes a different NPRS setting period, and the NPRS period can be 10 ms at the shortest and 1280 ms at the longest. The NPRS configuration of each cell includes the expected boundary of the cell, the terminal obtains the NPRS actual boundary based on the expected boundary of the cell by measurement, and the value of the time difference between the actual boundary and the expected boundary can be estimated and reported to the base station for positioning.

Since the number of NPRS cells that the base station sets in the terminal is usually as many as 70 or more at maximum, when setting a relatively large number of cells, it takes time to sequentially perform measurements according to the setting list, and the timing of positioning of the terminal is affected. This will increase the power consumption of your device.

The present disclosure provides an NPRS measurement method, a terminal and a computer-readable storage medium that can improve measurement efficiency and reduce measurement time and power consumption.

obtaining NPRS configuration information of the terminal, including one or more carriers corresponding to different cells and a carrier period corresponding to each carrier;
grouping the one or more carriers in NPRS configuration information based on carrier period length;
In the grouping result, measure the NPRS of the carriers from the group with the shortest carrier period, and based on the NPRS obtained by measurement, all carriers of the cell in which there is a carrier corresponding to the NPRS that satisfies the predetermined error requirement are selected from the grouping result. a step of removing;
A narrowband positioning reference signal NPRS measurement method is provided, comprising:

obtaining NPRS configuration information for the terminal, including expected subframe boundary information and one or more carriers corresponding to different cells and carrier frequency information corresponding to each carrier;
grouping the one or more carriers in the NPRS configuration information, wherein the carrier frequencies of the multiple carriers in each group are the same and between expected subframe boundaries of the cells corresponding to the multiple carriers; the difference value is less than or equal to a predetermined maximum boundary difference value threshold;
In the grouping result, measuring the NPRS of the carriers from the group with the highest number of carriers according to the number of carriers, and removing from the grouping result all carriers of the cell in which there is a carrier corresponding to the NPRS that satisfies the predetermined error requirement. ,
Further provided is an NPRS measurement method comprising:

Further provided is a computer readable storage medium storing one or more programs executable by one or more processors and implementing the above NPRS measurement method.

Further provided is a terminal including a processor and memory configured to implement the above NPRS measurement method by executing a program stored in memory.

a configuration acquisition module configured to acquire NPRS configuration information of a terminal including one or more carriers corresponding to different cells and a carrier period corresponding to each carrier;
a grouping module configured to group the one or more carriers in NPRS configuration information based on carrier period length;
In the grouping result, measure the NPRS of the carriers from the group with the shortest carrier period, and based on the NPRS obtained by measurement, all carriers of the cell in which there is a carrier corresponding to the NPRS that satisfies the predetermined error requirement are selected from the grouping result. a measurement module configured to remove;
Further provided is a terminal comprising:

a configuration acquisition module configured to acquire NPRS configuration information of a terminal including expected subframe boundary information and one or more carriers corresponding to different cells and carrier frequency information corresponding to each carrier;
The one or more carriers in the NPRS configuration information are grouped, the carrier frequencies of the multiple carriers in each group are the same, and the value of the difference between the expected subframe boundaries of the cells corresponding to the multiple carriers is , a grouping module configured to be less than or equal to a predetermined maximum boundary difference value threshold;
In the grouping result, based on the number of carriers, measure the NPRS of the carriers from the group with the largest number of carriers, and based on the NPRS obtained by measurement, all cells in which there are carriers corresponding to NPRS that satisfy the predetermined error requirement a measurement module configured to remove carriers from grouping results;
Further provided is a terminal comprising:

4 is a schematic flow chart of an NPRS measurement method according to an embodiment of the present invention; FIG. 4 is a schematic diagram of expected subframe boundaries of a multi-cell according to an embodiment of the present invention; Fig. 3 shows the distribution of NPRS for different cell identifiers (IDs) on the same resource block (RB) according to an embodiment of the invention; 4 is a schematic flowchart of another NPRS measurement method according to an embodiment of the present invention; 1 is a structural schematic diagram of a terminal according to an embodiment of the present invention; FIG. Fig. 4 is a structural schematic diagram of another terminal according to an embodiment of the present invention; 4 is a schematic diagram of an NPRS measurement process involving four cells, according to an embodiment of the invention; FIG.

Embodiments of the present invention will now be described with reference to the accompanying drawings.
The steps illustrated in the flowcharts of the accompanying drawings can be executed within a computer system as a set of computer-executable instructions. Also, although the flowcharts present a logical order, in some cases the steps shown or described may be performed in a different order.

As shown in FIG. 1, an embodiment of the present invention provides an NPRS measurement method including the following steps:
Step 101: Obtain NPRS configuration information of the terminal, including one or more carriers corresponding to different cells and carrier period information corresponding to each carrier.

In one exemplary embodiment, the NPRS configuration information further includes expected subframe boundary information of cells and carrier frequency information corresponding to each carrier.

Step 102: Group the carriers in the NPRS configuration information according to carrier period information.

In one exemplary embodiment, grouping the carriers in NPRS configuration information based on the carrier period information includes the following steps:
Based on one or more predetermined carrier period thresholds, the carriers in the NPRS configuration information are divided into two or more groups according to the length of the carrier period.

In one exemplary embodiment, after grouping the carriers in the NPRS configuration information based on the carrier period information, the method further comprises: dividing the groups of carriers resulting from the grouping into each secondary grouping, wherein the carrier frequencies of the carriers in each secondary group are the same, and the expected subframe boundaries of the cells corresponding to the carriers are close.

As shown in FIG. 2, the expected subframe boundaries of cells 0, 1 and 2 are the same, and the expected subframe boundary of cell 3 is different than the expected subframe boundaries of several other cells.

In one exemplary embodiment, the proximity of the expected subframe boundaries of the cells corresponding to the carrier means that the difference value between the expected subframe boundaries of the cells corresponding to the carrier exceeds a predetermined maximum boundary difference value threshold. including:

Step 103: Measure the NPRS of the carriers from the short carrier period group according to the carrier period length, and based on the measured NPRS, all the carriers of the cell corresponding to the carriers with NPRS that satisfy the predetermined error requirement. from the group.

In one exemplary embodiment, measuring the NPRS of the carriers from the short carrier period group based on the carrier period length is: according to the first principle of measuring the short carrier period group first, determining the measurement order of the groups, and in each group, measuring the NPRS of the carriers from the secondary group with high carrier count according to the second principle of measuring the secondary group with high carrier count first. include.

In embodiments of the present invention, the short carrier period group can measure enough NPRS samples in a relatively short period of time, and the long carrier period group takes a relatively long time to measure enough NPRS samples. Since time is required, the priority of the group with the short carrier cycle is high, and the priority of the group with the long carrier cycle is low. By sequentially measuring the NPRS of a plurality of groups of carriers in the order of measuring a group with a short carrier period first and then measuring a group with a long carrier period, the measurement efficiency is improved, the measurement time is shortened, and the power consumption is reduced. to reduce

In the same carrier period group, based on the expected subframe boundary and carrier frequency set by the base station, NPRS carriers with close expected subframe boundaries and the same carrier frequency are grouped into one group, and the grouping is completed. Afterwards, the groups are ordered based on the number of carriers included in each group, and the groups with a relatively large number of carriers are preferentially measured.

In one exemplary embodiment, when measuring the NPRS of carriers in the secondary group, the method further includes the steps of:
If the NPRS of two or more carriers in the secondary group are distributed in the same subframe, and the positions of the corresponding resource elements (REs) are different, the NPRS of the two or more carriers in the same subframe at the same time.

When the terminal performs boundary adjustment, the adjustment process takes a relatively long time. Therefore, by measuring the carriers near the expected subframe boundary into a group, the time consumed in the boundary switching process of the terminal is reduced. be able to. It takes time to switch the radio frequency carrier (carrier switching during NPRS reception affects the final measurement result, so it is necessary to reserve time for carrier switching), and the physical layer RB of NPRS Due to the property (a schematic diagram of the distribution of NPRS for different cell IDs on the same RB is shown in FIG. 3), the NPRS for co-frequency, co-edge cells with unequal cell ID mod 6 results are received and measured in the same subframe. can do. For example, there are two carriers in the secondary group, each of the two carriers needs to fully measure N NPRS data, the two carriers have different NPRS subframe distributions, and some subframes have two Since some subframes contain NPRS for one carrier and some subframes contain no NPRS for one carrier, if during the measurement we are in a subframe containing NPRS for two carriers , the NPRS of two carriers can be measured simultaneously in that subframe, in which case the NPRS data of two carriers can be obtained simultaneously in one subframe, further saving the total measurement time. As described above, by dividing carriers having the same carrier frequency into one group, it is possible to reduce the overall measurement time. By preferentially measuring secondary groups containing a relatively large number of carriers, the terminal can measure a relatively large number of cells in a relatively short amount of time, saving the overall measurement time.

In this application, the carriers in the same secondary group only need to be close to the expected subframe boundaries, and if the scenes are close to the expected subframe boundaries but have different subframe numbers or radio frame numbers, when generating the NPRS local sequence It can be distinguished and processed by a method that adopts an actual subframe number or a radio frame number.

There can be up to 5 carriers in one cell, the subframe boundaries of these 5 carriers are the same, and the NPRS result measured on one of them meets the predefined error requirement. , it indicates that the boundary difference for that cell has already been measured, no other carriers need to be measured anymore, and all carriers corresponding to that cell should be removed from the group waiting for measurement.

As shown in FIG. 4, an embodiment of the present invention further provides an NPRS measurement method including the following steps:
Step 401: Obtain NPRS configuration information of the terminal, including expected subframe boundary information and one or more carriers corresponding to different cells and carrier frequency information corresponding to each carrier.

Step 402: Group the carriers in the NPRS configuration information, wherein the carrier frequencies of the carriers in each group are the same, and the expected subframe boundaries of the cells corresponding to the carriers are close.

In one exemplary embodiment, the proximity of the expected subframe boundaries of the cells corresponding to the carrier means that the difference value between the expected subframe boundaries of the cells corresponding to the carrier exceeds a predetermined maximum boundary difference value threshold. including:

Step 403: Measure the NPRS of the carriers from the group with the higher number of carriers according to the number of carriers, and remove from the group all carriers of the cell corresponding to the carriers with NPRS that satisfy the predetermined error requirement.

In an embodiment of the present application, based on the expected subframe boundaries and carrier frequencies set by the base station, NPRS carriers with close expected subframe boundaries and the same carrier frequency are grouped into one group, and after the grouping is completed, , based on the number of carriers included in each group, and preferentially measure groups with a relatively large number of carriers.

In one exemplary embodiment, when measuring the NPRS of the carrier, the method further includes the steps of:
If the NPRS of two or more carriers in this group are distributed in the same subframe and the positions of the corresponding resource elements are different, then the NPRS of the two or more carriers are measured simultaneously in the same subframe.

When the terminal performs boundary adjustment, the adjustment process takes a relatively long time. Therefore, by measuring the carriers near the expected subframe boundary into a group, the time consumed in the boundary switching process of the terminal is reduced. be able to. It takes time to switch the radio frequency carrier (carrier switching during NPRS reception affects the final measurement result, so it is necessary to reserve time for carrier switching), and the physical layer RB of NPRS Due to the property, co-frequency, co-edge cell NPRS with unequal cell ID mod 6 results can be received and measured in the same subframe. For example, there are two carriers in one group, each of the two carriers needs to fully measure N NPRS data, the two carriers have different NPRS subframe distributions, and some subframes have two Since some subframes contain NPRS for one carrier and some subframes contain no NPRS for one carrier, if during the measurement we are in a subframe containing NPRS for two carriers , the NPRS of two carriers can be measured simultaneously in that subframe, in which case the NPRS data of two carriers can be obtained simultaneously in one subframe, further saving the total measurement time. As described above, by dividing carriers having the same carrier frequency into one group, it is possible to reduce the overall measurement time. By preferentially measuring groups including a relatively large number of carriers, the terminal can measure a relatively large number of cells in a relatively short amount of time, thereby saving the entire measurement time.

The same group of carriers in the present application only needs to be close to the expected subframe boundaries. It can be distinguished and processed by a method employing a frame number or a radio frame number.

There can be up to 5 carriers in one cell, the subframe boundaries of these 5 carriers are the same, and the NPRS result measured on one of them meets the predefined error requirement. , it indicates that the boundary difference for that cell has already been measured, no other carriers need to be measured anymore, and all carriers corresponding to that cell should be removed from the group waiting for measurement.

Embodiments of the present application further provide a computer-readable storage medium on which the computer-readable storage medium can be executed by one or more processors to implement the NPRS measurement method according to any one of the embodiments. One or more programs are stored.

Embodiments of the present application further provide a terminal comprising a processor and a memory, wherein the processor is configured to implement the NPRS measurement method according to any one of the embodiments by executing a program stored in the memory. be done.

The embodiment of the present application further provides a terminal including a first configuration acquisition module 501, a first grouping module 502 and a first measurement module 503, as shown in FIG.

The first configuration acquisition module 501 is configured to acquire terminal NPRS configuration information including one or more carriers corresponding to different cells and carrier period information corresponding to each carrier, The grouping module 502 is configured to group the carriers in the NPRS configuration information based on the carrier period information, and the first measurement module 503 determines the short carrier period based on the carrier period length. It is configured to measure the NPRS of the carriers from the group and, based on the measured NPRS obtained, remove from the group all carriers of the cell corresponding to carriers whose NPRS satisfy a predetermined error requirement.

In one exemplary embodiment, the first grouping module 502 grouping carriers in NPRS configuration information based on carrier period information includes the following steps:
Based on one or more predetermined carrier period thresholds, the carriers in the NPRS configuration information are divided into two or more groups according to the length of the carrier period.

In one exemplary embodiment, the NPRS configuration information further includes expected subframe boundary information of a cell and carrier frequency information corresponding to each carrier;
The first grouping module 502 is further configured to divide each of the groups of carriers obtained from the grouping into secondary groups, wherein the carriers in each secondary group have the same carrier frequency; and The expected subframe boundary of the cell corresponding to said carrier is close.

As shown in FIG. 2, the expected subframe boundaries of cells 0, 1 and 2 are the same, and the expected subframe boundary of cell 3 is different than the expected subframe boundaries of several other cells.

In one exemplary embodiment, proximity of expected subframe boundaries of cells corresponding to multiple carriers in each secondary group means that expected subframe boundaries of cells corresponding to multiple carriers in each secondary group are close to each other. is less than or equal to a predefined maximum boundary difference value threshold.

In embodiments of the present invention, the short carrier period group can measure enough NPRS samples in a relatively short period of time, and the long carrier period group takes a relatively long time to measure enough NPRS samples. Since time is required, the priority of the group with the short carrier cycle is high, and the priority of the group with the long carrier cycle is low. By sequentially measuring the NPRS of a plurality of groups of carriers in the order of measuring a group with a short carrier period first and then measuring a group with a long carrier period, the measurement efficiency is improved, the measurement time is shortened, and the power consumption is reduced. to reduce

In one embodiment, the first measurement module 503 measures the NPRS of carriers from short carrier period groups based on the carrier period lengths by: measuring the short carrier period groups first. determining the measurement order of the groups according to a first principle; measuring the NPRS of the carriers from the secondary group with the higher number of carriers according to the second principle of measuring the secondary group with the higher number of carriers first in each group. and

In the same carrier period group, based on the expected subframe boundary and carrier frequency set by the base station, NPRS carriers with close expected subframe boundaries and the same carrier frequency are grouped into one group, and the grouping is completed. Afterwards, the groups are ordered based on the number of carriers included in each group, and the groups with a relatively large number of carriers are preferentially measured.

In one exemplary embodiment, when measuring the NPRS of carriers in the secondary group by the first measurement module 503, the NPRS of two or more carriers in the secondary group are in the same subframe. The NPRS of the two or more carriers are measured simultaneously in the same subframe if they are distributed and the positions of the corresponding resource elements are different.

When the terminal performs boundary adjustment, the adjustment process takes a relatively long time. Therefore, by measuring the carriers near the expected subframe boundary into a group, the time consumed in the boundary switching process of the terminal is reduced. be able to. It takes time to switch the radio frequency carrier (carrier switching during NPRS reception affects the final measurement result, so it is necessary to reserve time for carrier switching), and the physical layer RB of NPRS Due to the property (a schematic diagram of the distribution of NPRS for different cell IDs on the same RB is shown in FIG. 3), the NPRS for co-frequency, co-edge cells with unequal cell ID mod 6 results are received and measured in the same subframe. can do. For example, there are two carriers in the secondary group, each of the two carriers needs to fully measure N NPRS data, the two carriers have different NPRS subframe distributions, and some subframes have two Since some subframes contain NPRS for one carrier and some subframes contain no NPRS for one carrier, if during the measurement we are in a subframe containing NPRS for two carriers , the NPRS of two carriers can be measured simultaneously in that subframe, in which case the NPRS data of two carriers can be obtained simultaneously in one subframe, further saving the total measurement time. As described above, by dividing carriers having the same carrier frequency into one group, it is possible to reduce the overall measurement time. By preferentially measuring secondary groups containing a relatively large number of carriers, the terminal can measure a relatively large number of cells in a relatively short amount of time, saving the overall measurement time.

Carriers in the same secondary group in the present application should be close to the expected subframe boundaries, and if the scenes are close to the expected subframe boundaries but have different subframe numbers or radio frame numbers, the actual can be distinguished and processed by adopting a subframe number or a radio frame number.

There can be up to 5 carriers in one cell, the subframe boundaries of these 5 carriers are the same, and the NPRS result measured on one of them meets the predefined error requirement. , it indicates that the boundary difference for that cell has already been measured, no other carriers need to be measured anymore, and all carriers corresponding to that cell should be removed from the group waiting for measurement.

The embodiment of the present application further provides a terminal including a second setting acquisition module 601, a second grouping module 602 and a second measurement module 603, as shown in FIG.

The second configuration obtaining module 601 is configured to obtain terminal NPRS configuration information including expected subframe boundary information and one or more carriers corresponding to different cells and carrier frequency information corresponding to each carrier. and the second grouping module 602 is configured to group the carriers in the NPRS configuration information, wherein the carriers in each group have the same carrier frequency and the expected subframe of the cell corresponding to the carriers Near the boundary, the second measurement module 603 measures the NPRS of carriers from a group with a large number of carriers according to the number of carriers, and based on the measured NPRS, the carriers of the NPRS that meet a predetermined error requirement. are configured to remove from the group all carriers of the cell corresponding to .

In one exemplary embodiment, the proximity of expected subframe boundaries of cells corresponding to carriers in each group means that the difference value between expected subframe boundaries of cells corresponding to carriers in each group is: Include being less than or equal to the default maximum boundary difference value threshold.

In an embodiment of the present application, based on the expected subframe boundaries and carrier frequencies set by the base station, NPRS carriers with close expected subframe boundaries and the same carrier frequency are grouped into one group, and after the grouping is completed, , based on the number of carriers included in each group, and preferentially measure groups with a relatively large number of carriers.

In one exemplary embodiment, when measuring the NPRS of the carriers by the second measurement module 603, the NPRS of two or more carriers in the group are distributed in the same subframe, and the corresponding resources are If the element positions are different, the NPRS of the two or more carriers are measured simultaneously in the same subframe.

When the terminal performs boundary adjustment, the adjustment process takes a relatively long time. Therefore, by measuring the carriers near the expected subframe boundary into a group, the time consumed in the boundary switching process of the terminal is reduced. be able to. It takes time to switch the radio frequency carrier (carrier switching during NPRS reception affects the final measurement result, so it is necessary to reserve time for carrier switching), and the physical layer RB of NPRS Due to the property, co-frequency, co-edge cell NPRS with unequal cell ID mod 6 results can be received and measured in the same subframe. For example, there are two carriers in one group, each of the two carriers needs to fully measure N NPRS data, the two carriers have different NPRS subframe distributions, and some subframes have two Since some subframes contain NPRS for one carrier and some subframes contain no NPRS for one carrier, if during the measurement we are in a subframe containing NPRS for two carriers , the NPRS of two carriers can be measured simultaneously in that subframe, in which case the NPRS data of two carriers can be obtained simultaneously in one subframe, further saving the total measurement time. As described above, by dividing carriers having the same carrier frequency into one group, it is possible to reduce the overall measurement time. By preferentially measuring groups including a relatively large number of carriers, the terminal can measure a relatively large number of cells in a relatively short amount of time, thereby saving the entire measurement time.

The same group of carriers in the present application only needs to be close to the expected subframe boundaries. It can be distinguished and processed by a method employing a frame number or a radio frame number.

There can be up to 5 carriers in one cell, the subframe boundaries of these 5 carriers are the same, and the NPRS result measured on one of them meets the predefined error requirement. , it indicates that the boundary difference for that cell has already been measured, no other carriers need to be measured anymore, and all carriers corresponding to that cell should be removed from the group waiting for measurement.

In one exemplary embodiment, the NPRS measurement proposal according to the embodiments of the present application is based on multi-level grouping planning, and the measurement planning process includes the following steps.

(1) First, the carriers are grouped according to the length of the carrier cycle into a short cycle group and a long cycle group. The short period group has a high priority because it can measure enough NPRS samples in a relatively short time, and the long period group takes a relatively long time to measure enough NPRS samples and has a high priority. is low.

(2) In the same periodic group, according to the expected subframe boundaries and carrier frequencies set by the base station, NPRS carriers with close expected subframe boundaries and the same carrier frequency should be grouped; grouping; is completed, it is necessary to perform further ordering based on the number of carriers included in each group, and preferentially measure groups with a relatively large number of carriers.

For the expected subframe boundary, when the terminal performs boundary adjustment, the adjustment process usually takes a relatively long time. time consumption can be reduced. In determining the expected subframe, it is sufficient if the expected subframe boundary is close. If the expected subframe boundary is close but the scene has a different subframe number or radio frame number, the actual subframe is determined when the NPRS local sequence is generated. It can be distinguished and processed by a method that employs a number or a radio frame number.

Regarding frequency, on the one hand, it takes time to switch radio frequency carriers (since carrier switching during NPRS reception affects the final measurement results, it is necessary to reserve time for carrier switching), and on the other hand, Then, due to the RB characteristics of NPRS, NPRS of the same frequency and same boundary cells with unequal cell ID mod 6 results can be received and measured in the same subframe, so carriers with the same carrier frequency are grouped into one group. By dividing, the total measurement time can be reduced.

There can be up to 5 carriers in one cell, the boundaries of these 5 carriers are the same, and the NPRS result measured on one of them can meet the predefined error requirement. , indicates that the boundary difference for that cell has already been measured, no other carriers need to be measured any more, and all carriers corresponding to that cell should be removed from the group.

By preferentially measuring a carrier group that includes a relatively large number of carriers and has the same carrier frequency as a near expected subframe boundary, the terminal can measure a relatively large number of cells in a relatively short amount of time. measurement time can be saved.

The present application uniformly considers the NPRS carrier period, the expected subframe boundary and the carrier frequency, can measure the NPRS of a relatively large number of cells in a relatively short period of time, and greatly enhances the efficiency of NPRS measurement under multi-cells. , thereby achieving the objectives of improving measured aging and reducing power consumption.

As shown in FIG. 7, the following four cells are taken as an example.
Cell 0 includes three carriers whose frequencies are carrier0, carrier1 and carrier2 respectively and whose periods are 10ms, 40ms and 320ms respectively.

Cell 1 includes two carriers whose frequencies are carrier1 and carrier2, respectively, and whose periods are 10 ms and 640 ms, respectively.

Cell 2 includes two carriers whose frequencies are carrier0 and carrier2, respectively, and whose periods are 10 ms and 640 ms, respectively.

Cell 3 includes two carriers whose frequencies are carrier1 and carrier2, respectively, and whose periods are 40 ms and 640 ms, respectively.

For simplicity, assume that all four cells have the same expected subframe boundaries.

The measuring step includes the following steps.
(1) Divide 10 ms and 40 ms NPRS-configured carriers into short-period groups, and divide longer-cycle NPRS-configured carriers into long-period groups.

(2) The carriers in the short period group and the long period group are grouped by boundary-frequency, respectively, as follows.

First group short cycle group: Cell0-carrier0, Cell2-carrier0.

Second group short cycle group: Cell0-carrier1, Cell1-carrier1, Cell3-carrier1.

First group long cycle group: Cell0-carrier2, Cell1-carrier2, Cell2-carrier2, Cell3-carrier2.

(3) Boundary between short period group and long period group—Frequency groups are sorted by the number of carriers as follows.

First group short cycle group: Cell0-carrier1, Cell1-carrier1, Cell3-carrier1.

Second group short cycle group: Cell0-carrier0, Cell2-carrier0.

First group long cycle group: Cell0-carrier2, Cell1-carrier2, Cell2-carrier2, Cell3-carrier2.

(4) Measure the NPRS of the short period group of the first group.
(5) After removing the relevant cell for which NPRS measurement has been completed in (4) from the group, steps (1), (2), and (3) are re-executed.

In this example, only Cell2 is not measured after removing the relevant cell for which NPRS measurement has been performed in (4).

Short cycle group of the first group: Cell2-carrier0.
Long cycle group of the first group: Cell2-carrier2.

The short period group is tested preferentially, and when the test is completed, the entire NPRS measurement process ends.

Claims (11)

A narrowband positioning reference signal NPRS measurement method, comprising:
obtaining NPRS configuration information of the terminal including at least one carrier corresponding to a different cell and a carrier period corresponding to each carrier;
grouping the at least one carrier in the NPRS configuration information based on carrier period length;
In the grouping result, the NPRS of the carriers are measured from the group with the shortest carrier period, and based on the measured NPRS, all carriers in the cell in which the carrier corresponding to the NPRS that satisfies the predetermined error requirement exists are selected as the grouping result. and removing from. grouping the at least one carrier in the NPRS configuration information based on the carrier period length;
2. The method of claim 1, comprising dividing the at least one carrier in the NPRS configuration information into multiple groups according to a carrier period length based on a predetermined at least one carrier period threshold. The NPRS configuration information further includes expected subframe boundary information for each cell and carrier frequency information corresponding to each carrier,
After grouping the at least one carrier in the NPRS configuration information based on the carrier period length, further comprising:
sub-grouping the carriers in each obtained group, wherein the carriers in each sub-group have the same carrier frequency and between the expected subframe boundaries of the cells corresponding to said carriers. 2. The method of claim 1, wherein the difference value is less than or equal to a predetermined maximum boundary difference value threshold. In the grouping results, the step of measuring the NPRS of the carriers from the group with the shortest carrier period is
Determining the measurement order for the grouping results according to the first principle of measuring the group with the shortest carrier period first; and in each group, according to the second principle of measuring the secondary group with the largest number of carriers first. , measuring the NPRS of carriers from the secondary group with the highest number of carriers. When measuring the NPRS of carriers in the secondary group, the method further comprises:
If the NPRS of multiple carriers are distributed in the same subframe in the secondary group and the positions of the resource elements corresponding to the multiple carriers are different, simultaneously measuring the NPRS of the multiple carriers in the same subframe. 5. The method of claim 4. A narrowband positioning reference signal NPRS measurement method, comprising:
obtaining NPRS configuration information for the terminal, including expected subframe boundary information and at least one carrier corresponding to different cells and carrier frequency information corresponding to each carrier;
grouping the at least one carrier in the NPRS configuration information, wherein the carrier frequencies of the multiple carriers in each group are the same and between expected subframe boundaries of the cells corresponding to the multiple carriers; the difference value is less than or equal to a predetermined maximum boundary difference value threshold;
In the grouping result, measuring the NPRS of the carriers from the group with the highest number of carriers according to the number of carriers, and removing from the grouping result all carriers of cells in which there are carriers corresponding to NPRS that satisfy a predetermined error requirement. When,
method including. A computer-readable storage medium storing at least one program executed by at least one processor and capable of implementing the narrowband positioning reference signal NPRS measurement method according to any one of claims 1 to 6. A terminal including a processor and a memory, wherein the processor implements the narrowband positioning reference signal NPRS measurement method according to any one of claims 1 to 6 by executing a program stored in the memory. A terminal that is configured to A terminal including a setting acquisition module, a grouping module, and a measurement module,
The configuration obtaining module is configured to obtain terminal narrowband positioning reference signal NPRS configuration information including at least one carrier corresponding to a different cell and a carrier period corresponding to each carrier;
the grouping module is configured to group the at least one carrier in the NPRS configuration information based on carrier period length;
The measurement module measures the NPRS of the carriers from the group with the shortest carrier period in the grouping result, and based on the measured NPRS, all the carriers of the cell in which there is a carrier corresponding to the NPRS that satisfies the predetermined error requirement. from the grouping results. The NPRS configuration information further includes expected subframe boundary information for each cell and carrier frequency information corresponding to each carrier,
The grouping module further divides the carriers in each obtained group into secondary groups, wherein the carriers in each secondary group have the same carrier frequency and the expected subgroups of cells corresponding to the carriers. 10. The terminal of claim 9, wherein the difference value between frame boundaries is configured to be less than or equal to a predefined maximum boundary difference value threshold. A terminal including a setting acquisition module, a grouping module, and a measurement module,
The configuration obtaining module is configured to obtain terminal narrowband positioning reference signal NPRS configuration information including expected subframe boundary information corresponding to different cells and at least one carrier and carrier frequency information corresponding to each carrier. is,
The grouping module is configured to group the at least one carrier in the NPRS configuration information, wherein the carrier frequencies of the multiple carriers in each group are the same, and the cell corresponding to the multiple carriers. the difference value between the expected subframe boundaries is less than or equal to the default maximum boundary difference value threshold, and
The measurement module measures the NPRS of the carrier from the group with the largest number of carriers in the grouping result based on the number of carriers, and based on the measured NPRS, the carrier corresponding to the NPRS that satisfies the predetermined error requirement is selected. A terminal configured to remove all carriers of existing cells from the grouping result.

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