Abstract
The present disclosure discloses a method and a device used for power adjustment in a User Equipment (UE) and a base station. The UE receives L reference signal groups transmitted by L antenna port sets respectively; receives R first signaling(s) for determining R first offset(s); and then transmits a first radio signal for determining K difference value(s) corresponding to K first reference power value(s) respectively, each of which is linearly correlated to a sum of the R first offset(s). Measurement(s) on K reference signal group(s) is (are) respectively used for determining K first reference power value(s). A transmitting power of the first radio signal is a first power associated with a first reference signal group, which is one of the K reference signal group(s). All of the L antenna port sets are used for one same serving cell or carrier. The disclosure helps improve power control performance and reduce overhead.
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5G | 29/05/2020 | ISLD-202005-041 | SHANGHAI LANGBO COMMUNICATION TECHNOLOGY |
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CN108288982B | 5G | 29/05/2020 | ISLD-202005-041 | SHANGHAI LANGBO COMMUNICATION TECHNOLOGY |
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CN108288982A | 5G | 29/05/2020 | ISLD-202005-041 | SHANGHAI LANGBO COMMUNICATION TECHNOLOGY |
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CN110099435A | 5G | 29/05/2020 | ISLD-202005-041 | SHANGHAI LANGBO COMMUNICATION TECHNOLOGY |
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Claim
1. A method in a User Equipment (UE) for power adjustment, comprising:
receiving L reference signal groups; receiving R first signaling(s); and transmitting a first radio signal; wherein the L reference signal groups are transmitted by L antenna port sets respectively, the R first signaling(s) is (are) used for determining R first offset(s), the first radio signal comprises a first report, the first report is used for determining K difference value(s), the K difference value(s) respectively corresponds(correspond) to K first reference power value(s); each of the K first reference power value(s) is linearly correlated to a sum of the R first offset(s); measurement(s) on K reference signal group(s) is (are) respectively used for determining the K first reference power value(s), the K reference signal group(s) is (are) a subset of the L reference signal groups; a transmitting power of the first radio signal is a first power; the first power is associated with a first reference signal group; the first reference signal group is one of the K reference signal group(s); the R first offset(s) is (are) used for determining the first power; an antenna port set comprises a positive integer number of antenna port(s); all antenna ports of the L antenna port sets are used for one same serving cell, or all antenna ports of the L antenna port sets are used for one same carrier; the L is a positive integer greater than 1, the K is a positive integer not greater than the L, the R is a positive integer.
2. The method according to claim 1, wherein the first report is triggered by a given condition; the given condition comprises at least one of the following:
a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s); or, further comprising: receiving a first downlink signaling, and receiving a second downlink signaling, the first report is triggered by a given condition; the given condition comprises at least one of the following: a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s), the first downlink signaling indicates a time length of the first timer, the second downlink signaling is used for determining at least one of the first threshold, the second threshold, the third threshold or the fourth threshold; or, a target first signaling is a latest first signaling among the R first signaling(s), the target first signaling comprises scheduling information of the first radio signal, the scheduling information of the first radio signal comprises at least one of time domain resources occupied, frequency domain resources occupied, an MCS, a HARQ process number, a Redundancy Version (RV) or a New Data Indicator (NDI).
3. The method according to claim 1, further comprising:
receiving Q second signaling(s); wherein the Q second signaling(s) is (are) respectively used for determining Q second offset(s), the K difference value(s) corresponds(correspond) to K second reference power value(s) respectively, each of the K second reference power value(s) is linearly correlated to a sum of the Q second offset(s), the measurement(s) on the K reference signal group(s) is (are) respectively used for determining the K second reference power value(s); the Q is a positive integer.
4. The method according to claim 1, wherein the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value;
or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, the K difference value(s) is (are) difference(s) between a first limiting power value and corresponding reference power value(s); or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, a first difference value is a difference between a second limiting power value and a corresponding reference power value, the first difference value is one difference value of the K difference value(s), difference value(s) other than the first difference value in the K difference value(s) is (are) equal to difference(s) between a first limiting power value and corresponding reference power value(s) respectively; or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, the K difference value(s) corresponds(correspond) to K target power value(s) respectively, the K difference value(s) is (are) respectively equal to difference(s) between corresponding target power value(s) and corresponding reference power value(s).
5. The method according to claim 3, wherein the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value;
or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, the K difference value(s) is (are) difference(s) between a first limiting power value and corresponding reference power value(s); or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, a first difference value is a difference between a second limiting power value and a corresponding reference power value, the first difference value is one difference value of the K difference value(s), difference value(s) other than the first difference value in the K difference value(s) is (are) equal to difference(s) between a first limiting power value and corresponding reference power value(s) respectively; or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, the K difference value(s) corresponds(correspond) to K target power value(s) respectively, the K difference value(s) is (are) respectively equal to difference(s) between corresponding target power value(s) and corresponding reference power value(s).
6. A method in a base station for power adjustment, comprising:
transmitting L reference signal groups; transmitting R first signaling(s); and receiving a first radio signal; wherein the L reference signal groups are transmitted by L antenna port sets respectively, the R first signaling(s) is (are) used for determining R first offset(s), the first radio signal comprises a first report, the first report is used for determining K difference value(s), the K difference value(s) respectively corresponds(correspond) to K first reference power value(s); each of the K first reference power value(s) is linearly correlated to a sum of the R first offset(s); measurement(s) on K reference signal group(s) is (are) respectively used for determining the K first reference power value(s), the K reference signal group(s) is (are) a subset of the L reference signal groups; a transmitting power of the first radio signal is a first power; the first power is associated with a first reference signal group; the first reference signal group is one of the K reference signal group(s); the R first offset(s) is (are) used for determining the first power; an antenna port set comprises a positive integer number of antenna port(s); all antenna ports of the L antenna port sets are used for one same serving cell, or all antenna ports of the L antenna port sets are used for one same carrier; the L is a positive integer greater than 1, the K is a positive integer not greater than the L, the R is a positive integer.
7. The method according to claim 6, wherein the first report is triggered by a given condition; the given condition comprises at least one of the following:
a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s); or, further comprising: transmitting a first downlink signaling, and transmitting a second downlink signaling, the first report is triggered by a given condition; the given condition comprises at least one of the following: a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s), the first downlink signaling indicates a time length of the first timer, the second downlink signaling is used for determining at least one of the first threshold, the second threshold, the third threshold or the fourth threshold; or, a target first signaling is a latest first signaling among the R first signaling(s), the target first signaling comprises scheduling information of the first radio signal, the scheduling information of the first radio signal comprises at least one of time domain resources occupied, frequency domain resources occupied, an MCS, a HARQ process number, an RV or an NDI.
8. The method according to claim 6, further comprising:
transmitting Q second signaling(s); wherein the Q second signaling(s) is (are) respectively used for determining Q second offset(s), the K difference value(s) corresponds(correspond) to K second reference power value(s) respectively, each of the K second reference power value(s) is linearly correlated to a sum of the Q second offset(s), the measurement(s) on the K reference signal group(s) is (are) respectively used for determining the K second reference power value(s); the Q is a positive integer.
9. The method according to claim 6, wherein the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value;
or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, the K difference value(s) is (are) difference(s) between a first limiting power value and corresponding reference power value(s); or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, a first difference value is a difference between a second limiting power value and a corresponding reference power value, the first difference value is one difference value of the K difference value(s), difference value(s) other than the first difference value in the K difference value(s) is (are) equal to difference(s) between a first limiting power value and corresponding reference power value(s) respectively; or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, the K difference value(s) corresponds(correspond) to K target power value(s) respectively, the K difference value(s) is (are) respectively equal to difference(s) between corresponding target power value(s) and corresponding reference power value(s).
10. The method according to claim 8, wherein the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value;
or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, the K difference value(s) is (are) difference(s) between a first limiting power value and corresponding reference power value(s); or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, a first difference value is a difference between a second limiting power value and a corresponding reference power value, the first difference value is one difference value of the K difference value(s), difference value(s) other than the first difference value in the K difference value(s) is (are) equal to difference(s) between a first limiting power value and corresponding reference power value(s) respectively; or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, the K difference value(s) corresponds(correspond) to K target power value(s) respectively, the K difference value(s) is (are) respectively equal to difference(s) between corresponding target power value(s) and corresponding reference power value(s).
11. A UE for power adjustment, comprising:
a first receiver, receiving L reference signal groups; a second receiver, receiving R first signaling(s); and a first transmitter, transmitting a first radio signal; wherein the L reference signal groups are transmitted by L antenna port sets respectively, the R first signaling(s) is (are) used for determining R first offset(s), the first radio signal comprises a first report, the first report is used for determining K difference value(s), the K difference value(s) respectively corresponds(correspond) to K first reference power value(s); each of the K first reference power value(s) is linearly correlated to a sum of the R first offset(s); measurement(s) on K reference signal group(s) is (are) respectively used for determining the K first reference power value(s), the K reference signal group(s) is (are) a subset of the L reference signal groups; a transmitting power of the first radio signal is a first power; the first power is associated with a first reference signal group; the first reference signal group is one of the K reference signal group(s); the R first offset(s) is (are) used for determining the first power; an antenna port set comprises a positive integer number of antenna port(s); all antenna ports of the L antenna port sets are used for one same serving cell, or all antenna ports of the L antenna port sets are used for one same carrier; the L is a positive integer greater than 1, the K is a positive integer not greater than the L, the R is a positive integer.
12. The UE according to claim 11, wherein the first report is triggered by a given condition; the given condition comprises at least one of the following:
a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s); or, the first receiver receives a first downlink signaling and a second downlink signaling, the first report is triggered by a given condition; the given condition comprises at least one of the following: a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s), the first downlink signaling indicates a time length of the first timer, the second downlink signaling is used for determining at least one of the first threshold, the second threshold, the third threshold or the fourth threshold; or, a target first signaling is a latest first signaling among the R first signaling(s), the target first signaling comprises scheduling information of the first radio signal, the scheduling information of the first radio signal comprises at least one of time domain resources occupied, frequency domain resources occupied, an MCS, a HARQ process number, an RV or an NDI.
13. The UE according to claim 11, wherein the second receiver receives Q second signaling(s); wherein the Q second signaling(s) is (are) respectively used for determining Q second offset(s), the K difference value(s) corresponds(correspond) to K second reference power value(s) respectively, each of the K second reference power value(s) is linearly correlated to a sum of the Q second offset(s), the measurement(s) on the K reference signal group(s) is (are) respectively used for determining the K second reference power value(s); the Q is a positive integer.
14. The UE according to claim 11, wherein the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value;
or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, the K difference value(s) is (are) difference(s) between a first limiting power value and corresponding reference power value(s); or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, a first difference value is a difference between a second limiting power value and a corresponding reference power value, the first difference value is one difference value of the K difference value(s), difference value(s) other than the first difference value in the K difference value(s) is (are) equal to difference(s) between a first limiting power value and corresponding reference power value(s) respectively; or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value, the K difference value(s) corresponds(correspond) to K target power value(s) respectively, the K difference value(s) is (are) respectively equal to difference(s) between corresponding target power value(s) and corresponding reference power value(s).
15. The UE according to claim 13, wherein the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value;
or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, the K difference value(s) is (are) difference(s) between a first limiting power value and corresponding reference power value(s); or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, a first difference value is a difference between a second limiting power value and a corresponding reference power value, the first difference value is one difference value of the K difference value(s), difference value(s) other than the first difference value in the K difference value(s) is (are) equal to difference(s) between a first limiting power value and corresponding reference power value(s) respectively; or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is determined by a corresponding first reference power value and a corresponding second reference power value, the K difference value(s) corresponds(correspond) to K target power value(s) respectively, the K difference value(s) is (are) respectively equal to difference(s) between corresponding target power value(s) and corresponding reference power value(s).
16. A base station for power adjustment, comprising:
a second transmitter, transmitting L reference signal groups; a third transmitter, transmitting R first signaling(s); and a third receiver, receiving a first radio signal; wherein the L reference signal groups are transmitted by L antenna port sets respectively, the R first signaling(s) is (are) used for determining R first offset(s), the first radio signal comprises a first report, the first report is used for determining K difference value(s), the K difference value(s) respectively corresponds(correspond) to K first reference power value(s); each of the K first reference power value(s) is linearly correlated to a sum of the R first offset(s); measurement(s) on K reference signal group(s) is (are) respectively used for determining the K first reference power value(s), the K reference signal group(s) is (are) a subset of the L reference signal groups; a transmitting power of the first radio signal is a first power; the first power is associated with a first reference signal group; the first reference signal group is one of the K reference signal group(s); the R first offset(s) is (are) used for determining the first power; an antenna port set comprises a positive integer number of antenna port(s); all antenna ports of the L antenna port sets are used for one same serving cell, or all antenna ports of the L antenna port sets are used for one same carrier; the L is a positive integer greater than 1, the K is a positive integer not greater than the L, the R is a positive integer.
17. The base station according to claim 16, wherein the first report is triggered by a given condition; the given condition comprises at least one of the following:
a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s); or, the second transmitter transmits a first downlink signaling and a second downlink signaling, the first report is triggered by a given condition; the given condition comprises at least one of the following: a change in an average of K pathloss value(s) is greater than a first threshold, a change in a first pathloss value of the K pathloss value(s) is greater than a second threshold, the first pathloss value is a pathloss value with a biggest change among the K pathloss value(s), a change in a second pathloss value of the K pathloss value(s) is greater than a third threshold, the second pathloss value is a pathloss value with a smallest change among the K pathloss value(s), a change in a reference pathloss value is greater than a fourth threshold, the reference pathloss value is linearly correlated to each of the K pathloss value(s) respectively, a first timer completes time counting, the UE receives a target signaling, the target signaling is used for triggering the first report, herein, the K pathloss value(s) is (are) respectively determined by the measurement(s) on the K reference signal group(s), the first downlink signaling indicates a time length of the first timer, the second downlink signaling is used for determining at least one of the first threshold, the second threshold, the third threshold or the fourth threshold; or, a target first signaling is a latest first signaling among the R first signaling(s), the target first signaling comprises scheduling information of the first radio signal, the scheduling information of the first radio signal comprises at least one of time domain resources occupied, frequency domain resources occupied, an MCS, a HARQ process number, an RV or an NDI.
18. The base station according to claim 16, wherein the third transmitter transmits Q second signaling(s); wherein the second receiver receives Q second signaling(s); wherein the Q second signaling(s) is (are) respectively used for determining Q second offset(s), the K difference value(s) corresponds(correspond) to K second reference power value(s) respectively, each of the K second reference power value(s) is linearly correlated to a sum of the Q second offset(s), the measurement(s) on the K reference signal group(s) is (are) respectively used for determining the K second reference power value(s); the Q is a positive integer.
19. The base station according to claim 16, wherein the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a corresponding first reference power value;
or, the K difference value(s) corresponds(correspond) to K reference power value(s) respectively, a given reference power value is any reference power value of the K reference power value(s), the given reference power value is equal to a co
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