WO2019113750A1 - 一种配置用户设备测量参数的方法、用户设备及网络设备 - Google Patents

一种配置用户设备测量参数的方法、用户设备及网络设备 Download PDF

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Publication number
WO2019113750A1
WO2019113750A1 PCT/CN2017/115492 CN2017115492W WO2019113750A1 WO 2019113750 A1 WO2019113750 A1 WO 2019113750A1 CN 2017115492 W CN2017115492 W CN 2017115492W WO 2019113750 A1 WO2019113750 A1 WO 2019113750A1
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WIPO (PCT)
Prior art keywords
filter coefficient
target
information
user equipment
measurement
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PCT/CN2017/115492
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English (en)
French (fr)
Inventor
杨宁
Original Assignee
Oppo广东移动通信有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Oppo广东移动通信有限公司 filed Critical Oppo广东移动通信有限公司
Priority to PCT/CN2017/115492 priority Critical patent/WO2019113750A1/zh
Priority to AU2017443100A priority patent/AU2017443100A1/en
Priority to CN202010388440.4A priority patent/CN111669780A/zh
Priority to JP2020549845A priority patent/JP7062784B2/ja
Priority to CN201780095523.0A priority patent/CN111165007A/zh
Priority to KR1020207019693A priority patent/KR20200093656A/ko
Priority to EP22163595.6A priority patent/EP4037370A1/en
Priority to EP17934564.0A priority patent/EP3726875A1/en
Publication of WO2019113750A1 publication Critical patent/WO2019113750A1/zh
Priority to US16/886,375 priority patent/US11395165B2/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/10Scheduling measurement reports ; Arrangements for measurement reports
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B17/00Monitoring; Testing
    • H04B17/30Monitoring; Testing of propagation channels
    • H04B17/309Measuring or estimating channel quality parameters
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L43/00Arrangements for monitoring or testing data switching networks
    • H04L43/50Testing arrangements
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/08Testing, supervising or monitoring using real traffic

Definitions

  • the present invention relates to the field of information processing technologies, and in particular, to a method for configuring user equipment measurement parameters, a user equipment (UE), a network device, and a computer storage medium.
  • UE user equipment
  • the MN and SN independently configure the measurement configuration for the UE.
  • the measurement of each UE in LTE is only configured according to the measurement amount being RSRP or RSRQ to configure two different filter coefficients.
  • the signal attenuation is different at different frequencies. For example, the frequency of the NR is higher, and the signal quality of the cell fluctuates greatly. Therefore, the influence of the new measurement signal on the final measurement result should be considered in the filter coefficient configuration.
  • an embodiment of the present invention provides a method for configuring user equipment measurement parameters, a user equipment (UE), a network device, and a computer storage medium.
  • UE user equipment
  • a method for configuring a measurement parameter of a user equipment, which is applied to a user equipment includes:
  • the target filter coefficient to be used for the measurement is determined.
  • a method for configuring a measurement parameter of a user equipment, which is applied to a network device includes:
  • the first communication unit acquires at least one filter coefficient information configured on the network side;
  • the first processing unit determines, based on the correlation information of the measurement object and the at least one filter coefficient information, a target filter coefficient to be used for performing the measurement.
  • the second communication unit configures at least one filter coefficient information to the user equipment, where the at least one filter coefficient includes at least the default filter coefficient information.
  • a user equipment UE provided by an embodiment of the present invention includes: a processor and a memory for storing a computer program capable of running on the processor,
  • processor is configured to perform the steps of the foregoing method when the computer program is run.
  • a network device provided by an embodiment of the present invention includes: a processor and a memory for storing a computer program capable of running on a processor,
  • processor is configured to perform the steps of the foregoing method when the computer program is run.
  • a computer storage medium is provided by the embodiment of the present invention.
  • the computer storage medium stores computer executable instructions, and the foregoing method steps are implemented when the computer executable instructions are executed.
  • the technical solution of the embodiment of the present invention enables the user equipment to obtain multiple filter coefficient information configured by the network side.
  • the user equipment may determine the target filter coefficient based on the measurement object and based on the plurality of filter coefficient information when the user equipment needs to perform measurement.
  • the signaling load of the filter coefficient configuration can be reduced when the user equipment needs to perform measurements.
  • FIG. 1 is a schematic flowchart of a method for configuring measurement parameters of a user equipment according to an embodiment of the present invention. intention;
  • FIG. 2 is a schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • FIG. 3 is a schematic structural diagram of a network device according to an embodiment of the present invention.
  • FIG. 4 is a schematic diagram of a hardware architecture according to an embodiment of the present invention.
  • An embodiment of the present invention provides a method for configuring a measurement parameter of a user equipment, which is applied to a user equipment (UE), as shown in FIG.
  • UE user equipment
  • Step 101 Acquire at least one filter coefficient information configured on the network side.
  • Step 102 Determine, according to the related information of the measurement object and the at least one filter coefficient information, a target filter coefficient to be used for performing measurement.
  • a plurality of filter coefficient information can be configured through the network side, and then the target filter coefficients to be used are selected from the plurality of filter coefficient information.
  • the at least one filter coefficient includes at least default filter coefficient information.
  • the method also includes obtaining at least one first reference filter coefficient configured on the network side.
  • each of the first reference filter coefficients can be set with multiple dimensions included in the embodiment, for example, a first reference filter coefficient is set for each dimension.
  • the dimension of the frequency may be divided into a low frequency, an intermediate frequency, a high frequency, and an ultra high frequency.
  • the first reference filter coefficients are set in all four dimensions; and the different first reference filter coefficients may be different.
  • the plurality of filter coefficient information is divided into frequency points according to the frequency, for example, a low frequency.
  • Dimensional division of multiple levels such as intermediate frequency, high frequency and ultra high frequency.
  • different filter coefficients are respectively configured in the three levels of intermediate frequency and high frequency. That is to say, different filter coefficients correspond to different frequency dimensions, and multiple filter coefficients can be set according to different frequency points in each frequency dimension.
  • the acquiring at least one filter coefficient information configured by the network side includes:
  • the filter coefficient information further includes: an offset value of the filter coefficient relative to the first reference filter coefficient. That is to say, in each of the at least one filter coefficient information of each dimension, each filter coefficient information may include an offset value and corresponding to which first reference filter coefficient. Of course, instead of indicating a specific reference filter coefficient, a default reference filter coefficient corresponding to each dimension is used to correspond to the offset value.
  • ⁇ cell beam>, ⁇ RSRP, RSRQ, SINR>, ⁇ CSI-SR, SSB>, ⁇ low frequency, intermediate frequency, high frequency and ultra high frequency four, etc., respectively, corresponding filter coefficient information is configured, the filtering
  • the coefficient information is an offset value of the filter coefficient to be configured with respect to the reference filter coefficient.
  • the foregoing offset value may default to the processing method of the first reference filter coefficient, and may include the following:
  • the offset value may be added to the first reference filter coefficient by default, and may of course be subtracted from the first reference filter coefficient by default; of course, there may be other calculation modes, which are not exhaustive. That is to say, the indexes of the filter coefficients to be configured in the enumeration are all larger than the index of the reference filter coefficients or all indexes smaller than the filter coefficients.
  • the second type of the filter coefficient information further includes: indication information that the filter coefficient is greater than or smaller than the reference filter coefficient.
  • This processing method is different from the first processing method in that in the filter coefficient information, in addition to indicating the offset value, the offset value and the The calculation method between a reference filter coefficient may be added or indicated as subtraction, and is defined in detail in specific filter coefficient information.
  • the user equipment After receiving the filter coefficient information, that is, the configuration parameters on the network side, the user equipment (UE) determines the filter coefficient according to the reference filter coefficient and the filter coefficient offset.
  • the determining, according to the related information of the measurement object, and the at least one filter coefficient information, determining a target filter coefficient to be used for performing the measurement including:
  • the measured cell is a cell or a beam
  • whether the measurement quantity is RSRP, RSRQ, or SINR
  • whether the measured signal is a CSI-RS or an SSB and a frequency band of the measured frequency point, to determine a target filter coefficient used in the current measurement.
  • a default configuration parameter is given for each combination, when the target filter coefficient is the default filter coefficient, the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the display configuration is Index information of the target filter coefficient.
  • the filter coefficient to be configured and the default configuration filter coefficient are the same, the configuration filter coefficient is not displayed, and the filter coefficient is configured by default.
  • the foregoing solution in this example is a scheme in which the UE side performs the configuration of the target filter coefficient based on the configured at least one filter coefficient information.
  • the default filter coefficient is used as the target filter coefficient. That is to say, the relevant information of the measurement object can be understood as the configuration information sent by the network side.
  • the acquiring at least one filter coefficient information configured by the network side includes:
  • the network side configures a list (List) of one or more filter coefficients for the user equipment.
  • a default filter coefficient value in the filter coefficient list is given.
  • a target filter coefficient to be used for performing the measurement including:
  • the target filter coefficient to be used for the measurement is selected from the at least one filter coefficient.
  • a filter coefficient list and a certain filter coefficient in the filter coefficient list are associated by the measurement id, and are associated by an index. If the filter coefficient to be associated is equal to the default filter coefficient value, the configuration is omitted, otherwise the configured filter coefficient index is displayed.
  • the correlation information based on the measurement object and the at least one filter coefficient information are used to determine a target filter coefficient to be used for measurement, and may also be configured to receive configuration information sent by the network side.
  • the target filter coefficient is indicated in the configuration information
  • the target filter coefficient is determined based on the configuration information; when the target filter coefficient is not indicated in the configuration information, a default filter coefficient is used as the target filter coefficient. That is to say, the relevant information of the measurement object can be understood as the configuration information sent by the network side. That is, the present example also provides a scenario in which the target filter coefficient is determined based on the indication on the network side. If the network side does not indicate it, it can be processed with the default value.
  • the acquiring at least one filter coefficient information configured by the network side includes:
  • a target filter coefficient to be used for performing the measurement including:
  • the target filter coefficients to be used for the measurement are calculated.
  • the target filter coefficients to be used for the measurement are calculated, including:
  • the second reference filter coefficient is multiplied by the target factor to obtain a target filter coefficient to be used for the measurement
  • the second reference filter coefficient is added to the target offset to obtain a target filter coefficient to be used for the measurement.
  • the filter coefficient reference filter coefficient * the factor corresponding to all items
  • the filter coefficient reference filter coefficient + offset corresponding to all items
  • the target filter coefficient is the default filter coefficient
  • the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the index of the configured target filter coefficient is displayed. information.
  • the user equipment can obtain multiple filter coefficient information configured by the network side, so that the user equipment can determine the target filter coefficient based on the multiple filter coefficient information when the user equipment needs to be measured, and thus can be in the user equipment. Reduce the signaling load of the filter coefficient configuration when measurements are needed.
  • An embodiment of the present invention provides a method for configuring a measurement parameter of a user equipment, where the network device includes: configuring at least one filter coefficient information to the user equipment; where the at least one filter coefficient includes at least a default filter coefficient information. .
  • a plurality of filter coefficient information can be configured through the network side, and then the target filter coefficients to be used are selected from the plurality of filter coefficient information.
  • the at least one filter coefficient includes at least default filter coefficient information.
  • the method also includes configuring at least one first reference filter coefficient for the user equipment.
  • each of the first reference filter coefficients can be set with multiple dimensions included in the embodiment, for example, a first reference filter coefficient is set for each dimension.
  • the dimension of the frequency may be divided into a low frequency, an intermediate frequency, a high frequency, and an ultra high frequency.
  • the first reference filter coefficients are set in all four dimensions; and the different first reference filter coefficients may be different.
  • a plurality of filter coefficient information are divided into frequency divisions according to frequencies, for example, low frequency, intermediate frequency, high frequency, and ultra high frequency. And different filter coefficients are respectively configured in the three levels of intermediate frequency and high frequency. That is to say, different filter coefficients correspond to different frequency dimensions, and multiple filter coefficients can be set according to different frequency points in each frequency dimension.
  • the at least one filter coefficient information is configured to the user equipment, including:
  • the filter coefficient information further includes: an offset value of the filter coefficient relative to the reference filter coefficient.
  • each filter coefficient information may include an offset value and corresponding to which first reference filter coefficient.
  • a default reference filter coefficient corresponding to each dimension is used to correspond to the offset value.
  • ⁇ cell beam>, ⁇ RSRP, RSRQ, SINR>, ⁇ CSI-SR, SSB>, ⁇ low frequency, intermediate frequency, high frequency and ultra high frequency four, etc., respectively, corresponding filter coefficient information is configured, the filtering
  • the coefficient information is an offset value of the filter coefficient to be configured with respect to the reference filter coefficient.
  • the foregoing offset value may default to the processing method of the first reference filter coefficient, and may include the following:
  • the offset value may be added to the first reference filter coefficient by default, and may of course be subtracted from the first reference filter coefficient by default; of course, there may be other calculation modes, which are not exhaustive. That is to say, the indexes of the filter coefficients to be configured in the enumeration are all larger than the index of the reference filter coefficients or all indexes smaller than the filter coefficients.
  • the second type of the filter coefficient information further includes: indication information that the filter coefficient is greater than or smaller than the reference filter coefficient.
  • the difference between the processing mode and the first processing mode is that, in the filter coefficient information, in addition to indicating the offset value, the calculation manner between the offset value and the first reference filter coefficient may be indicated, which may be The addition can also be indicated as subtraction, which is defined in detail in the specific filter coefficient information.
  • the user equipment After receiving the filter coefficient information, that is, the configuration parameters on the network side, the user equipment (UE) determines the filter coefficient according to the reference filter coefficient and the filter coefficient offset.
  • a default configuration parameter is given for each combination, when the target filter coefficient is the default filter coefficient, the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the display configuration is Index information of the target filter coefficient.
  • the filter coefficient to be configured and the default configuration filter coefficient are the same, the configuration filter coefficient is not displayed, and the filter coefficient is configured by default.
  • the at least one filter coefficient information is configured to the user equipment, including:
  • At least one filter coefficient is configured to the user equipment. That is, the network side configures a list (List) of one or more filter coefficients for the user equipment.
  • a default filter coefficient value in the filter coefficient list is given.
  • a target filter coefficient to be used for performing the measurement including:
  • the target filter coefficient to be used for the measurement is selected from the at least one filter coefficient.
  • a filter coefficient list and a certain filter coefficient in the filter coefficient list are associated by the measurement id, and are associated by an index. If the filter coefficient to be associated is equal to the default filter coefficient value, the configuration is omitted, otherwise the configured filter coefficient index is displayed.
  • the method further includes:
  • a second reference filter coefficient is configured to the user equipment. That is, a reference filter coefficient of the configuration.
  • the at least one filter coefficient information is configured to the user equipment, including:
  • the user equipment is configured with at least one factor or offset value corresponding to each dimension in at least one dimension.
  • a target filter coefficient to be used for performing the measurement including:
  • the target filter coefficients to be used for the measurement are calculated.
  • the target filter coefficients to be used for the measurement are calculated, including:
  • the second reference filter coefficient is multiplied by the target factor to obtain a target filter coefficient to be used for the measurement
  • the second reference filter coefficient is added to the target offset to obtain a target filter coefficient to be used for the measurement.
  • the filter coefficient reference filter coefficient * the factor corresponding to all items
  • the filter coefficient reference filter coefficient + offset corresponding to all items
  • the target filter coefficient is the default filter coefficient
  • the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the index information of the configured target filter coefficient is displayed.
  • the user equipment can obtain multiple filter coefficient information configured by the network side, so that the user equipment can determine the target filter coefficient based on the multiple filter coefficient information when the user equipment needs to be measured, and thus can be in the user equipment. Reduce the signaling load of the filter coefficient configuration when measurements are needed.
  • An embodiment of the present invention provides a user equipment (UE), as shown in FIG. 2, including:
  • the first communication unit 21 acquires at least one filter coefficient information configured on the network side;
  • the first processing unit 22 determines, based on the correlation information of the measurement object and the at least one filter coefficient information, a target filter coefficient to be used for performing the measurement.
  • a plurality of filter coefficient information can be configured through the network side, and then the target filter coefficients to be used are selected from the plurality of filter coefficient information.
  • the at least one filter coefficient includes at least default filter coefficient information.
  • the first communication unit 21 acquires at least one first reference filter coefficient configured on the network side.
  • each of the first reference filter coefficients can be set with multiple dimensions included in the embodiment, for example, a first reference filter coefficient is set for each dimension.
  • the dimension of the frequency may be divided into a low frequency, an intermediate frequency, a high frequency, and an ultra high frequency.
  • the first reference filter coefficients are set in all four dimensions; and the different first reference filter coefficients may be different.
  • a plurality of filter coefficient information are divided into frequency divisions according to frequencies, for example, low frequency, intermediate frequency, high frequency, and ultra high frequency. And different filter coefficients are respectively configured in the three levels of intermediate frequency and high frequency. That is to say, different filter coefficients correspond to different frequency dimensions, and multiple filter coefficients can be set according to different frequency points in each frequency dimension.
  • the first communication unit 21 acquires, for each of the at least one dimension, each of the network side configurations Filter coefficient information corresponding to each dimension;
  • the filter coefficient information further includes: an offset value of the filter coefficient relative to the first reference filter coefficient. That is to say, in each of the at least one filter coefficient information of each dimension, each filter coefficient information may include an offset value and corresponding to which first reference filter coefficient. Of course, instead of indicating a specific reference filter coefficient, a default reference filter coefficient corresponding to each dimension is used to correspond to the offset value.
  • ⁇ cell beam>, ⁇ RSRP, RSRQ, SINR>, ⁇ CSI-SR, SSB>, ⁇ low frequency, intermediate frequency, high frequency and ultra high frequency four, etc., respectively, corresponding filter coefficient information is configured, the filtering
  • the coefficient information is an offset value of the filter coefficient to be configured with respect to the reference filter coefficient.
  • the foregoing offset value may default to the processing method of the first reference filter coefficient, and may include the following:
  • the offset value may be added to the first reference filter coefficient by default, and may of course be subtracted from the first reference filter coefficient by default; of course, there may be other calculation modes, which are not exhaustive. That is to say, the indexes of the filter coefficients to be configured in the enumeration are all larger than the index of the reference filter coefficients or all indexes smaller than the filter coefficients.
  • the second type of the filter coefficient information further includes: indication information that the filter coefficient is greater than or smaller than the reference filter coefficient.
  • the difference between the processing mode and the first processing mode is that, in the filter coefficient information, in addition to indicating the offset value, the calculation manner between the offset value and the first reference filter coefficient may be indicated, which may be The addition can also be indicated as subtraction, which is defined in detail in the specific filter coefficient information.
  • the user equipment After receiving the filter coefficient information, that is, the configuration parameters on the network side, the user equipment (UE) determines the filter coefficient according to the reference filter coefficient and the filter coefficient offset.
  • the first processing unit 22 selects, according to the dimension corresponding to the measurement object, the type of the signal to be measured, and the frequency band, from the at least one filter coefficient information. Obtaining target filter coefficient information;
  • the measured cell is a cell or a beam
  • whether the measurement quantity is RSRP, RSRQ, or SINR
  • whether the measured signal is a CSI-RS or an SSB and a frequency band of the measured frequency point, to determine a target filter coefficient used in the current measurement.
  • a default configuration parameter is given for each combination, when the target filter coefficient is the default filter coefficient, the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the display configuration is Index information of the target filter coefficient.
  • the filter coefficient to be configured and the default configuration filter coefficient are the same, the configuration filter coefficient is not displayed, and the filter coefficient is configured by default.
  • the foregoing solution in this example is a scheme in which the UE side performs the configuration of the target filter coefficient based on the configured at least one filter coefficient information.
  • the default filter coefficient is used as the target filter coefficient. That is to say, the relevant information of the measurement object can be understood as the configuration information sent by the network side.
  • the first communication unit 21 acquires at least one filter coefficient configured on the network side.
  • the network side configures a list (List) of one or more filter coefficients for the user equipment.
  • a default filter coefficient value in the filter coefficient list is given.
  • the first processing unit 22 selects, from the at least one filter coefficient, a target filter coefficient to be used for measurement based on the identification information of the measurement object.
  • a filter coefficient list and a certain filter coefficient in the filter coefficient list are associated by the measurement id, and are associated by an index. If the filter coefficient to be associated is equal to the default filter coefficient value, the configuration is omitted, otherwise the configured filter coefficient index is displayed.
  • the correlation information based on the measurement object and the at least one filter coefficient information are used to determine a target filter coefficient to be used for measurement, and may also be configured to receive configuration information sent by the network side.
  • the target filter coefficient is indicated in the configuration information
  • the target filter coefficient is determined based on the configuration information; when the target filter coefficient is not indicated in the configuration information, a default filter coefficient is used as the target filter coefficient. That is to say, the relevant information of the measurement object can be understood as the configuration information sent by the network side. That is, the present example also provides a scenario in which the target filter coefficient is determined based on the indication on the network side. If the network side does not indicate it, it can be processed with the default value.
  • the first communication unit acquires at least one factor or offset value corresponding to each dimension in at least one dimension configured by the network side.
  • the first processing unit selects a target factor or a target offset based on the dimension information corresponding to the measurement object;
  • the target filter coefficients to be used for the measurement are calculated.
  • the first processing unit adopts a second reference filtering system when selecting a target factor Multiplying the number by the target factor to obtain a target filter coefficient to be used for the measurement;
  • the second reference filter coefficient is added to the target offset to obtain a target filter coefficient to be used for the measurement.
  • the filter coefficient reference filter coefficient * the factor corresponding to all items
  • the filter coefficient reference filter coefficient + offset corresponding to all items
  • the target filter coefficient is the default filter coefficient
  • the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the index information of the configured target filter coefficient is displayed.
  • the user equipment can obtain multiple filter coefficient information configured by the network side, so that the user equipment can determine the target filter coefficient based on the multiple filter coefficient information when the user equipment needs to be measured, and thus can be in the user equipment. Reduce the signaling load of the filter coefficient configuration when measurements are needed.
  • An embodiment of the present invention provides a network device, as shown in FIG. 3, including:
  • the second communication unit 31 configures at least one filter coefficient information to the user equipment, where the at least one filter coefficient includes at least the default filter coefficient information.
  • a plurality of filter coefficient information can be configured through the network side, and then the target filter coefficients to be used are selected from the plurality of filter coefficient information.
  • the at least one filter coefficient includes at least default filter coefficient information.
  • the second communication unit 31 configures at least one first reference filter coefficient for the user equipment.
  • each of the first reference filter coefficients can be set with multiple dimensions included in the embodiment, for example, a first reference filter coefficient is set for each dimension.
  • the dimension of the frequency may be divided into a low frequency, an intermediate frequency, a high frequency, and an ultra high frequency.
  • the first reference filter coefficients are set in all four dimensions; and the different first reference filter coefficients may be different.
  • a plurality of filter coefficient information are divided into frequency divisions according to frequencies, for example, low frequency, intermediate frequency, high frequency, and ultra high frequency. And different filter coefficients are respectively configured in the three levels of intermediate frequency and high frequency. That is to say, different filter coefficients correspond to different frequency dimensions, and multiple filter coefficients can be set according to different frequency points in each frequency dimension.
  • the network device further includes:
  • the second processing unit 32 determines filter coefficient information corresponding to each of the at least one dimension
  • the second communication unit 31 configures, to the user equipment, filter coefficient information corresponding to each of the at least one dimension
  • the filter coefficient information further includes: an offset value of the filter coefficient relative to the reference filter coefficient.
  • each filter coefficient information may include an offset value and corresponding to which first reference filter coefficient.
  • a default reference filter coefficient corresponding to each dimension is used to correspond to the offset value.
  • ⁇ cell beam>, ⁇ RSRP, RSRQ, SINR>, ⁇ CSI-SR, SSB>, ⁇ low frequency, intermediate frequency, high frequency and ultra high frequency four, etc., respectively, corresponding filter coefficient information is configured, the filtering
  • the coefficient information is an offset value of the filter coefficient to be configured with respect to the reference filter coefficient.
  • the foregoing offset value may default to the processing method of the first reference filter coefficient, and may include the following:
  • the offset value may be added to the first reference filter coefficient by default, and may of course be subtracted from the first reference filter coefficient by default; of course, there may be other calculation modes, which are not exhaustive. That is to say, the indexes of the filter coefficients to be configured in the enumeration are all larger than the index of the reference filter coefficients or all indexes smaller than the filter coefficients.
  • the second type of the filter coefficient information further includes: indication information that the filter coefficient is greater than or smaller than the reference filter coefficient.
  • the difference between the processing mode and the first processing mode is that, in the filter coefficient information, in addition to indicating the offset value, the calculation manner between the offset value and the first reference filter coefficient may be indicated, which may be The addition can also be indicated as subtraction, which is defined in detail in the specific filter coefficient information.
  • the user equipment After receiving the filter coefficient information, that is, the configuration parameters on the network side, the user equipment (UE) determines the filter coefficient according to the reference filter coefficient and the filter coefficient offset.
  • a default configuration parameter is given for each combination, when the target filter coefficient is the default filter coefficient, the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the display configuration is Index information of the target filter coefficient.
  • the filter coefficient to be configured and the default configuration filter coefficient are the same, the configuration filter coefficient is not displayed, and the filter coefficient is configured by default.
  • the second communication unit 31 configures at least one filter coefficient to the user equipment. That is, the network side configures a list (List) of one or more filter coefficients for the user equipment.
  • a default filter coefficient value in the filter coefficient list is given.
  • a target filter coefficient to be used for performing the measurement including:
  • a filter coefficient list and a certain filter coefficient in the filter coefficient list are associated by the measurement id, and are associated by an index. If the filter coefficient to be associated is equal to the default filter coefficient value, the configuration is omitted, otherwise the configured filter coefficient index is displayed.
  • the second communication unit 31 configures a second reference filter coefficient to the user equipment. That is, a reference filter coefficient of the configuration.
  • the second communication unit 31 configures, to the user equipment, at least one factor or offset value corresponding to each dimension in at least one dimension.
  • a target filter coefficient to be used for performing the measurement including:
  • the target filter coefficients to be used for the measurement are calculated.
  • the target filter coefficients to be used for the measurement are calculated, including:
  • the second reference filter coefficient is multiplied by the target factor to obtain a target filter coefficient to be used for the measurement
  • the second reference filter coefficient is added to the target offset to obtain a target filter coefficient to be used for the measurement.
  • the filter coefficient reference filter coefficient * the factor corresponding to all items
  • the filter coefficient reference filter coefficient + offset corresponding to all items
  • the target filter coefficient is the default filter coefficient
  • the target filter coefficient is not displayed; when the target filter coefficient is not the default filter coefficient, the index information of the configured target filter coefficient is displayed.
  • the user equipment can obtain multiple filter coefficient information configured by the network side, so that the user equipment can determine the target filter coefficient based on the multiple filter coefficient information when the user equipment needs to be measured, and thus can be in the user equipment. Reduce the signaling load of the filter coefficient configuration when measurements are needed.
  • the embodiment of the present invention further provides a hardware component architecture of the user equipment or the receiver device.
  • the method includes at least one processor 41, a memory 42, and at least one network interface 43.
  • the various components are coupled together by a bus system 44.
  • bus system 44 is used to implement connection communication between these components.
  • the bus system 44 includes, in addition to the data bus, a power bus, a control bus, and a status signal bus.
  • various buses are labeled as bus system 44 in FIG.
  • the memory 42 in the embodiments of the present invention may be a volatile memory or a non-volatile memory, or may include both volatile and non-volatile memory.
  • memory 42 stores elements, executable modules or data structures, or a subset thereof, or their extension set:
  • the processor 41 is configured to be able to process the method steps of the first embodiment or the second embodiment, and details are not described herein.
  • a computer storage medium is provided by the embodiment of the present invention.
  • the computer storage medium stores computer executable instructions. When the computer executable instructions are executed, the method steps of the first embodiment or the second embodiment are implemented.
  • Embodiments of the Invention may be stored in a computer readable storage medium if it is implemented in the form of a software function module and sold or used as a standalone product. Based on such understanding, the technical solution of the embodiments of the present invention may be embodied in the form of a software product in essence or in the form of a software product stored in a storage medium, including a plurality of instructions.
  • a computer device (which may be a personal computer, server, or network device, etc.) is caused to perform all or part of the methods described in various embodiments of the present invention.
  • the foregoing storage medium includes various media that can store program codes, such as a USB flash drive, a mobile hard disk, a read only memory (ROM), a magnetic disk, or an optical disk.
  • embodiments of the invention are not limited to any specific combination of hardware and software.
  • an embodiment of the present invention further provides a computer storage medium, wherein a computer program is configured, and the computer program is configured to execute a data scheduling method according to an embodiment of the present invention.

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Abstract

本发明公开了一种配置用户设备测量参数的方法、用户设备、网络设备及计算机存储介质,包括:获取网络侧配置的至少一个滤波系数信息;基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数。

Description

一种配置用户设备测量参数的方法、用户设备及网络设备 技术领域
本发明涉及信息处理技术领域,尤其涉及一种配置用户设备测量参数的方法、用户设备(UE)、网络设备及计算机存储介质。
背景技术
LTE和NR之间tight interworking的工作模式中,MN和SN独立给UE配置测量配置。对于测量滤波系数,LTE中的每个UE的测量中只是根据测量量是RSRP或者RSRQ来配置不同的两个滤波系数。
在5G中,由于NR的频谱范围比较广泛,不同的频率上信号衰减是不一样的。例如NR中的频点较高,小区的信号质量波动较大,所以滤波系数配置中应该多考虑新测量信号对最后测量结果的影响。并且,测量滤波系数考虑的因素比较多,例如每个测量对象都考虑不同的滤波系数,所以对于滤波系数的测量配置带来的信令也是比较大的,所以需要设计合理配置方式降低滤波系数配置带来的信令负荷。
发明内容
为解决上述技术问题,本发明实施例提供了一种配置用户设备测量参数的方法、用户设备(UE)、网络设备及计算机存储介质。
本发明实施例提供的一种配置用户设备测量参数的方法,应用于用户设备,包括:
获取网络侧配置的至少一个滤波系数信息;
基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数。
本发明实施例提供的一种配置用户设备测量参数的方法,应用于网络设备,包括:
向用户设备配置至少一个滤波系数信息;其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
本发明实施例提供的一种用户设备,包括:
第一通信单元,获取网络侧配置的至少一个滤波系数信息;
第一处理单元,基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数。
本发明实施例提供的一种网络设备,包括:
第二通信单元,向用户设备配置至少一个滤波系数信息;其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
本发明实施例提供的一种用户设备UE,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
其中,所述处理器用于运行所述计算机程序时,执行前述方法的步骤。
本发明实施例提供的一种网络设备,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
其中,所述处理器用于运行所述计算机程序时,执行前述方法的步骤。
本发明实施例提供的一种计算机存储介质,所述计算机存储介质存储有计算机可执行指令,所述计算机可执行指令被执行时实现前述方法步骤。
本发明实施例的技术方案,就能够使得用户设备获取网络侧配置的多个滤波系数信息,如此,用户设备可以在用户设备需要测量时,基于测量对象以及基于多个滤波系数信息确定目标滤波系数,进而能够在用户设备需要进行测量的时候减少滤波系数配置的信令负荷。
附图说明
图1为本发明实施例提供的一种配置用户设备测量参数的方法流程示 意图;
图2为本发明实施例用户设备组成结构示意图;
图3为本发明实施例网络设备组成结构示意图;
图4为本发明实施例的一种硬件架构示意图。
具体实施方式
为了能够更加详尽地了解本发明实施例的特点与技术内容,下面结合附图对本发明实施例的实现进行详细阐述,所附附图仅供参考说明之用,并非用来限定本发明实施例。
实施例一、
本发明实施例提供了一种配置用户设备测量参数的方法,应用于用户设备(UE),如图1所示,包括:
步骤101:获取网络侧配置的至少一个滤波系数信息;
步骤102:基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数。
也就是说,本发明实施例能够通过网络侧配置多个滤波系数信息,进而从多个滤波系数信息中选取得到所要采用的目标滤波系数。
下面分别采用多种示例对本实施例提供的方案进行具体说明:
示例1、
所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
所述方法还包括:获取网络侧配置的至少一个第一参考滤波系数。可以理解的是,每一个第一参考滤波系数,可以与本实施例中包含的多个维度进行设置,比如,每一个维度设置一个第一参考滤波系数。本实施例中可以将频率的维度划分为低频、中频、高频、超高频,相应的,四个维度均设置第一参考滤波系数;并且,不同的第一参考滤波系数可以不同。
本实施例中将多个滤波系数信息按照频率,将频点分为,例如低频, 中频、高频和超高频等多个等级进行维度划分。并且分别在中频、高频三个等级分别配置使用不同的滤波系数。也就是说不同的滤波系数对应不同的频率维度,并且每一个频率维度中可以根据不同的频点设置多个滤波系数。
所述获取网络侧配置的至少一个滤波系数信息,包括:
获取网络侧配置的针对至少一个维度中,每一个维度所对应的滤波系数信息;
其中,所述滤波系数信息中还包括有:滤波系数相对于第一参考滤波系数的偏置值。也就是说,在每一个维度的至少一个滤波系数信息中,每一个滤波系数信息中可以包括有一个偏置值、以及与哪个第一参考滤波系数相对应。当然,也可以不指示具体的参考滤波系数,而是默认的采用每一个维度所对应的一个第一参考滤波系数与偏置值进行对应。
可以理解的是,本示例中提供的维度划分方式,还可以包括有:
按照<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>,<低频,中频、高频和超高频四>等几个维度分别配置对应的滤波系数信息,该滤波系数信息是要配置的滤波系数相对于参考滤波系数的偏置值。
前述偏置值可以默认为与第一参考滤波系数的处理方式,可以包括以下几种:
第一种、偏置值可以默认为与第一参考滤波系数相加,当然还可以默认为与第一参考滤波系数相减;当然还可以有其他计算方式,这里不进行穷举。也就是说,所需要配置的滤波系数在枚举中的索引要么全都大于参考滤波系数的索引或者全都小于滤波系数的索引。
第二种、所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。这种处理方式与第一种处理方式不同之处在于,在滤波系数信息中,除了指示偏置值之外,还可以指示该偏置值与第 一参考滤波系数之间的计算方式,可以为相加也可以指示为相减,均在具体的滤波系数信息中进行详细限定。
用户设备(UE)收到滤波系数信息,也就是网络侧的配置参数后,根据参考滤波系数和滤波系数偏置确定滤波系数。
具体的,所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
基于所述测量对象所对应的维度,以及所要测量的信号的类型以及频段,从所述至少一个滤波系数信息中选取得到目标滤波系数信息;
基于所述目标滤波系数信息中包含的偏置值、以及第一参考滤波系数,计算得到进行测量所要采用的目标滤波系数。
也就是说,UE根据测量的是cell还是beam,测量量是RSRP,还是RSRQ,还是SINR,测量的信号是CSI-RS还是SSB以及测量的频点所在频段,来确定当前测量使用的目标滤波系数。
由于本示例中,针对每个组合给出一个默认的配置参数,当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
即如果想要配置的滤波系数和默认配置滤波系数相同,则采用不显示配置滤波系数,采用默认配置滤波系数。
进一步地,本示例前述方案为UE侧自行基于配置的至少一个滤波系数信息进行目标滤波系数的配置的方案;当然,还可以存在另一种方式,当未获取网络侧配置的滤波系数信息时,采用默认滤波系数作为所述目标滤波系数。也就是说,测量对象的相关信息可以理解为网络侧发来的配置信息。
示例2、
所述获取网络侧配置的至少一个滤波系数信息,包括:
获取网络侧配置的至少一个滤波系数。
即网络侧为用户设备配置一个或者多个滤波系数的列表(List)。
可选的,给出该滤波系数list中默认的滤波系数值。
所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
基于测量对象的标识信息,从所述至少一个滤波系数中选取得到进行测量所要采用的目标滤波系数。
也就是说,针对每个测量配置通过测量id关联一个滤波系数list以及该滤波系数list中某个滤波系数,通过索引进行关联。如果要关联的滤波系数等于默认的滤波系数值,则省略不配置,否则显示配置滤波系数索引。
与示例一相同的是,所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,还可以为,接收网络侧发来的配置信息,当所述配置信息中指示目标滤波系数时,基于所述配置信息确定目标滤波系数;当所述配置信息中未指示目标滤波系数时,采用默认滤波系数作为所述目标滤波系数。也就是说,测量对象的相关信息可以理解为网络侧发来的配置信息。即本示例同样提供一种场景就是基于网络侧的指示确定目标滤波系数。若网络侧未指示,可以采用默认值进行处理。
示例3、
获取网络侧配置的第二参考滤波系数。也就是接收网络侧配置的一个参考滤波系数。
所述获取网络侧配置的至少一个滤波系数信息,包括:
获取网络侧配置的在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
比如,可以为以下至少之一:
针对<cell,beam>的维度,分别配置两个因子或者偏置;
针对<RSRP,RSRQ,SINR>的维度,分别配置三个因子或者偏置;
针对<CSI-SR,SSB>的维度,分别配置两个因子或者偏置。
针对频点,例如<低频,中频、高频和超高频四>,分别配置n个因子或者偏置。n取决于对于频率的分配,例如上述例子n=4,如果频率分为<低频,中频、高频>则n=3,如果频率分为<低频,高频>则n=2.
所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
基于测量对象所对应的维度信息,选取得到目标因子或目标偏置;
基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数。
其中,所述基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数,包括:
当选取目标因子时,采用第二参考滤波系数与所述目标因子相乘,得到进行测量所要采用的目标滤波系数;
当选取目标偏置时,采用第二参考滤波系数与所述目标偏置相加,得到进行测量所要采用的目标滤波系数。
根据测量配置要求的<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>以及测量对象的频点信息,得出不同的频率因子或者偏置,计算出滤波系数。
如果是因子:则滤波系数=参考滤波系数*所有项对应的因子;
如果是偏置:则滤波系数=参考滤波系数+所有项对应的偏置;
前述多个示例均可以包括以下处理步骤:
当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引 信息。
可见,通过采用上述方案,就能够使得用户设备获取网络侧配置的多个滤波系数信息,如此,用户设备可以在用户设备需要测量时基于多个滤波系数信息确定目标滤波系数,进而能够在用户设备需要进行测量的时候减少滤波系数配置的信令负荷。
实施例二、
本发明实施例提供了一种配置用户设备测量参数的方法,应用于网络设备,包括:向用户设备配置至少一个滤波系数信息;其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
也就是说,本发明实施例能够通过网络侧配置多个滤波系数信息,进而从多个滤波系数信息中选取得到所要采用的目标滤波系数。
下面分别采用多种示例对本实施例提供的方案进行具体说明:
示例1、
所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
所述方法还包括:为用户设备配置至少一个第一参考滤波系数。可以理解的是,每一个第一参考滤波系数,可以与本实施例中包含的多个维度进行设置,比如,每一个维度设置一个第一参考滤波系数。本实施例中可以将频率的维度划分为低频、中频、高频、超高频,相应的,四个维度均设置第一参考滤波系数;并且,不同的第一参考滤波系数可以不同。
本实施例中将多个滤波系数信息按照频率,将频点分为,例如低频,中频、高频和超高频等多个等级进行维度划分。并且分别在中频、高频三个等级分别配置使用不同的滤波系数。也就是说不同的滤波系数对应不同的频率维度,并且每一个频率维度中可以根据不同的频点设置多个滤波系数。
所述向用户设备配置至少一个滤波系数信息,包括:
向用户设备配置针对至少一个维度中,每一个维度所对应的滤波系数信息;
其中,所述滤波系数信息中还包括有:滤波系数相对于参考滤波系数的偏置值。
也就是说,在每一个维度的至少一个滤波系数信息中,每一个滤波系数信息中可以包括有一个偏置值、以及与哪个第一参考滤波系数相对应。当然,也可以不指示具体的参考滤波系数,而是默认的采用每一个维度所对应的一个第一参考滤波系数与偏置值进行对应。
可以理解的是,本示例中提供的维度划分方式,还可以包括有:
按照<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>,<低频,中频、高频和超高频四>等几个维度分别配置对应的滤波系数信息,该滤波系数信息是要配置的滤波系数相对于参考滤波系数的偏置值。
前述偏置值可以默认为与第一参考滤波系数的处理方式,可以包括以下几种:
第一种、偏置值可以默认为与第一参考滤波系数相加,当然还可以默认为与第一参考滤波系数相减;当然还可以有其他计算方式,这里不进行穷举。也就是说,所需要配置的滤波系数在枚举中的索引要么全都大于参考滤波系数的索引或者全都小于滤波系数的索引。
第二种、所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。这种处理方式与第一种处理方式不同之处在于,在滤波系数信息中,除了指示偏置值之外,还可以指示该偏置值与第一参考滤波系数之间的计算方式,可以为相加也可以指示为相减,均在具体的滤波系数信息中进行详细限定。
用户设备(UE)收到滤波系数信息,也就是网络侧的配置参数后,根据参考滤波系数和滤波系数偏置确定滤波系数。
由于本示例中,针对每个组合给出一个默认的配置参数,当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
即如果想要配置的滤波系数和默认配置滤波系数相同,则不显示配置滤波系数,采用默认配置滤波系数。
示例2、
所述向用户设备配置至少一个滤波系数信息,包括:
向用户设备配置至少一个滤波系数。即网络侧为用户设备配置一个或者多个滤波系数的列表(List)。
可选的,给出该滤波系数list中默认的滤波系数值。
所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
基于测量对象的标识信息,从所述至少一个滤波系数中选取得到进行测量所要采用的目标滤波系数。
也就是说,针对每个测量配置通过测量id关联一个滤波系数list以及该滤波系数list中某个滤波系数,通过索引进行关联。如果要关联的滤波系数等于默认的滤波系数值,则省略不配置,否则显示配置滤波系数索引。
示例3、
所述方法还包括:
向用户设备配置第二参考滤波系数。也就是配置的一个参考滤波系数。
所述向用户设备配置至少一个滤波系数信息,包括:
向用户设备配置在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
比如,可以为以下至少之一:
针对<cell,beam>的维度,分别配置两个因子或者偏置;
针对<RSRP,RSRQ,SINR>的维度,分别配置三个因子或者偏置;
针对<CSI-SR,SSB>的维度,分别配置两个因子或者偏置。
针对频点,例如<低频,中频、高频和超高频四>,分别配置n个因子或者偏置。n取决于对于频率的分配,例如上述例子n=4,如果频率分为<低频,中频、高频>则n=3,如果频率分为<低频,高频>则n=2.
所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
基于测量对象所对应的维度信息,选取得到目标因子或目标偏置;
基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数。
其中,所述基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数,包括:
当选取目标因子时,采用第二参考滤波系数与所述目标因子相乘,得到进行测量所要采用的目标滤波系数;
当选取目标偏置时,采用第二参考滤波系数与所述目标偏置相加,得到进行测量所要采用的目标滤波系数。
根据测量配置要求的<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>以及测量对象的频点信息,得出不同的频率因子或者偏置,计算出滤波系数。
如果是因子:则滤波系数=参考滤波系数*所有项对应的因子;
如果是偏置:则滤波系数=参考滤波系数+所有项对应的偏置;
前述多个示例均可以包括以下处理步骤:
当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
可见,通过采用上述方案,就能够使得用户设备获取网络侧配置的多个滤波系数信息,如此,用户设备可以在用户设备需要测量时基于多个滤波系数信息确定目标滤波系数,进而能够在用户设备需要进行测量的时候减少滤波系数配置的信令负荷。
实施例三、
本发明实施例提供了一种用户设备(UE),如图2所示,包括:
第一通信单元21,获取网络侧配置的至少一个滤波系数信息;
第一处理单元22,基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数。
也就是说,本发明实施例能够通过网络侧配置多个滤波系数信息,进而从多个滤波系数信息中选取得到所要采用的目标滤波系数。
下面分别采用多种示例对本实施例提供的方案进行具体说明:
示例1、
所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
所述第一通信单元21,获取网络侧配置的至少一个第一参考滤波系数。可以理解的是,每一个第一参考滤波系数,可以与本实施例中包含的多个维度进行设置,比如,每一个维度设置一个第一参考滤波系数。本实施例中可以将频率的维度划分为低频、中频、高频、超高频,相应的,四个维度均设置第一参考滤波系数;并且,不同的第一参考滤波系数可以不同。
本实施例中将多个滤波系数信息按照频率,将频点分为,例如低频,中频、高频和超高频等多个等级进行维度划分。并且分别在中频、高频三个等级分别配置使用不同的滤波系数。也就是说不同的滤波系数对应不同的频率维度,并且每一个频率维度中可以根据不同的频点设置多个滤波系数。
所述第一通信单元21,获取网络侧配置的针对至少一个维度中,每一 个维度所对应的滤波系数信息;
其中,所述滤波系数信息中还包括有:滤波系数相对于第一参考滤波系数的偏置值。也就是说,在每一个维度的至少一个滤波系数信息中,每一个滤波系数信息中可以包括有一个偏置值、以及与哪个第一参考滤波系数相对应。当然,也可以不指示具体的参考滤波系数,而是默认的采用每一个维度所对应的一个第一参考滤波系数与偏置值进行对应。
可以理解的是,本示例中提供的维度划分方式,还可以包括有:
按照<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>,<低频,中频、高频和超高频四>等几个维度分别配置对应的滤波系数信息,该滤波系数信息是要配置的滤波系数相对于参考滤波系数的偏置值。
前述偏置值可以默认为与第一参考滤波系数的处理方式,可以包括以下几种:
第一种、偏置值可以默认为与第一参考滤波系数相加,当然还可以默认为与第一参考滤波系数相减;当然还可以有其他计算方式,这里不进行穷举。也就是说,所需要配置的滤波系数在枚举中的索引要么全都大于参考滤波系数的索引或者全都小于滤波系数的索引。
第二种、所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。这种处理方式与第一种处理方式不同之处在于,在滤波系数信息中,除了指示偏置值之外,还可以指示该偏置值与第一参考滤波系数之间的计算方式,可以为相加也可以指示为相减,均在具体的滤波系数信息中进行详细限定。
用户设备(UE)收到滤波系数信息,也就是网络侧的配置参数后,根据参考滤波系数和滤波系数偏置确定滤波系数。
具体的,所述第一处理单元22,基于所述测量对象所对应的维度,以及所要测量的信号的类型以及频段,从所述至少一个滤波系数信息中选取 得到目标滤波系数信息;
基于所述目标滤波系数信息中包含的偏置值、以及第一参考滤波系数,计算得到进行测量所要采用的目标滤波系数。
也就是说,UE根据测量的是cell还是beam,测量量是RSRP,还是RSRQ,还是SINR,测量的信号是CSI-RS还是SSB以及测量的频点所在频段,来确定当前测量使用的目标滤波系数。
由于本示例中,针对每个组合给出一个默认的配置参数,当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
即如果想要配置的滤波系数和默认配置滤波系数相同,则采用不显示配置滤波系数,采用默认配置滤波系数。
进一步地,本示例前述方案为UE侧自行基于配置的至少一个滤波系数信息进行目标滤波系数的配置的方案;当然,还可以存在另一种方式,当未获取网络侧配置的滤波系数信息时,采用默认滤波系数作为所述目标滤波系数。也就是说,测量对象的相关信息可以理解为网络侧发来的配置信息。
示例2、
所述第一通信单元21,获取网络侧配置的至少一个滤波系数。
即网络侧为用户设备配置一个或者多个滤波系数的列表(List)。
可选的,给出该滤波系数list中默认的滤波系数值。
所述第一处理单元22,基于测量对象的标识信息,从所述至少一个滤波系数中选取得到进行测量所要采用的目标滤波系数。
也就是说,针对每个测量配置通过测量id关联一个滤波系数list以及该滤波系数list中某个滤波系数,通过索引进行关联。如果要关联的滤波系数等于默认的滤波系数值,则省略不配置,否则显示配置滤波系数索引。
与示例一相同的是,所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,还可以为,接收网络侧发来的配置信息,当所述配置信息中指示目标滤波系数时,基于所述配置信息确定目标滤波系数;当所述配置信息中未指示目标滤波系数时,采用默认滤波系数作为所述目标滤波系数。也就是说,测量对象的相关信息可以理解为网络侧发来的配置信息。即本示例同样提供一种场景就是基于网络侧的指示确定目标滤波系数。若网络侧未指示,可以采用默认值进行处理。
示例3、
获取网络侧配置的第二参考滤波系数。也就是接收网络侧配置的一个参考滤波系数。
所述第一通信单元,获取网络侧配置的在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
比如,可以为以下至少之一:
针对<cell,beam>的维度,分别配置两个因子或者偏置;
针对<RSRP,RSRQ,SINR>的维度,分别配置三个因子或者偏置;
针对<CSI-SR,SSB>的维度,分别配置两个因子或者偏置。
针对频点,例如<低频,中频、高频和超高频四>,分别配置n个因子或者偏置。n取决于对于频率的分配,例如上述例子n=4,如果频率分为<低频,中频、高频>则n=3,如果频率分为<低频,高频>则n=2.
所述第一处理单元,基于测量对象所对应的维度信息,选取得到目标因子或目标偏置;
基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数。
其中,所述第一处理单元,当选取目标因子时,采用第二参考滤波系 数与所述目标因子相乘,得到进行测量所要采用的目标滤波系数;
当选取目标偏置时,采用第二参考滤波系数与所述目标偏置相加,得到进行测量所要采用的目标滤波系数。
根据测量配置要求的<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>以及测量对象的频点信息,得出不同的频率因子或者偏置,计算出滤波系数。
如果是因子:则滤波系数=参考滤波系数*所有项对应的因子;
如果是偏置:则滤波系数=参考滤波系数+所有项对应的偏置;
前述多个示例均可以包括以下处理步骤:
当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
可见,通过采用上述方案,就能够使得用户设备获取网络侧配置的多个滤波系数信息,如此,用户设备可以在用户设备需要测量时基于多个滤波系数信息确定目标滤波系数,进而能够在用户设备需要进行测量的时候减少滤波系数配置的信令负荷。
实施例四、
本发明实施例提供了一种网络设备,如图3所示,包括:
第二通信单元31,向用户设备配置至少一个滤波系数信息;其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
也就是说,本发明实施例能够通过网络侧配置多个滤波系数信息,进而从多个滤波系数信息中选取得到所要采用的目标滤波系数。
下面分别采用多种示例对本实施例提供的方案进行具体说明:
示例1、
所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
所述第二通信单元31,为用户设备配置至少一个第一参考滤波系数。可以理解的是,每一个第一参考滤波系数,可以与本实施例中包含的多个维度进行设置,比如,每一个维度设置一个第一参考滤波系数。本实施例中可以将频率的维度划分为低频、中频、高频、超高频,相应的,四个维度均设置第一参考滤波系数;并且,不同的第一参考滤波系数可以不同。
本实施例中将多个滤波系数信息按照频率,将频点分为,例如低频,中频、高频和超高频等多个等级进行维度划分。并且分别在中频、高频三个等级分别配置使用不同的滤波系数。也就是说不同的滤波系数对应不同的频率维度,并且每一个频率维度中可以根据不同的频点设置多个滤波系数。
所述网络设备还包括:
第二处理单元32,确定至少一个维度中,每一个维度所对应的滤波系数信息;
所述第二通信单元31,向用户设备配置针对至少一个维度中,每一个维度所对应的滤波系数信息;
其中,所述滤波系数信息中还包括有:滤波系数相对于参考滤波系数的偏置值。
也就是说,在每一个维度的至少一个滤波系数信息中,每一个滤波系数信息中可以包括有一个偏置值、以及与哪个第一参考滤波系数相对应。当然,也可以不指示具体的参考滤波系数,而是默认的采用每一个维度所对应的一个第一参考滤波系数与偏置值进行对应。
可以理解的是,本示例中提供的维度划分方式,还可以包括有:
按照<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>,<低频,中频、高频和超高频四>等几个维度分别配置对应的滤波系数信息,该滤波系数信息是要配置的滤波系数相对于参考滤波系数的偏置值。
前述偏置值可以默认为与第一参考滤波系数的处理方式,可以包括以下几种:
第一种、偏置值可以默认为与第一参考滤波系数相加,当然还可以默认为与第一参考滤波系数相减;当然还可以有其他计算方式,这里不进行穷举。也就是说,所需要配置的滤波系数在枚举中的索引要么全都大于参考滤波系数的索引或者全都小于滤波系数的索引。
第二种、所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。这种处理方式与第一种处理方式不同之处在于,在滤波系数信息中,除了指示偏置值之外,还可以指示该偏置值与第一参考滤波系数之间的计算方式,可以为相加也可以指示为相减,均在具体的滤波系数信息中进行详细限定。
用户设备(UE)收到滤波系数信息,也就是网络侧的配置参数后,根据参考滤波系数和滤波系数偏置确定滤波系数。
由于本示例中,针对每个组合给出一个默认的配置参数,当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
即如果想要配置的滤波系数和默认配置滤波系数相同,则不显示配置滤波系数,采用默认配置滤波系数。
示例2、
所述第二通信单元31,向用户设备配置至少一个滤波系数。即网络侧为用户设备配置一个或者多个滤波系数的列表(List)。
可选的,给出该滤波系数list中默认的滤波系数值。
所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
基于测量对象的标识信息,从所述至少一个滤波系数中选取得到进行 测量所要采用的目标滤波系数。
也就是说,针对每个测量配置通过测量id关联一个滤波系数list以及该滤波系数list中某个滤波系数,通过索引进行关联。如果要关联的滤波系数等于默认的滤波系数值,则省略不配置,否则显示配置滤波系数索引。
示例3、
所述第二通信单元31,向用户设备配置第二参考滤波系数。也就是配置的一个参考滤波系数。
所述第二通信单元31,向用户设备配置在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
比如,可以为以下至少之一:
针对<cell,beam>的维度,分别配置两个因子或者偏置;
针对<RSRP,RSRQ,SINR>的维度,分别配置三个因子或者偏置;
针对<CSI-SR,SSB>的维度,分别配置两个因子或者偏置。
针对频点,例如<低频,中频、高频和超高频四>,分别配置n个因子或者偏置。n取决于对于频率的分配,例如上述例子n=4,如果频率分为<低频,中频、高频>则n=3,如果频率分为<低频,高频>则n=2.
所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
基于测量对象所对应的维度信息,选取得到目标因子或目标偏置;
基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数。
其中,所述基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数,包括:
当选取目标因子时,采用第二参考滤波系数与所述目标因子相乘,得到进行测量所要采用的目标滤波系数;
当选取目标偏置时,采用第二参考滤波系数与所述目标偏置相加,得到进行测量所要采用的目标滤波系数。
根据测量配置要求的<cell,beam>,<RSRP,RSRQ,SINR>,<CSI-SR,SSB>以及测量对象的频点信息,得出不同的频率因子或者偏置,计算出滤波系数。
如果是因子:则滤波系数=参考滤波系数*所有项对应的因子;
如果是偏置:则滤波系数=参考滤波系数+所有项对应的偏置;
前述多个示例均可以包括以下处理步骤:
当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
可见,通过采用上述方案,就能够使得用户设备获取网络侧配置的多个滤波系数信息,如此,用户设备可以在用户设备需要测量时基于多个滤波系数信息确定目标滤波系数,进而能够在用户设备需要进行测量的时候减少滤波系数配置的信令负荷。
本发明实施例还提供了一种用户设备、或接收方设备的硬件组成架构,如图4所示,包括:至少一个处理器41、存储器42、至少一个网络接口43。各个组件通过总线***44耦合在一起。可理解,总线***44用于实现这些组件之间的连接通信。总线***44除包括数据总线之外,还包括电源总线、控制总线和状态信号总线。但是为了清楚说明起见,在图4中将各种总线都标为总线***44。
可以理解,本发明实施例中的存储器42可以是易失性存储器或非易失性存储器,或可包括易失性和非易失性存储器两者。
在一些实施方式中,存储器42存储了如下的元素,可执行模块或者数据结构,或者他们的子集,或者他们的扩展集:
操作***421和应用程序422。
其中,所述处理器41配置为:能够处理前述实施例一或二的方法步骤,这里不再进行赘述。
本发明实施例提供的一种计算机存储介质,所述计算机存储介质存储有计算机可执行指令,所述计算机可执行指令被执行时实施前述实施例一或二的方法步骤。
本发明实施例上述装置如果以软件功能模块的形式实现并作为独立的产品销售或使用时,也可以存储在一个计算机可读取存储介质中。基于这样的理解,本发明实施例的技术方案本质上或者说对现有技术做出贡献的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括若干指令用以使得一台计算机设备(可以是个人计算机、服务器、或者网络设备等)执行本发明各个实施例所述方法的全部或部分。而前述的存储介质包括:U盘、移动硬盘、只读存储器(ROM,Read Only Memory)、磁碟或者光盘等各种可以存储程序代码的介质。这样,本发明实施例不限制于任何特定的硬件和软件结合。
相应地,本发明实施例还提供一种计算机存储介质,其中存储有计算机程序,该计算机程序配置为执行本发明实施例的数据调度方法。
尽管为示例目的,已经公开了本发明的优选实施例,本领域的技术人员将意识到各种改进、增加和取代也是可能的,因此,本发明的范围应当不限于上述实施例。

Claims (45)

  1. 一种配置用户设备测量参数的方法,应用于用户设备,包括:
    获取网络侧配置的至少一个滤波系数信息;
    基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数。
  2. 根据权利要求1所述的方法,其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
  3. 根据权利要求1所述的方法,其中,所述方法还包括:
    获取网络侧配置的至少一个第一参考滤波系数。
  4. 根据权利要求3所述的方法,其中,所述获取网络侧配置的至少一个滤波系数信息,包括:
    获取网络侧配置的针对至少一个维度中,每一个维度所对应的滤波系数信息;
    其中,所述滤波系数信息中还包括有:滤波系数相对于第一参考滤波系数的偏置值。
  5. 根据权利要求4所述的方法,其中,所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。
  6. 根据权利要求4所述的方法,其中,所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
    基于所述测量对象所对应的维度,以及所要测量的信号的类型以及频段,从所述至少一个滤波系数信息中选取得到目标滤波系数信息;
    基于所述目标滤波系数信息中包含的偏置值、以及第一参考滤波系数,计算得到进行测量所要采用的目标滤波系数。
  7. 根据权利要求1所述的方法,其中,所述获取网络侧配置的至少一 个滤波系数信息,包括:
    获取网络侧配置的至少一个滤波系数。
  8. 根据权利要求7所述的方法,其中,所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
    基于测量对象的标识信息,从所述至少一个滤波系数中选取得到进行测量所要采用的目标滤波系数。
  9. 根据权利要求1所述的方法,其中,所述方法还包括:
    获取网络侧配置的第二参考滤波系数。
  10. 根据权利要求9所述的方法,其中,所述获取网络侧配置的至少一个滤波系数信息,包括:
    获取网络侧配置的在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
  11. 根据权利要求10所述的方法,其中,所述基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数,包括:
    基于测量对象所对应的维度信息,选取得到目标因子或目标偏置;
    基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数。
  12. 根据权利要求11所述的方法,其中,所述基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数,包括:
    当选取目标因子时,采用第二参考滤波系数与所述目标因子相乘,得到进行测量所要采用的目标滤波系数;
    当选取目标偏置时,采用第二参考滤波系数与所述目标偏置相加,得到进行测量所要采用的目标滤波系数。
  13. 根据权利要求1-12任一项所述的方法,其中,所述方法还包括:
    当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
  14. 根据权利要求1所述的方法,其中,所述方法还包括:
    当未获取网络侧配置的滤波系数信息时,采用默认滤波系数作为所述目标滤波系数。
  15. 一种配置用户设备测量参数的方法,应用于网络设备,包括:
    向用户设备配置至少一个滤波系数信息;其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
  16. 根据权利要求15所述的方法,其中,所述方法还包括:
    为用户设备配置至少一个第一参考滤波系数。
  17. 根据权利要求16所述的方法,其中,所述向用户设备配置至少一个滤波系数信息,包括:
    向用户设备配置针对至少一个维度中,每一个维度所对应的滤波系数信息;
    其中,所述滤波系数信息中还包括有:滤波系数相对于参考滤波系数的偏置值。
  18. 根据权利要求16所述的方法,其中,所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。
  19. 根据权利要求15所述的方法,其中,所述向用户设备配置至少一个滤波系数信息,包括:
    向用户设备配置至少一个滤波系数。
  20. 根据权利要求15所述的方法,其中,所述方法还包括:
    向用户设备配置第二参考滤波系数。
  21. 根据权利要求20所述的方法,其中,所述向用户设备配置至少一个滤波系数信息,包括:
    向用户设备配置在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
  22. 一种用户设备,包括:
    第一通信单元,获取网络侧配置的至少一个滤波系数信息;
    第一处理单元,基于测量对象的相关信息、以及所述至少一个滤波系数信息,确定进行测量所要采用的目标滤波系数。
  23. 根据权利要求22所述的用户设备,其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
  24. 根据权利要求22所述的用户设备,其中,所述第一通信单元,获取网络侧配置的至少一个第一参考滤波系数。
  25. 根据权利要求24所述的用户设备,其中,所述第一通信单元,获取网络侧配置的针对至少一个维度中,每一个维度所对应的滤波系数信息;
    其中,所述滤波系数信息中还包括有:滤波系数相对于第一参考滤波系数的偏置值。
  26. 根据权利要求25所述的用户设备,其中,所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。
  27. 根据权利要求25所述的用户设备,其中,所述第一处理单元,基于所述测量对象所对应的维度,以及所要测量的信号的类型以及频段,从所述至少一个滤波系数信息中选取得到目标滤波系数信息;
    基于所述目标滤波系数信息中包含的偏置值、以及第一参考滤波系数,计算得到进行测量所要采用的目标滤波系数。
  28. 根据权利要求22所述的用户设备,其中,所述获取网络侧配置的至少一个滤波系数信息,包括:
    获取网络侧配置的至少一个滤波系数。
  29. 根据权利要求28所述的用户设备,其中,所述第一通信单元,基于测量对象的标识信息,从所述至少一个滤波系数中选取得到进行测量所要采用的目标滤波系数。
  30. 根据权利要求22所述的用户设备,其中,所述第一通信单元,获取网络侧配置的第二参考滤波系数。
  31. 根据权利要求30所述的用户设备,其中,所述第一通信单元,获取网络侧配置的在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
  32. 根据权利要求31所述的用户设备,其中,所述第一处理单元,基于测量对象所对应的维度信息,选取得到目标因子或目标偏置;
    基于选取的目标因子或目标偏置,计算得到进行测量所要采用的目标滤波系数。
  33. 根据权利要求32所述的用户设备,其中,所述第一处理单元,当选取目标因子时,采用第二参考滤波系数与所述目标因子相乘,得到进行测量所要采用的目标滤波系数;
    当选取目标偏置时,采用第二参考滤波系数与所述目标偏置相加,得到进行测量所要采用的目标滤波系数。
  34. 根据权利要求22-33任一项所述的用户设备,其中,所述第一处理单元,当目标滤波系数为默认滤波系数时,不显示所述目标滤波系数;当所述目标滤波系数非默认滤波系数时,显示配置的所述目标滤波系数的索引信息。
  35. 根据权利要求22所述的用户设备,其中,所述第一处理单元,当未获取网络侧配置的滤波系数信息时,采用默认滤波系数作为所述目标滤波系数。
  36. 一种网络设备,包括:
    第二通信单元,向用户设备配置至少一个滤波系数信息;其中,所述至少一个滤波系数中包含至少包含有默认滤波系数信息。
  37. 根据权利要求36所述的网络设备,其中,所述第二通信单元,为用户设备配置至少一个第一参考滤波系数。
  38. 根据权利要求37所述的网络设备,其中,所述网络设备还包括:
    第二处理单元,确定至少一个维度中,每一个维度所对应的滤波系数信息;
    所述第二通信单元,向用户设备配置针对至少一个维度中,每一个维度所对应的滤波系数信息;
    其中,所述滤波系数信息中还包括有:滤波系数相对于参考滤波系数的偏置值。
  39. 根据权利要求37所述的网络设备,其中,所述滤波系数信息中还包括有:所述滤波系数大于或小于所述参考滤波系数的指示信息。
  40. 根据权利要求36所述的网络设备,其中,所述第二通信单元,向用户设备配置至少一个滤波系数。
  41. 根据权利要求36所述的网络设备,其中,所述第二通信单元,向用户设备配置第二参考滤波系数。
  42. 根据权利要求41所述的网络设备,其中,所述网络设备还包括:
    第二处理单元,确定至少一个维度中,每一个维度所对应的至少一个因子或偏置值;
    所述第二通信单元,向用户设备配置在至少一个维度中,每一个维度所对应的至少一个因子或偏置值。
  43. 一种用户设备,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
    其中,所述处理器用于运行所述计算机程序时,执行权利要求1-14任一项所述方法的步骤。
  44. 一种网络设备,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
    其中,所述处理器用于运行所述计算机程序时,执行权利要求15-21任一项所述方法的步骤。
  45. 一种计算机存储介质,所述计算机存储介质存储有计算机可执行指令,所述计算机可执行指令被执行时实现权利要求1-21任一项所述方法的步骤。
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