WO2022017489A1 - 功率获取方法、装置及节点设备 - Google Patents

功率获取方法、装置及节点设备 Download PDF

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Publication number
WO2022017489A1
WO2022017489A1 PCT/CN2021/108081 CN2021108081W WO2022017489A1 WO 2022017489 A1 WO2022017489 A1 WO 2022017489A1 CN 2021108081 W CN2021108081 W CN 2021108081W WO 2022017489 A1 WO2022017489 A1 WO 2022017489A1
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Prior art keywords
power
unit
transmission
transmit power
cell group
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PCT/CN2021/108081
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English (en)
French (fr)
Inventor
王欢
刘进华
Original Assignee
维沃移动通信有限公司
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Publication date
Application filed by 维沃移动通信有限公司 filed Critical 维沃移动通信有限公司
Priority to JP2023500410A priority Critical patent/JP7460848B2/ja
Priority to EP21846488.1A priority patent/EP4164315A4/en
Publication of WO2022017489A1 publication Critical patent/WO2022017489A1/zh
Priority to US18/094,197 priority patent/US20230156684A1/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • H04W72/044Wireless resource allocation based on the type of the allocated resource
    • H04W72/0473Wireless resource allocation based on the type of the allocated resource the resource being transmission power
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/18TPC being performed according to specific parameters
    • H04W52/28TPC being performed according to specific parameters using user profile, e.g. mobile speed, priority or network state, e.g. standby, idle or non transmission
    • H04W52/281TPC being performed according to specific parameters using user profile, e.g. mobile speed, priority or network state, e.g. standby, idle or non transmission taking into account user or data type priority
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/50Allocation or scheduling criteria for wireless resources
    • H04W72/56Allocation or scheduling criteria for wireless resources based on priority criteria
    • H04W72/563Allocation or scheduling criteria for wireless resources based on priority criteria of the wireless resources
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L5/00Arrangements affording multiple use of the transmission path
    • H04L5/0001Arrangements for dividing the transmission path
    • H04L5/0003Two-dimensional division
    • H04L5/0005Time-frequency
    • H04L5/0007Time-frequency the frequencies being orthogonal, e.g. OFDM(A), DMT
    • H04L5/001Time-frequency the frequencies being orthogonal, e.g. OFDM(A), DMT the frequencies being arranged in component carriers
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/30TPC using constraints in the total amount of available transmission power
    • H04W52/36TPC using constraints in the total amount of available transmission power with a discrete range or set of values, e.g. step size, ramping or offsets
    • H04W52/365Power headroom reporting
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/30TPC using constraints in the total amount of available transmission power
    • H04W52/36TPC using constraints in the total amount of available transmission power with a discrete range or set of values, e.g. step size, ramping or offsets
    • H04W52/367Power values between minimum and maximum limits, e.g. dynamic range
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02DCLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
    • Y02D30/00Reducing energy consumption in communication networks
    • Y02D30/70Reducing energy consumption in communication networks in wireless communication networks

Definitions

  • the present invention relates to the field of communication technologies, and in particular, to a power acquisition method, device and node device.
  • the distributed unit (Distributed Unit, DU) and the mobile terminal (Mobile Termination, MT) of the IAB node can transmit simultaneously.
  • an IAB node can connect to multiple parent IAB (parent IAB) nodes and send information to multiple parent IAB nodes at the same time (for example, IAB MT for dual link).
  • parent IAB parent IAB
  • IAB MT mobile Termination
  • DU MT Master Cell Group
  • SCG MT Secondary Cell Group
  • the total transmit power is shared, but the power sharing scheme of the related art does not consider the existence of multiple connections of the MT. Therefore, there is no scheme of power sharing between the MT MCG link, the MT SCG link and the DU in the related art.
  • the purpose of the embodiments of the present application is to provide a power acquisition method, apparatus, and node device, which can solve the problem of how to perform power sharing in at least one cell group of a DU and an MT.
  • a power acquisition method applied to a node device, including:
  • the configuration power includes at least one of a first configuration power and a second configuration power
  • the first configuration power refers to the power configured for the distributed unit DU of the self-backhaul IAB node
  • the second configuration power The configured power includes the power configured for the MT in the IAB node and the power configured for at least one cell group of the MT, or the second configured power includes the power configured for the MT at least one cell group;
  • the sending priority includes at least one of: DU sending priority, MT sending priority, and MT sending priority of at least one cell group.
  • a power acquisition apparatus applied to a node device, including:
  • a first obtaining module configured to obtain configuration power, where the configuration power includes at least one of a first configuration power and a second configuration power, and the first configuration power refers to the configuration for the distribution unit DU of the self-backhaul IAB node
  • the second configured power includes the configured power of the MT in the IAB node and the power configured for at least one cell group of the MT, or the second configured power includes at least one cell group for the MT. Configured power;
  • a first determining module configured to determine the transmit power of the DU and the transmit power of at least one cell group of the MT, wherein at least one of the transmit power of the DU and the transmit power of at least one cell group of the MT item is determined according to the configuration power and transmission priority;
  • the sending priority includes at least one of: DU sending priority, MT sending priority, and MT sending priority of at least one cell group.
  • a node device in a third aspect, includes a processor, a memory, and a program or instruction stored on the memory and executable on the processor, the program or instruction being executed by the processor When implementing the steps of the method as described in the first aspect.
  • a readable storage medium is provided, and a program or an instruction is stored on the readable storage medium, and when the program or instruction is executed by a processor, the steps of the method according to the first aspect are implemented.
  • a fifth aspect provides a chip, the chip includes a processor and a communication interface, the communication interface is coupled to the processor, and the processor is configured to run a network-side device program or instruction, implementing the method described in the first aspect. method described.
  • the configuration power is obtained; according to the configuration power and the transmission priority, the transmission power of the DU and/or the transmission power of the at least one cell group of the MT are determined, thereby realizing the at least one cell group of the DU and the MT.
  • the dynamic power sharing between them improves the power efficiency of IAB transmission.
  • Fig. 1 is the structural representation of IAB system
  • FIG. 2 shows a schematic diagram of the CU-DU structure of the IAB system
  • FIG. 3 shows a schematic flowchart of a power acquisition method according to an embodiment of the present application
  • FIG. 4 shows a schematic diagram of a module of a power acquisition device according to an embodiment of the present application
  • FIG. 5 shows one of the structural block diagrams of the node device according to the embodiment of the present application.
  • FIG. 6 shows the second structural block diagram of a node device according to an embodiment of the present application.
  • first, second and the like in the description and claims of the present application are used to distinguish similar objects, and are not used to describe a specific order or sequence. It is to be understood that the data so used are interchangeable under appropriate circumstances so that the embodiments of the present application can be practiced in sequences other than those illustrated or described herein, and "first”, “second” distinguishes Usually it is a class, and the number of objects is not limited.
  • the first object may be one or multiple.
  • “and/or” in the description and claims indicates at least one of the connected objects, and the character “/" generally indicates that the associated objects are in an "or” relationship.
  • LTE Long Term Evolution
  • LTE-Advanced LTE-Advanced
  • LTE-A Long Term Evolution
  • CDMA Code Division Multiple Access
  • TDMA Time Division Multiple Access
  • FDMA Frequency Division Multiple Access
  • OFDMA Orthogonal Frequency Division Multiple Access
  • SC-FDMA Single-carrier Frequency-Division Multiple Access
  • system and “network” in the embodiments of the present application are often used interchangeably, and the described technology can be used not only for the above-mentioned systems and radio technologies, but also for other systems and radio technologies.
  • NR New Radio
  • the following description describes a New Radio (NR) system for example purposes, and uses NR terminology in most of the description below, although these techniques are also applicable to applications other than NR system applications, such as 6th generation ( 6 th Generation, 6G) communication system.
  • 6th generation 6 th Generation, 6G
  • the integrated access backhaul (IAB) system is a technology that NR Rel-16 started to formulate standards.
  • Figure 1 shows a schematic diagram of an IAB system.
  • An IAB node includes a distributed unit (Distributed Unit, DU) functional part and a mobile terminal (Mobile Termination, MT) functional part.
  • DU Distributed Unit
  • MT Mobile Termination
  • an access point (ie IAB node) 11 can find an upstream access point (parent IAB node, parent node) 12, and establish a wireless connection with the DU of the upstream access point, the wireless connection is called backhaul link (backhaul link).
  • backhaul link backhaul link
  • a self-backhaul loop includes a donor IAB node 13, which has a directly connected wired transmission network.
  • FIG. 2 is a structural diagram of a central unit-distributed unit (Centralized Unit-Distributed Unit, CU-DU) of an IAB system.
  • a CU may also be called a control unit.
  • the DUs of all IAB nodes are connected to a CU node, which configures the DUs through the F1-AP protocol.
  • the CU configures the MT through the RRC protocol. Donor IAB nodes do not have the MT functional part.
  • the introduction of the IAB system is to solve the situation that the wired transmission network is not deployed in place when the access points are densely deployed. That is, when there is no wired transmission network, the access point can rely on wireless backhaul.
  • an embodiment of the present application provides a power acquisition method, which is applied to a node device, where the node device is specifically an IAB node, and the method includes:
  • the configuration power includes at least one of a first configuration power and a second configuration power
  • the first configuration power refers to the power configured for the distributed unit DU of the self-backhaul IAB node
  • the second configuration power The configured power includes the power configured for the MT in the IAB node and the power configured for at least one cell group of the MT, or the second configured power includes the power configured for at least one cell group of the MT;
  • the sending priority includes at least one of: DU sending priority, MT sending priority, and MT sending priority of at least one cell group.
  • Protocol conventions for network configurations, and transmission priorities at the physical layer.
  • the transmission priority between DU and MT agreed in the protocol or network configuration; or the transmission priority between DU, MT MCG and MT SCG agreed in the protocol or network configuration;
  • the transmission priority of the cell group stipulates that the transmission priority of the DU and MT cell group is determined based on the physical channel type of the DU and MT transmission.
  • the protocol stipulates that the transmission priorities of the DU and MT cell groups are determined based on the service types transmitted by the DU and the MT.
  • the transmission of the physical layer with a higher priority indicated by the DCI is preferentially sent.
  • the network configuration refers to configuration through higher layer signaling, such as RRC or F1-C configuration.
  • the power acquisition method of the embodiment of the present application acquires the configured power; and determines the transmission power of the DU and/or the transmission power of at least one cell group of the MT according to the configured power and the transmission priority, thereby realizing at least one of the DU and the MT. Dynamic power sharing between cell groups improves the power efficiency of IAB transmission.
  • determining the transmit power of the DU and the transmit power of at least one cell group of the MT includes:
  • determining the transmission power of the DU and the transmission power of the MT wherein at least one of the transmission power of the DU and the transmission power of the MT is determined according to the configuration power and the transmission priority;
  • the transmit power of at least one cell group of the MT is determined according to the transmit power of the MT or a preset power fixed value.
  • dynamic power allocation is performed between the DU and the MT, for example, dynamic power allocation is performed according to at least one of the maximum power principle and the minimum guaranteed power principle.
  • the traditional power sharing method is adopted between at least one cell group of the MT. Such as semi-static power distribution or dynamic power distribution.
  • the first configured power includes Q DU , where Q DU is the transmit power or the maximum transmit power configured for the DU, the second configured power includes Q MT , and Q MT is for The transmit power or the maximum transmit power configured by the MT.
  • Q DU +Q MT >P total Q total is the total power of the IAB node, or, P total is the maximum power output by the transmitter of the IAB node, or, P total is the total power that the DU and MT can support. transmit power.
  • the determining the transmit power of the DU includes:
  • the transmission power of the DU is determined according to the difference between the total power P total of the IAB node and the transmission power of the MT and Q DU ;
  • the transmission power of the DU is determined, and the transmission power of the DU is less than or equal to Q DU .
  • the transmission power of the MT is determined, and the transmission power of the MT is less than or equal to Q MT , according to the P total and the transmission power of the MT
  • the difference between Q and the smaller value in the Q DU determines the transmit power of the DU.
  • the determining of the transmit power of the MT includes:
  • the transmission power of the MT is determined according to the difference between the total power P total of the IAB node and the transmission power of the DU and Q MT .
  • the transmission priority of the DU when the transmission priority of the DU is higher than the transmission priority of the MT, first determine the transmission power of the DU, and the transmission power of the DU is less than or equal to Q DU ; according to the P total and the transmission of the DU The power difference and the Q MT determine the transmit power of the MT.
  • the transmission power of the MT and/or the transmission power of the DU is determined according to the principle of maximum power.
  • the first configured power is the minimum guaranteed power P DU configured for the DU
  • the second configured power is the minimum guaranteed power P MT configured by the MT. , P DU +P MT ⁇ P total ;
  • the determining the transmit power of the DU includes:
  • the transmission power of the DU is determined according to the first difference between the total power P total of the IAB node and the transmission power of the MT;
  • the transmission power of the DU is determined according to the second difference between the total power P total of the IAB node and the P MT.
  • the maximum transmission power of the MT is determined according to the first difference between the total power of the IAB node and the P DU; at least according to the maximum transmission power of the MT power, to determine the transmission power of the MT; according to the second difference between the total power of the IAB node and the transmission power of the MT, determine the transmission power of the DU.
  • the above-mentioned determination of the transmit power of the DU includes the following two ways:
  • Method 1 directly determine the transmit power of the DU
  • Mode 2 First determine the maximum transmission power of the DU, and determine the transmission power of the DU according to the maximum transmission power of the DU and the downlink transmission scheduled by the DU.
  • the maximum transmission power P total - P DU of the MT according to the minimum guaranteed power P DU of the DU, and then determine the power pwr MT (transmission power of the MT) required for the uplink transmission of the MT according to the scheduled MT transmission and power control algorithm.
  • pwr MT when pwr MT >P total- P DU , pwr MT is set to P total- P DU ; then determine that the maximum transmit power of Du is P total- pwr MT ; then, according to the downlink transmission scheduled by DU, determine the transmit power of DU pwr DU , when pwr DU is greater than P total -pwr MT , pwr DU is set to P total -pwr MT .
  • the determining of the transmit power of the MT includes:
  • the transmission power of the MT is determined according to the third difference between the total power P total of the IAB node and the P DU;
  • the transmission power of the MT is determined according to the fourth difference between the total power P total of the IAB node and the transmission power of the DU.
  • the transmission power of the DU is first determined according to the difference between the total power of the IAB node and the P MT, and then the total power P of the IAB node is determined.
  • the fourth difference between the total and the transmission power of the DU determines the maximum transmission power of the MT, and at least determines the transmission power of the MT according to the maximum transmission power of the MT.
  • the maximum transmit power of the DU can be first determined as P total -P MT , and then the transmit power of the DU pwr DU is determined according to the downlink transmission scheduled for the DU.
  • pwr DU is greater than P total -P MT
  • pwr DU is set to P total - P MT
  • determine that the maximum transmission power of MT is P total- pwr DU
  • pwr MT is set to P total -pwr DU .
  • the determining of the transmit power of the MT includes:
  • the determining the actual maximum transmit power of the MT includes:
  • the smaller value of the third difference and the P cmax is selected as the actual maximum transmit power of the MT.
  • the maximum transmit power of the MT is min(P cmax , P total - P DU ), that is, when the required transmit power of the MT is greater than min(P cmax , P total - P DU ), the The transmission power is min(P cmax , P total - P DU ).
  • the smaller value of the fourth difference and the P cmax is selected as the actual maximum transmit power of the MT, and the P cmax is the agreement agreed or The maximum transmit power of the preconfigured MT.
  • the transmission power of the MT and/or the transmission power of the DU is determined according to the principle of minimum guaranteed power.
  • the first configured power includes Q DU and/or P DU
  • the second configured power includes Q MT and/or P MT
  • Q DU refers to the DU
  • P DU refers to the minimum guaranteed power configured for the DU
  • Q MT refers to the transmit power or maximum transmit power configured for the MT
  • P MT refers to the configured transmit power for the MT.
  • Minimum guaranteed power; the determining the transmit power of the DU includes:
  • the transmission power of the DU is determined according to the difference between the total power P total of the IAB node and the transmission power of the MT and Q DU ;
  • the transmission power of the DU is determined according to the difference between the total power P total of the IAB node and P MT and Q DU .
  • the maximum transmission power of the MT can be calculated first according to the difference between the total power P total of the IAB node and the P DU and Q MT ;
  • the maximum transmit power determines the transmit power of the MT, and then determines the transmit power of the DU according to the difference between the total power P total of the IAB node and the transmit power of the MT and Q DU .
  • the minimum guaranteed power of DU P DU and Q MT first determine the maximum transmit power of MT as min(Q MT , P total - P DU ), and then according to the uplink transmission and power control parameters scheduled for the MT, determine the maximum transmission power of the MT.
  • the required uplink transmission power pwr MT transmission power of MT
  • pwr MT transmission power of MT
  • pwr MT transmission power of MT
  • the difference between the total power of the IAB node P total and P MT and the smaller value of the Q DU are selected as the maximum transmission power of the DU. ; Determine the transmit power of the DU at least according to the maximum transmit power of the DU.
  • the minimum guaranteed power P MT and Q DU of the MT first determine the maximum transmission power of the DU as min(Q DU , P total -P MT ), and then according to the downlink transmission and power control parameters scheduled for the DU, determine the maximum transmission power of the DU.
  • the required downlink transmission power pwr DU transmission power of DU
  • pwr DU transmission power of DU
  • pwr DU is set to min(Q DU , P total -P MT ).
  • the determining of the transmit power of the MT includes:
  • the transmission power of the MT is determined according to the difference between the total power P total of the IAB node and the P DU and Q MT ;
  • the transmission power of the MT is determined according to the difference between the total power P total of the IAB node and the transmission power of the DU and Q MT .
  • the transmission priority of the MT is higher than the transmission priority of the DU
  • the smaller value of the difference between the total power P total of the IAB node and the P DU and the Q MT is selected as the maximum transmission power of the MT , and determine the transmit power of the MT at least according to the maximum transmit power of the MT.
  • the minimum guaranteed power of DU P DU and Q MT first determine the maximum transmit power of MT as min(Q MT , P total - P DU ), and then according to the uplink transmission and power control parameters scheduled for the MT, determine the maximum transmission power of the MT.
  • the required uplink transmission power pwr MT transmission power of MT
  • pwr MT transmission power of MT
  • pwr MT is set to min(Q MT P total -P DU ).
  • the sending priority of DU is higher than the sending priority of MT, first select the smaller value according to the difference between the total power of the IAB node P total and P MT and Q DU , as the maximum value of the DU.
  • Transmission power determine the transmission power of the DU at least according to the maximum transmission power of the DU; and then determine the transmission power of the MT according to the difference between P total and the transmission power of the DU and Q MT .
  • the minimum guaranteed power P MT and Q DU of the MT first determine the maximum transmission power of the DU as min(Q DU , P total -P MT ), and then according to the downlink transmission and power control parameters scheduled for the DU, determine the maximum transmission power of the DU.
  • the required downlink transmission power pwr DU transmission power of DU
  • pwr DU transmission power of DU
  • pwr DU transmission power of DU
  • the transmission power of the DU and/or the transmission power of the MT is determined by combining the maximum power principle and the minimum guaranteed power principle.
  • the maximum transmit power may be greater than P cmax MT, MT i.e. when determining the maximum transmit power, the maximum power value by dedicated signaling configuration may be covered predetermined maximum power value.
  • preconfigured maximum transmit power may be greater than P 0 DU, DU i.e. when determining the maximum transmit power, the maximum power value by dedicated signaling configuration may be covered predetermined maximum power value.
  • P 0 may be the maximum transmit power of the DU specified by RAN4.
  • the second configuration power includes the maximum transmission power Q MCG configured for the MT primary cell group and the maximum transmission power Q SCG configured for the MT secondary cell group;
  • the transmission power of the MT includes The maximum transmission power configured for the MT, the maximum transmission power of the MT agreed in the protocol, or the actual maximum transmission power of the MT;
  • the Q MCG and Q SCG and according to the preset power sharing rule, obtain the maximum transmission power of the MT primary cell group and the maximum transmission power of the MT secondary cell group;
  • the preset power sharing rule includes a first power sharing rule, a second power sharing rule and a third power sharing rule
  • the first power sharing rule refers to dynamic power sharing when the sum of Q MCG and Q SCG is greater than the target power
  • the second power sharing rule refers to semi-static power sharing when the sum of Q MCG and Q SCG is less than or equal to the target power
  • the third power sharing rule is to perform dynamic power sharing
  • the target power is the transmit power of the MT or a preset power fixed value.
  • the UE If the UE is in dual link state, its transmit power can be shared between the MCG link and the SCG link.
  • the power sharing between the MCG link and the SCG link can be divided into semi-static and dynamic power sharing.
  • the sum of the maximum uplink transmit power configured on the MCG link and the SCG link is less than or equal to the total transmit power of the UE, and the MCG and SCG are respectively limited by their configured maximum transmit power when performing power control. .
  • the maximum transmit power configured on the MCG link and the SCG link is only applicable to the moment when the MCG link and the SCG link are simultaneously transmitted.
  • LTE DC adopts the principle of minimum guaranteed power.
  • the MCG link and SCG link are each configured with a minimum guaranteed transmission power and the sum of the two is less than or equal to the maximum transmission power of the UE, while the MCG link and the SCG link are each configured with a minimum guaranteed transmission power.
  • the SCG link may share the remaining power portion (ie, the total power minus the remaining power of the sum of the minimum guaranteed transmit powers of the MCG link and the SCG link).
  • NR-NR DC adopts the principle of maximum power.
  • the MCG link and the SCG link are each configured with a maximum transmit power, and the sum of the two can be greater than the maximum transmit power of the UE.
  • the UE When the sum of the power required by the MCG link and the SCG link sent at the same time is greater than the maximum transmit power of the UE, the UE needs to give priority to allocating transmit power to the MCG link to ensure the transmission of the MCG link.
  • the transmit power of the MCG link is still Limited by the configured maximum transmit power
  • the transmit power of the SCG link is limited by the smaller of the configured maximum transmit power and the remaining transmit power (ie, the total power minus the transmit power of the MCG link).
  • the method before acquiring the maximum transmit power of the MT primary cell group and the maximum transmit power of the MT secondary cell group, the method further includes:
  • At least one of the Q MCG and the Q SCG is adjusted according to the difference between the preset fixed power value and the transmit power of the MT.
  • P fixed P cmax or P total
  • P cmax is the maximum transmit power of the MT specified in the protocol
  • P total is the configured maximum transmit power of the MT.
  • both the Q MCG or the Q SCG are adjusted. For example, if the difference between the preset fixed power value and the maximum transmit power of the MT is 10 watts, that is, the preset fixed power value is 10 watts larger than the maximum transmit power of the MT, then the Q MCG is reduced by 10 watts, or the Q SCG is reduced by 10 watts. Reduce by 10 watts.
  • the difference between the preset fixed power value and the maximum transmit power of the MT is -10 watts, that is, the preset fixed power value is 10 watts smaller than the maximum transmit power of the MT
  • the Q MCG is increased by 10 watts, or,
  • the Q SCG is increased by 10 watts, that is, either the Q MCG or the Q SCG is adjusted by the same value as the difference above.
  • both the Q MCG and the Q SCG are adjusted. Specifically, according to the difference between the preset fixed power value and the maximum transmit power of the MT, the Q MCG is adjusted according to the first adjustment ratio, and the Q SCG is adjusted according to the second adjustment ratio.
  • the first adjustment ratio and the second adjustment ratio may be the same or different.
  • the sum of the first adjustment ratio and the second adjustment ratio is 1, for example, the two adjustment ratios are respectively 0.5, that is, Q MCG and Q SCG equally share the above difference; optionally, the above first adjustment
  • the ratio and the second adjustment ratio are determined according to the above difference. For example, if the preset power fixed value increases by 10% relative to the maximum transmit power of the MT, it is determined that the first adjustment ratio and the second adjustment ratio are both 10%, that is, Q MCG and Q SCG are both increased by 10%.
  • the maximum power of the MCG and the SCG is limited by the maximum transmission power of the MT.
  • the transmit power of the DU and the transmit power of at least one cell group of the MT are directly determined.
  • dynamic power allocation is performed between the DU and at least one cell group of the MT. Specifically, according to at least one of the maximum power principle and the minimum guaranteed power principle, the transmission power of the DU and/or the at least one cell group of the MT is determined. transmit power. For example, the transmission power of the DU, the transmission power of the MT primary cell group, and the transmission power of the MT secondary cell group are determined.
  • the first configured power is Q DU , where Q DU refers to the transmit power or the maximum transmit power configured for the DU, and the The second configured power includes Q 1 and Q 2 .
  • Q 1 refers to the transmit power or the maximum transmit power configured for the MT primary cell group, and Q 2 refers to the configured transmit power or the maximum transmit power for the MT secondary cell group.
  • Q DU +Q 1 +Q 2 >P total , where P total is the total power of the IAB node.
  • Determining the transmit power of the DU and the transmit power of at least one cell group of the MT includes:
  • the sending priority of the first unit y in the IAB node is higher than the sending priority of the second unit x in the IAB node, according to min(Q x , P total -sum(pwr y )), determining the transmit power or the actual maximum transmit power of the second unit;
  • the first unit is at least one of the DU, the MT secondary cell group and the MT primary cell group in the IAB node, and the second unit includes the DU, the MT secondary cell group or the MT primary cell group, and the first unit is different from the second unit;
  • Q x represents the maximum transmit power or transmit power configured for the second unit
  • Q x is Q DU , Q 1 or Q 2
  • pwr y represents the transmit power of the first unit
  • P total is the total power of the IAB node .
  • the first unit y is a DU
  • the second unit x is the MT primary cell group
  • the transmission priority of the MT secondary cell group is lower than the transmission priority of the MT primary cell group.
  • the transmit power of the MT primary cell group is min(Q 1 , P-sum(pwr DU )). That is, the transmit power of the DU is determined first, and then the transmit power of the MT primary cell group is determined according to Q 1 and P-sum (pwr DU ).
  • the first unit is the DU and the MT primary cell group
  • the second unit is the MT secondary cell group
  • the maximum power principle is adopted to determine the transmission power of the DU and/or the transmission power of at least one cell group of the MT.
  • the transmission power of the DU and/or the transmission power of at least one cell group of the MT may be determined in the following manner.
  • the first unit is at least one of the DU, the MT secondary cell group and the MT primary cell group in the IAB node
  • the second unit is a cell group in the MT
  • the first unit and the The second unit is different
  • pwr k represents the transmit power of the k unit in the MT, and the transmit priority of the k unit is higher than that of the second unit
  • P cmax is the maximum transmit power of the MT agreed in the protocol
  • Q x represents the maximum transmit power or transmit power configured for the second unit
  • Q x is Q DU , Q 1 or Q 2
  • pwr y represents the transmit power of the first unit.
  • the first configured power includes P DU
  • the second configured power includes P 1 and P 2
  • the P DU refers to the minimum guaranteed power configured for the DU
  • the P 1 refers to the minimum guaranteed power configured for the MT primary cell group
  • the P 2 refers to the minimum guaranteed power configured for the MT secondary cell group.
  • P DU +P 1 +P 2 ⁇ P total P total is the total power of the IAB node;
  • Determining the transmit power of the DU and the transmit power of at least one cell group of the MT includes:
  • the transmission priority of the first unit y in the IAB node is higher than the transmission priority of the second unit x in the IAB node, and the transmission priority of the second unit x is higher than that in the IAB node
  • the transmission priority of the third unit z according to P total- sum(pwr y )-sum(P z ), determine the transmission power or the actual maximum transmission power of the second unit;
  • the first unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the second unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the third unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node, and the first unit, the second unit and the third unit are different;
  • the pwr y represents the transmit power of the first unit
  • P z represents the minimum guaranteed power configured for the third unit
  • P z is equal to P DU , P 1 or P 2 .
  • the priority of y is higher than that of x
  • the priority of x is higher than that of z.
  • the maximum transmit power or transmit power of z is determined as P total -pwr y -pwr x , and the transmit power pwr z of z is determined under this limit.
  • the principle of minimum guaranteed power is adopted to determine the transmission power of the DU and/or the transmission power of at least one cell group of the MT.
  • the first configured power includes Q DU and P DU
  • the second configured power includes Q 1 , Q 2 , P 1 and P 2
  • Q DU refers to all
  • P DU refers to the minimum guaranteed power configured for the DU
  • Q 1 refers to the transmit power or maximum transmit power configured for the MT primary cell group
  • Q 2 refers to the MT secondary cell group.
  • the transmit power or the maximum transmit power configured for the cell group, P 1 refers to the minimum guaranteed power configured for the MT primary cell group, and P 2 refers to the minimum guaranteed power configured for the MT secondary cell group;
  • Determining the transmit power of the DU and the transmit power of at least one cell group of the MT includes:
  • the transmission priority of the first unit y in the IAB node is higher than the transmission priority of the second unit x in the IAB node, and the transmission priority of the second unit x is higher than that in the IAB node
  • the transmission priority of the third unit z according to min ⁇ Q x ,P total -sum(pwr y )-sum(P z ) ⁇ , determine the transmission power or the actual maximum transmission power of the second unit;
  • the first unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the second unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the third unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node, and the first unit, the second unit and the third unit are different;
  • the pwr y represents the transmit power of the first unit
  • P z represents the minimum guaranteed power configured for the third unit
  • P z is equal to P DU , P 1 or P 2
  • Q x represents the configured power for the second unit Maximum transmit power or transmit power
  • Q x is Q DU , Q 1 or Q 2 .
  • the priority of y is higher than that of x
  • the priority of x is higher than that of z.
  • the maximum transmit power or transmit power of z is determined as min(Q z , P total -pwr x -pwr y ), and the transmit power pwr z of z is determined under this limit.
  • the transmission power or the actual maximum transmission power of the second unit may be determined in the following manner.
  • the transmission priority of the first unit y in the IAB node is higher than the transmission priority of the second unit x in the IAB node, and the transmission priority of the second unit x is higher than that of the first unit x in the IAB node
  • the transmission priority of the three-unit z and in the case of Q 1 +Q 2 >P cmax , according to min(P cmax -sum(pwr k )-sum(P s ), Q x , P total -sum( pwr y )–sum(P z )), determine the transmit power of the second unit or the actual maximum transmit power;
  • the first unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the second unit is a cell group in the MT
  • the third unit is the IAB node DU, MT secondary cell group or MT primary cell group, and the first unit, the second unit and the third unit are different;
  • the pwr y represents the transmit power of the first unit
  • P z represents the minimum guaranteed power configured for the third unit
  • P z is equal to P DU , P 1 or P 2
  • Q x represents the configured power for the second unit Maximum transmit power or transmit power
  • Q x is Q DU , Q 1 or Q 2
  • pwr k represents the transmit power of unit k in the MT, and the transmit priority of unit k is higher than the transmit priority of the second unit
  • P cmax is the maximum transmit power of the MT agreed in the protocol
  • P s represents the minimum guaranteed power configured for the s unit in the MT, and the transmit priority of the s unit is lower than that of the second unit.
  • the method further includes:
  • the upper limit of the power calculated by the PHR is assumed to be at least one of the following:
  • the MT when the PHR is reported, at least for the time of the power sharing, the MT may report one or more PHRs.
  • the maximum transmit power of the MT cell group is the theoretically achievable maximum transmit power (eg, P total , P cmax , Q MT , min(Q MT , P total -pwr DU ), P total -P DU , P total - pwr DU , min(Q MT , P total -P DU ), Q MCG , QSCG, Q MCG down or up or scaled value, Q SCG down or up or scaled value), actual max send Power (eg, the maximum transmit power of the MT excluding the transmit power occupied by the high-priority CG), and/or, the minimum guaranteed power value (P MT ).
  • P MT the theoretically achievable maximum transmit power
  • the MT when the PHR is reported, at least for the moment of the power sharing, the MT may report one or more PHRs.
  • the maximum transmit power of the MT cell group is the theoretically achievable maximum transmit power (for example, P total , P cmax , Q 1 or Q 2 ), the actual maximum transmit power (for example, excluding high-priority cells from the MT’s maximum transmit power The transmit power occupied by the group (CG), and/or the minimum guaranteed power excluding the low priority cell group), and/or the minimum guaranteed power value.
  • multiple PHRs may be reported at the same time, or different PHRs may be reported in different transmission conditions.
  • the minimum guaranteed power has the same meaning as the minimum guaranteed power in the existing minimum guaranteed power principle, and the actual maximum transmission power can be understood as the total transmission power minus the power of one of the units. Remaining power after transmit power.
  • the power acquisition method of the embodiment of the present application acquires the configured power; and determines the transmission power of the DU and/or the transmission power of at least one cell group of the MT according to the configured power and the transmission priority, thereby realizing at least one of the DU and the MT. Dynamic power sharing between cell groups improves the power efficiency of IAB transmission.
  • the execution subject may be a power acquisition apparatus, or a control module in the power acquisition apparatus for executing the power acquisition method.
  • the power acquisition device provided by the embodiment of the present application is described by taking the power acquisition method performed by the power acquisition device as an example.
  • an embodiment of the present application provides a power acquisition apparatus 400, which is applied to a node device and includes:
  • a first obtaining module 401 configured to obtain configuration power, where the configuration power includes at least one of a first configuration power and a second configuration power, and the first configuration power refers to a distributed unit DU that is a self-backhaul IAB node
  • a first determining module 402 configured to determine the transmission power of the DU and the transmission power of at least one cell group of the MT, wherein the transmission power of the DU and the transmission power of at least one cell group of the MT are among the At least one item of is determined according to the configuration power and transmission priority;
  • the sending priority includes at least one of: DU sending priority, MT sending priority, and MT sending priority of at least one cell group.
  • the power acquisition apparatus of the embodiment of the present application acquires the configured power; and determines the transmission power of the DU and/or the transmission power of at least one cell group of the MT according to the configured power and the transmission priority, thereby realizing at least one of the DU and the MT. Dynamic power sharing between cell groups improves the power efficiency of IAB transmission.
  • the first determination module includes:
  • a first determination submodule configured to determine the transmission power of the DU and the transmission power of the MT, wherein at least one of the transmission power of the DU and the transmission power of the MT is determined according to the configuration power and the transmission power of the MT.
  • Send priority is determined;
  • the second determination sub-module is configured to determine the transmission power of at least one cell group of the MT according to the transmission power of the MT or a preset power fixed value.
  • the first configured power is the transmit power or the maximum transmit power Q DU configured for the DU
  • the second configured power is the transmit power or the maximum transmit power configured for the MT QMT ;
  • the first determination sub-module is configured to determine the transmission of the DU according to the difference between the total power P total of the IAB node and the transmission power of the MT and Q DU when the transmission priority of the MT is higher than the transmission priority of the DU power;
  • the transmission power of the DU is determined, and the transmission power of the DU is less than or equal to Q DU .
  • the first configured power Q DU is the transmit power or the maximum transmit power configured for the DU
  • the second configured power Q MT is the transmit power or the maximum transmit power configured for the MT transmit power
  • the first determination submodule is configured to determine the transmission power of the MT when the transmission priority of the MT is higher than the transmission priority of the DU, and the transmission power of the MT is less than or equal to Q MT ;
  • the transmission power of the MT is determined according to the difference between the total power P total of the IAB node and the transmission power of the DU and Q MT .
  • the first configured power is a minimum guaranteed power P DU configured for the DU
  • the second configured power is a minimum guaranteed power P MT configured by the MT
  • the first determination submodule is used to determine the transmission power of the DU according to the first difference between the total power P total of the IAB node and the transmission power of the MT when the transmission priority of the MT is higher than the transmission priority of the DU ;
  • the transmission power of the DU is determined according to the second difference between the total power P total of the IAB node and the P MT.
  • the first configured power is a minimum guaranteed power P DU configured for the DU
  • the second configured power is a minimum guaranteed power P MT configured by the MT
  • the first determination submodule is configured to determine the transmission power of the MT according to the third difference between the total power P total of the IAB node and the P DU when the transmission priority of the MT is higher than the transmission priority of the DU;
  • the transmission power of the MT is determined according to the fourth difference between the total power P total of the IAB node and the transmission power of the DU.
  • the first determination submodule includes:
  • a first determining unit configured to determine the actual maximum transmit power of the MT
  • a second determining unit configured to determine the transmit power of the MT at least according to the actual maximum transmit power of the MT
  • Example embodiments of the present application power acquiring means said first means for determining the MT in the case where the presence of P cmax, select the value of the third difference and the P cmax smaller as the MT the actual maximum transmit power;
  • the smaller value of the fourth difference and the P cmax is selected as the actual maximum transmit power of the MT, and the P cmax is the agreement agreed or The maximum transmit power of the preconfigured MT.
  • the first configured power includes Q DU and/or P DU
  • the second configured power includes Q MT and/or P MT
  • Q DU refers to the configuration for the DU
  • P DU refers to the minimum guaranteed power configured for the DU
  • Q MT refers to the transmission power or maximum transmission power configured for the MT
  • P MT refers to the minimum guaranteed power configured for the MT. guaranteed power
  • the first determination sub-module is configured to determine the transmission of the DU according to the difference between the total power P total of the IAB node and the transmission power of the MT and Q DU when the transmission priority of the MT is higher than the transmission priority of the DU power;
  • the transmission power of the DU is determined according to the difference between the total power P total of the IAB node and P MT and Q DU .
  • the first configured power includes Q DU and/or P DU
  • the second configured power includes Q MT and/or P MT
  • Q DU refers to the configuration for the DU
  • P DU refers to the minimum guaranteed power configured for the DU
  • Q MT refers to the transmission power or maximum transmission power configured for the MT
  • P MT refers to the minimum guaranteed power configured for the MT. guaranteed power
  • the first determination submodule is configured to determine the transmission power of the MT according to the difference between the total power P total of the IAB node and the P DU and Q MT when the transmission priority of the MT is higher than the transmission priority of the DU;
  • the transmission power of the MT is determined according to the difference between the total power P total of the IAB node and the transmission power of the DU and Q MT .
  • the second configuration power includes the maximum transmission power Q MCG configured for the MT primary cell group and the maximum transmission power Q SCG configured for the MT secondary cell group;
  • the MT transmission power includes: The maximum transmission power configured by the MT, the maximum transmission power of the MT agreed in the protocol, or the actual maximum transmission power of the MT;
  • the second determination submodule is configured to obtain the maximum transmit power of the MT primary cell group and the maximum transmit power of the MT secondary cell group according to the Q MCG and the Q SCG and according to a preset power sharing rule;
  • the preset power sharing rule includes a first power sharing rule, a second power sharing rule and a third power sharing rule
  • the first power sharing rule refers to dynamic power sharing when the sum of Q MCG and Q SCG is greater than the target power
  • the second power sharing rule refers to semi-static power sharing when the sum of Q MCG and Q SCG is less than or equal to the target power
  • the third power sharing rule is to perform dynamic power sharing
  • the target power is the transmit power of the MT or a preset power fixed value.
  • the first determination module further includes: an adjustment sub-module, used for the second determination sub-module to acquire the maximum transmission power of the MT primary cell group and the maximum transmission power of the MT secondary cell group before the second determination sub-module acquires the maximum transmission power of the MT secondary cell group.
  • an adjustment sub-module used for the second determination sub-module to acquire the maximum transmission power of the MT primary cell group and the maximum transmission power of the MT secondary cell group before the second determination sub-module acquires the maximum transmission power of the MT secondary cell group.
  • the first configured power is Q DU
  • Q DU refers to the transmit power or the maximum transmit power configured for the DU
  • the second configured power includes Q 1 and Q 2
  • Q 1 refers to the configured transmit power or maximum transmit power for the MT primary cell group
  • Q 2 refers to the configured transmit power or maximum transmit power for the MT secondary cell group
  • the first determining module is configured to, in the case that the sending priority of the first unit y in the IAB node is higher than the sending priority of the second unit x in the IAB node, according to min(Q x , P total -sum(pwr y )), to determine the transmit power or the actual maximum transmit power of the second unit;
  • the first unit is at least one of the DU, the MT secondary cell group and the MT primary cell group in the IAB node, and the second unit includes the DU, the MT secondary cell group or the MT primary cell group, and the first unit is different from the second unit;
  • Q x represents the maximum transmit power or transmit power configured for the second unit
  • Q x is Q DU , Q 1 or Q 2
  • pwr y represents the transmit power of the first unit
  • P total is the total power of the IAB node .
  • Q DU +Q 1 +Q 2 >P total .
  • the first configured power includes Q DU
  • Q DU refers to the transmit power or the maximum transmit power configured for the DU
  • the second configured power includes Q 1 and Q 2
  • Q 1 refers to the configured transmit power or maximum transmit power for the MT primary cell group
  • Q 2 refers to the configured transmit power or maximum transmit power for the MT secondary cell group
  • the first determining module is used in the case where the sending priority of the first unit y in the IAB node is higher than the sending priority of the second unit x in the IAB node, and Q 1 +Q 2 >P cmax Next, according to min(P cmax -sum(pwr k ), Q x , P total -sum(pwr y )), determine the transmit power or the actual maximum transmit power of the second unit;
  • the first unit is at least one of the DU, the MT secondary cell group and the MT primary cell group in the IAB node
  • the second unit is a cell group in the MT
  • the first unit and the The second unit is different
  • pwr k represents the transmit power of the k unit in the MT, and the transmit priority of the k unit is higher than that of the second unit
  • P cmax is the maximum transmit power of the MT agreed in the protocol
  • Q x represents the maximum transmit power or transmit power configured for the second unit
  • Q x is Q DU , Q 1 or Q 2
  • pwr y represents the transmit power of the first unit.
  • the first configured power includes P DU
  • the second configured power includes P 1 and P 2
  • the P DU refers to the minimum guaranteed power configured for the DU
  • the P 1 refers to the minimum guaranteed power configured for the MT primary cell group
  • the P 2 refers to the minimum guaranteed power configured for the MT secondary cell group
  • the first determining module is used for the sending priority of the first unit y in the IAB node is higher than the sending priority of the second unit x in the IAB node, and the sending priority of the second unit x
  • the transmission power or the actual maximum transmission power of the second unit is determined according to P total -sum(pwr y )-sum(P z ) ;
  • the first unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the second unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the third unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node, and the first unit, the second unit and the third unit are different;
  • the pwr y represents the transmit power of the first unit
  • P z represents the minimum guaranteed power configured for the third unit
  • P z is equal to P DU , P 1 or P 2 .
  • the first configured power includes Q DU and P DU
  • the second configured power includes Q 1 , Q 2 , P 1 and P 2
  • Q DU refers to the The transmit power or the maximum transmit power configured for the DU
  • the P DU refers to the minimum guaranteed power configured for the DU
  • Q 1 refers to the transmit power or the maximum transmit power configured for the MT primary cell group
  • Q 2 refers to the MT secondary cell
  • the transmit power or the maximum transmit power configured by the group P 1 refers to the minimum guaranteed power configured for the MT primary cell group
  • P 2 refers to the minimum guaranteed power configured for the MT secondary cell group
  • the first determining module is used for the sending priority of the first unit y in the IAB node is higher than the sending priority of the second unit x in the IAB node, and the sending priority of the second unit x In the case that the sending priority of the third unit z in the IAB node is higher than that of the third unit z in the IAB node, according to min ⁇ Q x ,P total -sum(pwr y )-sum(P z ) ⁇ , determine the sending of the second unit power or actual maximum transmit power;
  • the first unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the second unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the third unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node, and the first unit, the second unit and the third unit are different;
  • the pwr y represents the transmit power of the first unit
  • P z represents the minimum guaranteed power configured for the third unit
  • P z is equal to P DU , P 1 or P 2
  • Q x represents the configured power for the second unit Maximum transmit power or transmit power
  • Q x is Q DU , Q 1 or Q 2 .
  • the first configured power includes Q DU and P DU
  • the second configured power includes Q 1 , Q 2 , P 1 and P 2
  • Q DU refers to the The transmit power or the maximum transmit power configured for the DU
  • the P DU refers to the minimum guaranteed power configured for the DU
  • Q 1 refers to the transmit power or the maximum transmit power configured for the MT primary cell group
  • Q 2 refers to the MT secondary cell
  • the transmit power or the maximum transmit power configured by the group P 1 refers to the minimum guaranteed power configured for the MT primary cell group
  • P 2 refers to the minimum guaranteed power configured for the MT secondary cell group
  • the first determining module is used for the sending priority of the first unit y in the IAB node to be higher than the sending priority of the second unit x in the IAB node, and the sending priority of the second unit x is higher In the case of the transmission priority of the third unit z in the IAB node, and in the case of Q 1 +Q 2 >P cmax , according to min(P cmax -sum(pwr k )-sum(P s ), Q x , P total -sum(pwr y )-sum(P z )), determine the transmit power or the actual maximum transmit power of the second unit;
  • the first unit is the DU, the MT secondary cell group or the MT primary cell group in the IAB node
  • the second unit is a cell group in the MT
  • the third unit is the IAB node DU, MT secondary cell group or MT primary cell group, and the first unit, the second unit and the third unit are different;
  • the pwr y represents the transmit power of the first unit
  • P z represents the minimum guaranteed power configured for the third unit
  • P z is equal to P DU , P 1 or P 2
  • Q x represents the configured power for the second unit Maximum transmit power or transmit power
  • Q x is Q DU , Q 1 or Q 2
  • pwr k represents the transmit power of unit k in the MT, and the transmit priority of unit k is higher than the transmit priority of the second unit
  • P cmax is the maximum transmit power of the MT agreed in the protocol
  • P s represents the minimum guaranteed power configured for the s unit in the MT, and the transmit priority of the s unit is lower than that of the second unit.
  • a reporting module configured to report at least one power headroom report PHR after the first determining module determines the transmission power of the DU and the transmission power of at least one cell group of the MT;
  • the upper limit of the power calculated by the PHR is assumed to be at least one of the following:
  • the transmission priority is determined in at least one of the following ways:
  • the transmission priority of the physical layer is the transmission priority of the physical layer.
  • the power acquisition apparatus of the embodiment of the present application acquires the configured power; and determines the transmission power of the DU and/or the transmission power of at least one cell group of the MT according to the configured power and the transmission priority, thereby realizing at least one of the DU and the MT. Dynamic power sharing between cell groups improves the power efficiency of IAB transmission.
  • the power acquisition apparatus in this embodiment of the present application may be an apparatus, or may be a component, an integrated circuit, or a chip in a node device.
  • the power acquisition apparatus provided in the embodiments of the present application can implement each process implemented by the method embodiments in FIG. 1 to FIG. 3 , and achieve the same technical effect. To avoid repetition, details are not repeated here.
  • an embodiment of the present application further provides a node device 500 .
  • the node device includes a processor 501 , a memory 502 , and a program stored in the memory 502 and running on the processor 501 . or instruction, when the program or instruction is executed by the processor 501, each process of the above power acquisition method embodiment can be implemented, and the same technical effect can be achieved. To avoid repetition, details are not repeated here.
  • an embodiment of the present application further provides a node device.
  • the node device 600 includes: an antenna 601 , a radio frequency device 602 , and a baseband device 603 .
  • the antenna 601 is connected to the radio frequency device 602 .
  • the radio frequency device 602 receives information through the antenna 601, and sends the received information to the baseband device 603 for processing.
  • the baseband device 603 processes the information to be sent and sends it to the radio frequency device 602
  • the radio frequency device 602 processes the received information and sends it out through the antenna 601 .
  • the above-mentioned frequency band processing apparatus may be located in the baseband apparatus 603 , and the method performed by the node device in the above embodiment may be implemented in the baseband apparatus 603 .
  • the baseband apparatus 603 includes a processor 604 and a memory 605 .
  • the baseband device 603 may include, for example, at least one baseband board on which multiple chips are arranged. As shown in FIG. 6 , one of the chips is, for example, the processor 604, which is connected to the memory 605 to call the program in the memory 605 to execute The operations shown in the above method embodiments.
  • the baseband device 603 may further include a network interface 606 for exchanging information with the radio frequency device 602, the interface being, for example, a common public radio interface (CPRI).
  • CPRI common public radio interface
  • the node device in the embodiment of the present invention further includes: instructions or programs stored in the memory 605 and executable on the processor 604, and the processor 604 invokes the instructions or programs in the memory 605 to execute the modules shown in FIG. 4 to execute method, and achieve the same technical effect, in order to avoid repetition, it is not repeated here.
  • Embodiments of the present application further provide a readable storage medium, where a program or an instruction is stored on the readable storage medium, and when the program or instruction is executed by a processor, each process of the foregoing power acquisition method embodiment can be achieved, and can achieve the same In order to avoid repetition, the technical effect will not be repeated here.
  • the processor is the processor in the node device in the foregoing embodiment.
  • the readable storage medium includes a computer-readable storage medium, such as a computer read-only memory (Read-Only Memory, ROM), a random access memory (Random Access Memory, RAM), a magnetic disk or an optical disk, and the like.
  • An embodiment of the present application further provides a chip, where the chip includes a processor and a communication interface, the communication interface is coupled to the processor, and the processor is used to run a node device program or instruction to implement the above power acquisition method In order to avoid repetition, the details are not repeated here.
  • the chip mentioned in the embodiments of the present application may also be referred to as a system-on-chip, a system-on-chip, a system-on-chip, or a system-on-a-chip, or the like.

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Abstract

本申请公开了一种功率获取方法、装置及节点设备,属于通信技术领域。本申请的功率获取方法包括:获取配置功率,所述配置功率包括第一配置功率和第二配置功率中的至少一项,所述第一配置功率是指为自回传IAB节点的分布单元DU配置的功率,所述第二配置功率包括为所述IAB节点中MT配置的功率和为所述MT至少一个小区组配置的功率,或者,所述第二配置功率包括为所述MT至少一个小区组配置的功率;确定所述DU的发送功率和所述MT至少一个小区组的发送功率,DU的发送功率和所述MT至少一个小区组的发送功率中的至少一项是根据配置功率和发送优先级确定的。

Description

功率获取方法、装置及节点设备
相关申请的交叉引用
本申请主张在2020年7月24日在中国提交的中国专利申请号No.202010724901.0的优先权,其全部内容通过引用包含于此。
技术领域
本发明涉及通信技术领域,特别涉及一种功率获取方法、装置及节点设备。
背景技术
在自回传(Integrated Access Backhaul,IAB)技术中,IAB节点的分布单元(Distributed Unit,DU)和移动终端(Mobile Termination,MT)可以进行同时发送。另外,IAB节点可以连接多个父IAB(parent IAB)节点,并同时向多个parent IAB节点发送信息(例如,IAB MT进行双链接)。考虑到IAB节点的硬件限制,IAB节点的DU、MT主小区组(Master Cell Group,MCG)和MT辅小区组(Secondary Cell Group,SCG)同时发送时,DU,MT MCG和MT SCG之间需要共享总发射功率,但相关技术的功率共享方案中,并未考虑MT存在多连接的情况,因此,相关技术中并不存在MT MCG链路,MT SCG链路和DU间进行功率共享的方案。
发明内容
本申请实施例的目的是提供一种功率获取方法、装置及节点设备,能够解决DU和MT至少一个小区组如何进行功率共享的问题。
为了解决上述技术问题,本申请是这样实现的:
第一方面,提供了一种功率获取方法,应用于节点设备,包括:
获取配置功率,所述配置功率包括第一配置功率和第二配置功率中的至少一项,所述第一配置功率是指为自回传IAB节点的分布单元DU配置的功率,所述第二配置功率包括所述IAB节点中MT的配置的功率和为所述MT 至少一个小区组配置的功率,或者,所述第二配置功率包括为所述MT至少一个小区组配置的功率;
确定所述DU的发送功率和所述MT至少一项小区组的发送功率,其中,所述DU的发送功率和所述MT至少一个小区组的发送功率中的至少一项是根据所述配置功率和发送优先级确定的;
其中,所述发送优先级包括:DU的发送优先级、MT的发送优先级和MT至少一个小区组的发送优先级中的至少一项。
第二方面,提供了一种功率获取装置,应用于节点设备,包括:
第一获取模块,用于获取配置功率,所述配置功率包括第一配置功率和第二配置功率中的至少一项,所述第一配置功率是指为自回传IAB节点的分布单元DU配置的功率,所述第二配置功率包括所述IAB节点中MT的配置的功率和为所述MT至少一个小区组配置的功率,或者,所述第二配置功率包括为所述MT至少一个小区组配置的功率;
第一确定模块,用于确定所述DU的发送功率和所述MT至少一项小区组的发送功率,其中,所述DU的发送功率和所述MT至少一个小区组的发送功率中的至少一项是根据所述配置功率和发送优先级确定的;
其中,所述发送优先级包括:DU的发送优先级、MT的发送优先级和MT至少一个小区组的发送优先级中的至少一项。
第三方面,提供了一种节点设备,该终端包括处理器、存储器及存储在所述存储器上并可在所述处理器上运行的程序或指令,所述程序或指令被所述处理器执行时实现如第一方面所述的方法的步骤。
第四方面,提供了一种可读存储介质,所述可读存储介质上存储程序或指令,所述程序或指令被处理器执行时实现如第一方面所述的方法的步骤。
第五方面,提供了一种芯片,所述芯片包括处理器和通信接口,所述通信接口和所述处理器耦合,所述处理器用于运行网络侧设备程序或指令,实现如第一方面所述的方法。
在本申请实施例中,获取配置功率;根据所述配置功率和发送优先级, 确定所述DU的发送功率和/或MT至少一个小区组的发送功率,从而实现了DU和MT至少一个小区组之间的动态功率共享,提高了IAB传输的功率效率。
附图说明
图1为IAB系统的结构示意图;
图2表示IAB系统的CU-DU结构示意图;
图3表示本申请实施例的功率获取方法的流程示意图;
图4表示本申请实施例的功率获取装置的模块示意图;
图5表示本申请实施例的节点设备的结构框图之一;
图6表示本申请实施例的节点设备的结构框图之二。
具体实施方式
下面将结合本申请实施例中的附图,对本申请实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例是本申请一部分实施例,而不是全部的实施例。基于本申请中的实施例,本领域普通技术人员在没有作出创造性劳动前提下所获得的所有其他实施例,都属于本申请保护的范围。
本申请的说明书和权利要求书中的术语“第一”、“第二”等是用于区别类似的对象,而不用于描述特定的顺序或先后次序。应该理解这样使用的数据在适当情况下可以互换,以便本申请的实施例能够以除了在这里图示或描述的那些以外的顺序实施,且“第一”、“第二”所区别的对象通常为一类,并不限定对象的个数,例如第一对象可以是一个,也可以是多个。此外,说明书以及权利要求中“和/或”表示所连接对象的至少其中之一,字符“/”一般表示前后关联对象是一种“或”的关系。
值得指出的是,本申请实施例所描述的技术不限于长期演进型(Long Term Evolution,LTE)/LTE的演进(LTE-Advanced,LTE-A)系统,还可用于其他无线通信系统,诸如码分多址(Code Division Multiple Access,CDMA)、 时分多址(Time Division Multiple Access,TDMA)、频分多址(Frequency Division Multiple Access,FDMA)、正交频分多址(Orthogonal Frequency Division Multiple Access,OFDMA)、单载波频分多址(Single-carrier Frequency-Division Multiple Access,SC-FDMA)和其他系统。本申请实施例中的术语“系统”和“网络”常被可互换地使用,所描述的技术既可用于以上提及的系统和无线电技术,也可用于其他系统和无线电技术。然而,以下描述出于示例目的描述了新空口(New Radio,NR)系统,并且在以下大部分描述中使用NR术语,尽管这些技术也可应用于NR系统应用以外的应用,如第6代(6 th Generation,6G)通信系统。
为使本领域技术人员能够更好地理解本发明,先对IAB系统进行以下说明。
自回传(integrated access backhaul,IAB)系统是NR Rel-16开始制定标准的一项技术。图1显示了一个IAB系统示意图。一个IAB节点包括分布单元(Distributed Unit,DU)功能部分和移动终端(Mobile Termination,MT)功能部分。依靠MT,一个接入点(即IAB node)11可以找到一个上游接入点(parent IAB node,父节点)12,并跟上游接入点的DU建立无线连接,该无线连接被称为回传链路(backhaul link)。在一个IAB节点建立完整的回传链路后,该IAB节点打开其DU功能,DU会提供小区服务,即DU可以为UE提供接入服务。一个自回传回路包含一个宿主(donor)IAB节点13,donor IAB节点有直接相连的有线传输网。
图2是一个IAB系统的中央单元-分布单元(Centralized Unit-Distributed Unit,CU-DU)结构图。CU也可以称为控制单元。在一个自回传回路中,所有的IAB节点的DU都连接到一个CU节点,由这一个节点通过F1-AP协议进行对DU进行配置。CU通过RRC协议,对MT进行配置。Donor IAB节点没有MT功能部分。
IAB系统的引入是为了解决接入点密集部署时,有线传输网部署不到位的情况。即在没有有线传输网络时,接入点可以依赖无线回传。
下面结合附图,通过具体的实施例及其应用场景对本申请实施例提供的功率获取方法进行详细地说明。
如图3所示,本申请实施例提供了一种功率获取方法,应用于节点设备,该节点设备具体为IAB节点,该方法包括:
获取配置功率,所述配置功率包括第一配置功率和第二配置功率中的至少一项,所述第一配置功率是指为自回传IAB节点的分布单元DU配置的功率,所述第二配置功率包括所述IAB节点中MT的配置的功率和为所述MT至少一个小区组配置的功率,或者,所述第二配置功率包括为所述MT至少一个小区组配置的功率;
确定所述DU的发送功率和所述MT至少一项小区组的发送功率,其中,所述DU的发送功率和所述MT至少一个小区组的发送功率中的至少一项是根据所述配置功率和发送优先级确定的;
其中,所述发送优先级包括:DU的发送优先级、MT的发送优先级和MT至少一个小区组的发送优先级中的至少一项。
上述发送优先级是通过以下至少一种方式确定的:
协议约定、网络配置、物理层的传输优先级。
例如,协议约定或网络配置DU和MT间的发送优先级;或协议约定或网络配置DU,MT MCG和MT SCG间的发送优先级;特别的,协议约定DU的优先级高于MT的任一小区组的发送优先级。再例如协议约定基于DU和MT传输的物理信道类型确定DU和MT小区组的发送优先级。再例如协议约定基于DU和MT传输的业务类型确定DU和MT小区组的发送优先级。再例如,优先发送DCI指示的优先级高的物理层的传输。
另外,网络配置是指通过高层信令配置,例如RRC或F1-C配置。
本申请实施例的功率获取方法,获取配置功率;根据所述配置功率和发送优先级,确定所述DU的发送功率和/或MT至少一个小区组的发送功率,从而实现了DU和MT至少一个小区组之间的动态功率共享,提高了IAB传输的功率效率。
作为第一种可选的方案,确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
确定所述DU的发送功率和MT的发送功率,其中,所述DU的发送功率和所述MT的发送功率中的至少一项是根据所述配置功率和所述发送优先级确定的;
根据所述MT的发送功率或预设功率固定值,确定MT至少一个小区组的发送功率。
该方案中,首先,DU和MT之间进行动态功率分配,如按照最大功率原则和最小保证功率原则中的至少一项进行动态功率分配。然后,MT的至少一个小区组之间采用传统的功率共享方式。如采用半静态功率分配方式或采用动态动力分配方式。
作为第一种可选的实现方式,所述第一配置功率包括Q DU,Q DU是为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q MT,Q MT是为所述MT配置的发送功率或最大发送功率。可选的,Q DU+Q MT>P total,P total为所述IAB节点的总功率,或者,P total为IAB节点发射机输出的最大功率,或者,P total为DU和MT可支持的总发送功率。
所述确定所述DU的发送功率,包括:
在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,确定DU的发送功率,所述DU的发送功率小于或者等于Q DU
具体的,在MT的发送优先级高于DU的发送优先级的情况下,确定MT的发送功率,所述MT的发送功率小于或者等于Q MT,根据所述P total与所述MT的发送功率的差值和Q DU中较小的值,确定DU的发送功率。
这里,先确定MT的发送功率pwr MT,pwr MT≤Q MT,然后根据min(Q DU,P total-pwr MT),确定DU的发送功率。
所述确定MT的发送功率,包括:
在MT的发送优先级高于DU的发送优先级的情况下,确定MT的发送功率,所述MT的发送功率小于或者等于Q MT
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。
具体的,在DU的发送优先级高于MT的发送优先级的情况下,先确定DU的发送功率,所述DU的发送功率小于或者等于Q DU;根据所述P total与所述DU的发送功率的差值和所述Q MT,确定MT的发送功率。
这里,先确定DU的发送功率pwr DU,pwr DU≤Q DU,然后根据min(Q MT,P total–pwr DU),确定DU的发送功率。上述第一种可选的实现方式,按照最大功率原则,确定MT的发送功率和/或DU的发送功率。
作为第二种可选的实现方式,所述第一配置功率是为所述DU配置的最小保证功率P DU,所述第二配置功率为所述MT配置的最小保证功率P MT,可选的,P DU+P MT≤P total
所述确定所述DU的发送功率,包括:
在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的第一差值,确定DU的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与P MT的第二差值,确定DU的发送功率。
具体的,在MT的发送优先级高于DU的发送优先级的情况下,根据所述IAB节点的总功率与P DU的第一差值,确定MT的最大发送功率;至少根据MT的最大发送功率,确定MT的发送功率;根据IAB节点的总功率与MT的发送功率的第二差值,确定DU的发送功率。
其中,上述确定DU的发送功率包括以下两种方式:
方式一:直接确定DU的发送功率;
方式二:先确定DU的最大发送功率,根据DU的最大发送功率和DU调度的下行传输,确定DU的发送功率。
例如,先根据DU的最小保证功率P DU,确定MT的最大发送功率P total- P DU,再根据调度的MT传输和功率控制算法确定MT上行传输所需的功率pwr MT(MT的发送功率),当pwr MT>P total-P DU时,pwr MT设置为P total-P DU;然后确定Du的最大发送功率为P total-pwr MT;接着,根据DU调度的下行传输,确定DU的发送功率pwr DU,当pwr DU大于P total-pwr MT时,pwr DU设置为P total-pwr MT
所述确定MT的发送功率,包括:
在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与P DU的第三差值,确定MT的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的第四差值,确定MT的发送功率。
具体的,在DU的发送优先级高于MT的发送优先级的情况下,先根据所述IAB节点的总功率与P MT的差值,确定DU的发送功率,然后根据IAB节点的总功率P total与DU的发送功率的第四差值,确定MT的最大发送功率,至少根据MT的最大发送功率,确定MT的发送功率。
这里,可先确定DU的最大发送功率为P total-P MT,再根据给DU调度的下行传输确定DU的发送功率pwr DU,当pwr DU大于P total-P MT,pwr DU设置为P total-P MT;然后确定MT的最大发送功率为P total-pwr DU,接着根据给MT调度的上行传输,确定MT所需的上行传输功率pwr MT(MT的发送功率),当pwr MT大于P total-pwr DU时,pwr MT设置为P total-pwr DU
进一步地,所述确定MT的发送功率,包括:
确定MT的实际最大发送功率;
至少根据所述MT的实际最大发送功率,确定MT的发送功率;
进一步可选的,所述确定MT的实际最大发送功率,包括:
在所述MT存在P cmax的情况下,选取所述第三差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率。
在MT有一个P cmax时,MT的最大发送功率为min(P cmax,P total-P DU),即当MT的所需发送功率大于min(P cmax,P total-P DU)时,使用的发送功率为 min(P cmax,P total-P DU)。
或者,在所述MT存在P cmax的情况下,选取所述第四差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率,所述P cmax为协议约定的或预配置的MT的最大发送功率。
当MT有一个P cmax时,MT的最大发送功率为min(P cmax,P total-pwr DU),即当MT的所需发送功率大于min(P cmax,P total-pwr DU)时,使用的发送功率为min(P cmax,P total-pwr DU)。
上述第二种可选的实现方式,按照最小保证功率原则,确定MT的发送功率和/或DU的发送功率。
作为第三种可选的实现方式,所述第一配置功率包括Q DU和/或P DU,所述第二配置功率包括Q MT和/或P MT,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为所述DU配置的最小保证功率;Q MT是指为所述MT配置的发送功率或最大发送功率,P MT是指为所述MT配置的最小保证功率;所述确定所述DU的发送功率,包括:
在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与P MT的差值以及Q DU,确定DU的发送功率。
具体的,在MT的发送优先级高于DU的发送优先级的情况下,可以先根据IAB节点的总功率P total与P DU的差值与Q MT,MT的最大发送功率;至少根据MT的最大发送功率,确定MT的发送功率,然后根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率。
这里,先根据DU的最小保证功率P DU和Q MT,确定MT的最大发送功率为min(Q MT,P total-P DU),再根据给MT调度的上行传输和功率控制参数,确定MT所需的上行传输功率pwr MT(MT的发送功率),当pwr MT大于min(Q MT,P total-PDU)时,pwr MT设置为min(Q MTP total-P DU);然后确定DU的发送功率为min(Q DU,P total-pwr MT)。
可选的,在DU的发送优先级高于MT的发送优先级的情况下,选取IAB节点的总功率P total与P MT的差值和Q DU中的较小值,作为DU的最大发送功率;至少根据DU的最大发送功率,确定DU的发送功率。
这里,先根据MT的最小保证功率P MT和Q DU,确定DU的最大发送功率为min(Q DU,P total-P MT),再根据给DU调度的下行传输和功率控制参数,确定DU所需的下行传输功率pwr DU(DU的发送功率),当pwr DU大于min(Q DU,P total-P MT)时,pwr DU设置为min(Q DU,P total-P MT)。
所述确定MT的发送功率,包括:
在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与P DU的差值以及Q MT,确定MT的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。具体的,在MT的发送优先级高于DU的发送优先级的情况下,选取根据IAB节点的总功率P total与P DU的差值与Q MT中较小的值,作为MT的最大发送功率,至少根据MT的最大发送功率,确定MT的发送功率。
这里,先根据DU的最小保证功率P DU和Q MT,确定MT的最大发送功率为min(Q MT,P total-P DU),再根据给MT调度的上行传输和功率控制参数,确定MT所需的上行传输功率pwr MT(MT的发送功率),当pwr MT大于min(Q MT,P total-PDU)时,pwr MT设置为min(Q MTP total-P DU)。
可选的,在DU的发送优先级高于MT的发送优先级的情况下,先选取根据IAB节点的总功率P total与P MT的差值以及Q DU中较小的值,作为DU的最大发送功率;至少根据DU的最大发送功率,确定DU的发送功率;然后根据P total与DU的发送功率的差值和Q MT,确定MT的发送功率。
这里,先根据MT的最小保证功率P MT和Q DU,确定DU的最大发送功率为min(Q DU,P total-P MT),再根据给DU调度的下行传输和功率控制参数,确定DU所需的下行传输功率pwr DU(DU的发送功率),当pwr DU大于min(Q DU,P total-P MT)时,pwr DU设置为min(Q DU,P total-P MT);然后确定MT的 发送功率为min(Q MT,P total-pwr DU)。
这里,采用最大功率原则与最小保证功率原则相结合的方式,确定所述DU的发送功率和/或MT的发送功率。
可选地,当网络给MT配置的Q MT大于预配置的P cmax时,MT的最大发送功率可以大于P cmax,即MT在确定最大发送功率时,通过专用信令配置的最大功率值可以覆盖预定的最大功率值。
可选地,当网络给DU配置的Q DU大于预配置的P 0时,DU的最大发送功率可以大于P 0,即DU在确定最大发送功率时,通过专用信令配置的最大功率值可以覆盖预定的最大功率值。其中,P 0可以是RAN4规定的DU的最大发送功率。
上述第一种可选的方案中,所述第二配置功率包括为MT主小区组配置的最大发送功率Q MCG和为MT辅小区组配置的最大发送功率Q SCG;所述MT的发送功率包括为MT配置的最大发送功率、协议约定的MT的最大发送功率或MT的实际最大发送功率;
根据MT的发送功率或预设功率固定值,确定MT至少一个小区组的发送功率,包括:
根据所述Q MCG和Q SCG,按照预设功率共享规则,获取MT主小区组的最大发送功率和MT辅小区组的最大发送功率;
其中,所述预设功率共享规则包括第一功率共享规则、第二功率共享规则和第三功率共享规则;
所述第一功率共享规则是指在Q MCG与Q SCG之和大于目标功率的情况下,进行动态功率共享;
所述第二功率共享规则是指在Q MCG与Q SCG之和小于或者等于目标功率的情况下,进行半静态功率共享;
所述第三功率共享规则是进行动态功率共享;
其中,所述目标功率为MT的发送功率或预设功率固定值。
下面对双链接(Dual Connectivity,DC)下MCG和SCG的功率共享进 行以下说明。
如果UE处于双链接状态,其发送功率可以在MCG链路和SCG链路之间共享。MCG链路和SCG链路间的功率共享可以分为半静态和动态的功率共享。
对于半静态的功率共享,MCG链路和SCG链路所配置的最大上行发送功率之和小于或等于UE的总发送功率,MCG和SCG在做功控的时候分别受限于其配置的最大发送功率。对于NR-NR的双链接,MCG链路和SCG链路配置的最大发送功率只适用于MCG链路和SCG链路存在同时发送的时刻。
对于动态功率共享,LTE DC采用的是最小保证功率的原则,MCG链路和SCG链路各自配置有一个最小保证发送功率且两者之和小或等于UE的最大发送功率,而MCG链路和SCG链路可以分享剩余功率部分(即总功率减去MCG链路和SCG链路的最小保证发送功率之和的剩余功率)。NR-NR DC采用的是最大功率的原则,MCG链路和SCG链路各自配置有一个最大发送功率且两者之和可以大于UE的最大发送功率。当同时发送的MCG链路和SCG链路所需的功率之和大于UE的最大发送功率时,UE需优先给MCG链路分配发送功率,保证MCG link的发送,但是,MCG link的发送功率仍受限于配置的最大发送功率,SCG链路的发送功率受限于为其配置的最大发送功率和剩余发送功率的较小者(即总功率减去MCG链路的发送功率)。
进一步可选的,获取MT主小区组的最大发送功率和MT辅小区组的最大发送功率之前,还包括:
在预设功率固定值与MT的发送功率不同的情况下,根据预设功率固定值与MT的发送功率的差值,对Q MCG和Q SCG中的至少一项进行调整。
在本申请实施例中,MT小区组间的总发送功率Q MCG+Q SCG受限于MT的最大发送功率(P cmax或Q MT)或受限于协议约定或配置的预设功率固定值P fixed(P fixed=P cmax或P total)。其中,P cmax为协议规定的MT的最大发送功率,P total为配置的MT的最大发送功率。
在预设功率固定值与MT的最大发送功率不同的情况下,作为一种可选 的实现方式,对Q MCG或Q SCG均进行调整。例如,预设功率固定值与MT的最大发送功率的差值为10瓦,即预设功率固定值比MT的最大发送功率值大10瓦,则将Q MCG减少10瓦,或,将Q SCG减少10瓦。又例如,预设功率固定值与MT的最大发送功率的差值为-10瓦,即预设功率固定值比MT的最大发送功率值小10瓦,则将Q MCG增加10瓦,或,将Q SCG增加10瓦,也即是说,Q MCG或Q SCG均的调整值与上述差值相同。
在预设功率固定值与MT的最大发送功率不同的情况下,作为另一种可选的实现方式,对Q MCG和Q SCG均进行调整。具体的,根据预设功率固定值与MT的最大发送功率的差值,按照第一调整比例对Q MCG进行调整,按照第二调整比例对Q SCG进行调整。该第一调整比例和第二调整比例可以相同,也可以不同。可选的,第一调整比例和第二调整比例之和为1,例如,两个调整比例分别为0.5,也就是说,Q MCG和Q SCG平分上述差值;可选的,上述第一调整比例和第二调整比例根据上述差值确定。例如,预设功率固定值相对于MT的最大发送功率增长了10%,则确定上述第一调整比例和第二调整比例均为10%,即Q MCG和Q SCG均增加10%。
另外,在不存在MT的MCG和SCG同时发送的情况时,MCG和SCG的最大功率受限于MT的最大发送功率。
作为第二种可选的方案,本申请实施例中,直接确定所述DU的发送功率和所述MT至少一项小区组的发送功率。
这里,DU和MT的至少一个小区组之间进行动态功率分配,具体的,按照最大功率原则和最小保证功率原则中的至少一个,确定DU的发送功率和/或所述MT至少一个小区组的发送功率。例如,确定DU的发送功率、MT主小区组的发送功率和MT辅小区组的发送功率。
在该第二种可选的方案中,作为第一种可选的实现方式,所述第一配置功率为Q DU,Q DU是指为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q 1和Q 2,Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为所述MT辅小区组的配置发送功率或最大发送功率,可选的, Q DU+Q 1+Q 2>P total,P total为所述IAB节点的总功率。
确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级的情况下,根据min(Q x,P total-sum(pwr y)),确定所述第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,所述第二单元包括所述DU、MT辅小区组或MT主小区组,且所述第一单元与所述第二单元不同;
Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率,P total为所述IAB节点的总功率。
例如,第一单元y为DU,第二单元x为MT主小区组,另外MT辅小区组的发送优先级低于MT主小区组的发送优先级。则MT主小区组的发送功率为min(Q 1,P-sum(pwr DU))。即先确定DU的发送功率,然后再根据Q 1和P-sum(pwr DU),确定MT主小区组的发送功率。
又例如,第一单元为DU和MT主小区组,第二单元为MT辅小区组,则先确定DU的发送功率pwr DU和MT主小区组的发送功率pwr MCG,最后根据min(Q 2,P-sum(pwr DU+pwr MCG)),确定MT辅小区组的发送功率。
这里,采用最大功率原则,确定所述DU的发送功率和/或所述MT至少一个小区组的发送功率。
另外,当Q 1+Q 2>P cmax时,可以采用以下方式确定所述DU的发送功率和/或所述MT至少一个小区组的发送功率。
在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且Q 1+Q 2>P cmax的情况下,根据min(P cmax–sum(pwr k),Q x,P total-sum(pwr y)),确定第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,第二单元为MT中的一个小区组,且所述第一单元与所述第二单元不同;pwr k表示MT中的k单元的发送功率,且k单元的发送优 先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率。
第二种可选的实现方式,所述第一配置功率包括P DU,所述第二配置功率包括P 1和P 2,所述P DU是指为所述DU配置的最小保证功率,所述P 1是指为MT主小区组配置的最小保证功率,所述P 2是指为所述MT辅小区组配置的最小保证功率,可选的,P DU+P 1+P 2≤P total,P total为所述IAB节点的总功率;
确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据P total–sum(pwr y)–sum(P z),确定所述第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2
假设x,y,z分别对应MT主小区组,MT辅小区组和DU,y的优先级高于x,x的优先级高于z。
先确定y的最大发送功率或发送功率为P total-P x-P z,在此限制下确定y的发送功率pwr y
再确定x的最大发送功率或发送功率为P total–pwr y-P z,在此限制下确定x的发送功率pwr x
最后确定z的最大发送功率或发送功率为P total–pwr y-pwr x,在此限制下确定z的发送功率pwr z
这里,采用最小保证功率原则,确定所述DU的发送功率和/或所述MT 至少一个小区组的发送功率。
作为第三种可选的实现方式,所述第一配置功率包括Q DU和P DU,所述第二配置功率包括Q 1、Q 2、P 1和P 2,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为DU配置的最小保证功率;Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为所述MT辅小区组配置的发送功率或最大发送功率,P 1是指为MT主小区组配置的最小保证功率,P 2是指为所述MT辅小区组配置的最小保证功率;
确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据min{Q x,P total–sum(pwr y)–sum(P z)},确定所述第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2
假设x,y,z分别对应MT主小区组,MT辅小区组和DU,y的优先级高于x,x的优先级高于z。
先确定y的最大发送功率或发送功率为min(Q y,P total-P x-P z),在此限制下确定y的发送功率pwr y
再确定x的最大发送功率或发送功率为min(Q x,P total–pwr y-P z),在此限制下确定x的发送功率pwr x
最后确定z的最大发送功率或发送功率为min(Q z,P total-pwr x-pwr y),在此限制下确定z的发送功率pwr z
另外,Q 1+Q 2>P cmax的情况下,可以采取以下方式确定第二单元的发送功率或实际最大发送功率。
在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,且Q 1+Q 2>P cmax的情况下,根据min(P cmax-sum(pwr k)-sum(P s),Q x,P total-sum(pwr y)–sum(P z)),确定第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为MT中的一个小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2;pwr k表示MT中的k单元的发送功率,且k单元的发送优先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;P s表示为MT中的s单元配置的最小保证功率,且s单元的发送优先级低于第二单元的发送优先级。
可选的,所述确定所述DU的发送功率和所述MT至少一项小区组的发送功率之后,还包括:
上报至少一个功率余量报告PHR;
其中,所述PHR计算的功率上限假设为以下至少一项:
至少一个配置的最大发送功率;
至少一个协议约定的最大功率;
至少一个实际最大发送功率;
至少一个配置的最小保证功率。
针对上述第一种可选的方案,PHR上报时,至少针对所述功率共享的时刻,MT可以上报一个或多个PHR。
假设MT小区组的最大发送功率为理论上可以达到的最大发送功率(例如,P total、P cmax、Q MT、min(Q MT,P total-pwr DU)、P total-P DU、P total-pwr DU、min(Q MT,P total-P DU)、Q MCG、QSCG、Q MCG下调或上浮或按比例调整后的值、Q SCG下调或上浮或按比例调整后的值)、实际最大发送功率(例如,MT的最大发送功率中除去高优先级CG所占用的发送功率),和/或,最小保证功率值(P MT)。
针对上述第二种可选的方案,PHR上报时,至少针对所述功率共享的时刻,MT可以上报一个或多个PHR。
假设MT小区组最大发送功率为理论上可以达到的最大发送功率(例如,P total、P cmax、Q 1或Q 2)、实际最大发送功率(例如,MT的最大发送功率中除去高优先级小区组(CG)所占用的发送功率,和/或,除去低优先级小区组的最小保证功率),和/或,最小保证功率值。
本申请实施例中,可以同时上报多个PHR,或者,不同发送情况上报不同的PHR。
需要说明的是,本申请实施例中的,最小保证功率与现有最小保证功率原则中的最小保证功率所表示的含义相同,实际最大发送功率可以理解为总的发送功率减去其中一个单元的发送功率之后的剩余功率。
本申请实施例的功率获取方法,获取配置功率;根据所述配置功率和发送优先级,确定所述DU的发送功率和/或MT至少一个小区组的发送功率,从而实现了DU和MT至少一个小区组之间的动态功率共享,提高了IAB传输的功率效率。
需要说明的是,本申请实施例提供的功率获取方法,执行主体可以为功率获取装置,或者,该功率获取装置中的用于执行功率获取方法的控制模块。本申请实施例中以功率获取装置执行功率获取方法为例,说明本申请实施例提供的功率获取装置。
如图4所示,本申请实施例提供了一种功率获取装置400,应用于节点设备,包括:
第一获取模块401,用于获取配置功率,所述配置功率包括第一配置功率 和第二配置功率中的至少一项,所述第一配置功率是指为自回传IAB节点的分布单元DU配置的功率,所述第二配置功率包括所述IAB节点中MT的配置的功率和为所述MT至少一个小区组配置的功率,或者,所述第二配置功率包括为所述MT至少一个小区组配置的功率;
第一确定模块402,用于用于确定所述DU的发送功率和所述MT至少一项小区组的发送功率,其中,所述DU的发送功率和所述MT至少一个小区组的发送功率中的至少一项是根据所述配置功率和发送优先级确定的;
其中,所述发送优先级包括:DU的发送优先级、MT的发送优先级和MT至少一个小区组的发送优先级中的至少一项。
本申请实施例的功率获取装置,获取配置功率;根据所述配置功率和发送优先级,确定所述DU的发送功率和/或MT至少一个小区组的发送功率,从而实现了DU和MT至少一个小区组之间的动态功率共享,提高了IAB传输的功率效率。
本申请实施例的功率获取装置,所述第一确定模块包括:
第一确定子模块,用于确定所述DU的发送功率和MT的发送功率,其中,所述DU的发送功率和所述MT的发送功率中的至少一项是根据所述配置功率和所述发送优先级确定的;
第二确定子模块,用于根据所述MT的发送功率或预设功率固定值,确定MT至少一个小区组的发送功率。
本申请实施例的功率获取装置,所述第一配置功率是为所述DU配置的发送功率或最大发送功率Q DU,所述第二配置功率是为所述MT配置的发送功率或最大发送功率Q MT
所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,确定DU的发送功率,所述DU的发送功率小于或者等于Q DU
本申请实施例的功率获取装置,所述第一配置功率Q DU是为所述DU配置的发送功率或最大发送功率,所述第二配置功率Q MT是为所述MT配置的发送功率或最大发送功率;
所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,确定MT的发送功率,所述MT的发送功率小于或者等于Q MT
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。
本申请实施例的功率获取装置,Q DU+Q MT>P total
本申请实施例的功率获取装置,所述第一配置功率是为所述DU配置的最小保证功率P DU,所述第二配置功率为所述MT配置的最小保证功率P MT
所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的第一差值,确定DU的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与P MT的第二差值,确定DU的发送功率。
本申请实施例的功率获取装置,所述第一配置功率是为所述DU配置的最小保证功率P DU,所述第二配置功率为所述MT配置的最小保证功率P MT
所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与P DU的第三差值,确定MT的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的第四差值,确定MT的发送功率。
本申请实施例的功率获取装置,所述第一确定子模块包括:
第一确定单元,用于确定MT的实际最大发送功率;
第二确定单元,用于至少根据所述MT的实际最大发送功率,确定MT的发送功率;
本申请实施例的功率获取装置,所述第一确定单元用于在所述MT存在 P cmax的情况下,选取所述第三差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率;
或者,在所述MT存在P cmax的情况下,选取所述第四差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率,所述P cmax为协议约定的或预配置的MT的最大发送功率。
本申请实施例的功率获取装置,所述第一配置功率包括Q DU和/或P DU,所述第二配置功率包括Q MT和/或P MT,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为所述DU配置的最小保证功率;Q MT是指为所述MT配置的发送功率或最大发送功率,P MT是指为所述MT配置的最小保证功率;
所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与P MT的差值以及Q DU,确定DU的发送功率。
本申请实施例的功率获取装置,所述第一配置功率包括Q DU和/或P DU,所述第二配置功率包括Q MT和/或P MT,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为所述DU配置的最小保证功率;Q MT是指为所述MT配置的发送功率或最大发送功率,P MT是指为所述MT配置的最小保证功率;
所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与P DU的差值以及Q MT,确定MT的发送功率;
或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。
本申请实施例的功率获取装置,所述第二配置功率包括为MT主小区组配置的最大发送功率Q MCG和为MT辅小区组配置的最大发送功率Q SCG;所 述MT的发送功率包括为MT配置的最大发送功率、协议约定的MT的最大发送功率或MT的实际最大发送功率;
所述第二确定子模块用于根据所述Q MCG和Q SCG,按照预设功率共享规则,获取MT主小区组的最大发送功率和MT辅小区组的最大发送功率;
其中,所述预设功率共享规则包括第一功率共享规则、第二功率共享规则和第三功率共享规则;
所述第一功率共享规则是指在Q MCG与Q SCG之和大于目标功率的情况下,进行动态功率共享;
所述第二功率共享规则是指在Q MCG与Q SCG之和小于或者等于目标功率的情况下,进行半静态功率共享;
所述第三功率共享规则是进行动态功率共享;
其中,所述目标功率为所述MT的发送功率或预设功率固定值。
本申请实施例的功率获取装置,所述第一确定模块还包括:调整子模块,用于第二确定子模块获取MT主小区组的最大发送功率和MT辅小区组的最大发送功率之前,在预设功率固定值与MT的发送功率不同的情况下,根据预设功率固定值与MT的发送功率的差值,对Q MCG和Q SCG中的至少一项进行调整。
本申请实施例的功率获取装置,所述第一配置功率为Q DU,Q DU是指为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q 1和Q 2,Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为所述MT辅小区组的配置发送功率或最大发送功率;
所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级的情况下,根据min(Q x,P total-sum(pwr y)),确定所述第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,所述第二单元包括所述DU、MT辅小区组或MT主小区组,且所述第一单元与所述第二单元不同;
Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率,P total为所述IAB节点的总功率。
本申请实施例的功率获取装置,其中,Q DU+Q 1+Q 2>P total
本申请实施例的功率获取装置,所述第一配置功率包括Q DU,Q DU是指为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q 1和Q 2,Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为所述MT辅小区组的配置发送功率或最大发送功率;
所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且Q 1+Q 2>P cmax的情况下,根据min(P cmax–sum(pwr k),Q x,P total-sum(pwr y)),确定第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,第二单元为MT中的一个小区组,且所述第一单元与所述第二单元不同;pwr k表示MT中的k单元的发送功率,且k单元的发送优先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率。
本申请实施例的功率获取装置,所述第一配置功率包括P DU,所述第二配置功率包括P 1和P 2,所述P DU是指为所述DU配置的最小保证功率,所述P 1是指为MT主小区组配置的最小保证功率,所述P 2是指为所述MT辅小区组配置的最小保证功率;
所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据P total–sum(pwr y)–sum(P z),确定所述第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区 组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2
本申请实施例的功率获取装置,所述第一配置功率包括Q DU和P DU,所述第二配置功率包括Q 1、Q 2、P 1和P 2,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为DU配置的最小保证功率;Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为所述MT辅小区组配置的发送功率或最大发送功率,P 1是指为MT主小区组配置的最小保证功率,P 2是指为所述MT辅小区组配置的最小保证功率;
所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据min{Q x,P total–sum(pwr y)–sum(P z)},确定所述第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2
本申请实施例的功率获取装置,所述第一配置功率包括Q DU和P DU,所述第二配置功率包括Q 1、Q 2、P 1和P 2,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为DU配置的最小保证功率;Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为所述MT辅小区组配置的发送功率或最大发送功率,P 1是指为MT主小区组配置的最小保证功率,P 2是指为所述MT辅小区组配置的最小保证功率;
所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,且Q 1+Q 2>P cmax的情况下,根据min(P cmax-sum(pwr k)-sum(P s),Q x,P total-sum(pwr y)–sum(P z)),确定第二单元的发送功率或实际最大发送功率;
其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为MT中的一个小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2;pwr k表示MT中的k单元的发送功率,且k单元的发送优先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;P s表示为MT中的s单元配置的最小保证功率,且s单元的发送优先级低于第二单元的发送优先级。
本申请实施例的功率获取装置,还包括:
上报模块,用于第一确定模块确定所述DU的发送功率和所述MT至少一项小区组的发送功率之后,上报至少一个功率余量报告PHR;
其中,所述PHR计算的功率上限假设为以下至少一项:
至少一个配置的最大发送功率;
至少一个协议约定的最大功率;
至少一个实际最大发送功率;
至少一个配置的最小保证功率。
本申请实施例的功率获取装置,所述发送优先级是通过以下至少一种方式确定的:
协议约定;
网络配置;
物理层的传输优先级。
本申请实施例的功率获取装置,获取配置功率;根据所述配置功率和发送优先级,确定所述DU的发送功率和/或MT至少一个小区组的发送功率,从而实现了DU和MT至少一个小区组之间的动态功率共享,提高了IAB传输的功率效率。
本申请实施例中的功率获取装置可以是装置,也可以是节点设备中的部件、集成电路、或芯片。
本申请实施例提供的功率获取装置能够实现图1至图3的方法实施例实现的各个过程,并达到相同的技术效果,为避免重复,这里不再赘述。
可选的,如图5所示,本申请实施例还提供一种节点设备500,该节点设备包括处理器501,存储器502,存储在存储器502上并可在所述处理器501上运行的程序或指令,该程序或指令被处理器501执行时实现上述功率获取方法实施例的各个过程,且能达到相同的技术效果,为避免重复,这里不再赘述。
如图6所示,本申请实施例还提供了一种节点设备,该节点设备600包括:天线601、射频装置602、基带装置603。天线601与射频装置602连接。在上行方向上,射频装置602通过天线601接收信息,将接收的信息发送给基带装置603进行处理。在下行方向上,基带装置603对要发送的信息进行处理,并发送给射频装置602,射频装置602对收到的信息进行处理后经过天线601发送出去。
上述频带处理装置可以位于基带装置603中,以上实施例中节点设备执行的方法可以在基带装置603中实现,该基带装置603包括处理器604和存储器605。
基带装置603例如可以包括至少一个基带板,该基带板上设置有多个芯片,如图6所示,其中一个芯片例如为处理器604,与存储器605连接,以调用存储器605中的程序,执行以上方法实施例中所示的操作。
该基带装置603还可以包括网络接口606,用于与射频装置602交互信 息,该接口例如为通用公共无线接口(common public radio interface,CPRI)。
具体地,本发明实施例的节点设备还包括:存储在存储器605上并可在处理器604上运行的指令或程序,处理器604调用存储器605中的指令或程序执行图4所示各模块执行的方法,并达到相同的技术效果,为避免重复,故不在此赘述。
本申请实施例还提供一种可读存储介质,所述可读存储介质上存储有程序或指令,该程序或指令被处理器执行时实现上述功率获取方法实施例的各个过程,且能达到相同的技术效果,为避免重复,这里不再赘述。
其中,所述处理器为上述实施例中所述节点设备中的处理器。所述可读存储介质,包括计算机可读存储介质,如计算机只读存储器(Read-Only Memory,ROM)、随机存取存储器(Random Access Memory,RAM)、磁碟或者光盘等。
本申请实施例另提供了一种芯片,所述芯片包括处理器和通信接口,所述通信接口和所述处理器耦合,所述处理器用于运行节点设备程序或指令,实现上述功率获取方法实施例的各个过程,且能达到相同的技术效果,为避免重复,这里不再赘述。
应理解,本申请实施例提到的芯片还可以称为系统级芯片,系统芯片,芯片系统或片上系统芯片等。
需要说明的是,在本文中,术语“包括”、“包含”或者其任何其他变体意在涵盖非排他性的包含,从而使得包括一系列要素的过程、方法、物品或者装置不仅包括那些要素,而且还包括没有明确列出的其他要素,或者是还包括为这种过程、方法、物品或者装置所固有的要素。在没有更多限制的情况下,由语句“包括一个……”限定的要素,并不排除在包括该要素的过程、方法、物品或者装置中还存在另外的相同要素。此外,需要指出的是,本申请实施方式中的方法和装置的范围不限按示出或讨论的顺序来执行功能,还可包括根据所涉及的功能按基本同时的方式或按相反的顺序来执行功能,例如,可以按不同于所描述的次序来执行所描述的方法,并且还可以添加、省去、或组 合各种步骤。另外,参照某些示例所描述的特征可在其他示例中被组合。
通过以上的实施方式的描述,本领域的技术人员可以清楚地了解到上述实施例方法可借助软件加必需的通用硬件平台的方式来实现,当然也可以通过硬件,但很多情况下前者是更佳的实施方式。基于这样的理解,本申请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(如ROM/RAM、磁碟、光盘)中,包括若干指令用以使得一台终端(可以是手机,计算机,服务器,空调器,或者网络设备等)执行本申请各个实施例所述的方法。
上面结合附图对本申请的实施例进行了描述,但是本申请并不局限于上述的具体实施方式,上述的具体实施方式仅仅是示意性的,而不是限制性的,本领域的普通技术人员在本申请的启示下,在不脱离本申请宗旨和权利要求所保护的范围情况下,还可做出很多形式,均属于本申请的保护之内。

Claims (46)

  1. 一种功率获取方法,应用于节点设备,包括:
    获取配置功率,所述配置功率包括第一配置功率和第二配置功率中的至少一项,所述第一配置功率是指为自回传IAB节点的分布单元DU配置的功率,所述第二配置功率包括所述IAB节点中MT的配置的功率和为所述MT至少一个小区组配置的功率,或者,所述第二配置功率包括为所述MT至少一个小区组配置的功率;
    确定所述DU的发送功率和所述MT至少一项小区组的发送功率,其中,所述DU的发送功率和所述MT至少一个小区组的发送功率中的至少一项是根据所述配置功率和发送优先级确定的;
    其中,所述发送优先级包括:DU的发送优先级、MT的发送优先级和MT至少一个小区组的发送优先级中的至少一项。
  2. 根据权利要求1所述的功率获取方法,其中,确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
    确定所述DU的发送功率和MT的发送功率,其中,所述DU的发送功率和所述MT的发送功率中的至少一项是根据所述配置功率和所述发送优先级确定的;
    根据所述MT的发送功率或预设功率固定值,确定MT至少一个小区组的发送功率。
  3. 根据权利要求2所述的功率获取方法,其中,所述第一配置功率是为所述DU配置的发送功率或最大发送功率Q DU,所述第二配置功率是为所述MT配置的发送功率或最大发送功率Q MT
    所述确定所述DU的发送功率,包括:
    在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,确定DU 的发送功率,所述DU的发送功率小于或者等于Q DU
  4. 根据权利要求2所述的功率获取方法,其中,所述第一配置功率Q DU是为所述DU配置的发送功率或最大发送功率,所述第二配置功率Q MT是为所述MT配置的发送功率或最大发送功率;
    所述确定MT的发送功率,包括:
    在MT的发送优先级高于DU的发送优先级的情况下,确定MT的发送功率,所述MT的发送功率小于或者等于Q MT
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。
  5. 根据权利要求3或4所述的功率获取方法,其中,Q DU+Q MT>P total
  6. 根据权利要求2所述的功率获取方法,其中,所述第一配置功率是为所述DU配置的最小保证功率P DU,所述第二配置功率为所述MT配置的最小保证功率P MT
    所述确定所述DU的发送功率,包括:
    在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的第一差值,确定DU的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与P MT的第二差值,确定DU的发送功率。
  7. 根据权利要求2所述的功率获取方法,其中,所述第一配置功率是为所述DU配置的最小保证功率P DU,所述第二配置功率为所述MT配置的最小保证功率P MT
    所述确定MT的发送功率,包括:
    在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与P DU的第三差值,确定MT的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的第四差值,确定MT的发送功率。
  8. 根据权利要求7所述的功率获取方法,其中,所述确定MT的发送功 率,包括:
    确定MT的实际最大发送功率;
    至少根据所述MT的实际最大发送功率,确定MT的发送功率。
  9. 根据权利要求8所述的功率获取方法,其中,所述确定MT的实际最大发送功率,包括:
    在所述MT存在P cmax的情况下,选取所述第三差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率;
    或者,在所述MT存在P cmax的情况下,选取所述第四差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率,所述P cmax为协议约定的或预配置的MT的最大发送功率。
  10. 根据权利要求2所述的功率获取方法,其中,所述第一配置功率包括Q DU和/或P DU,所述第二配置功率包括Q MT和/或P MT,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为所述DU配置的最小保证功率;Q MT是指为所述MT配置的发送功率或最大发送功率,P MT是指为所述MT配置的最小保证功率;
    所述确定所述DU的发送功率,包括:
    在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与P MT的差值以及Q DU,确定DU的发送功率。
  11. 根据权利要求2所述的功率获取方法,其中,所述第一配置功率包括Q DU和/或P DU,所述第二配置功率包括Q MT和/或P MT,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为所述DU配置的最小保证功率;Q MT是指为所述MT配置的发送功率或最大发送功率,P MT是指为所述MT配置的最小保证功率;
    所述确定MT的发送功率,包括:
    在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的 总功率P total与P DU的差值以及Q MT,确定MT的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。
  12. 根据权利要求2所述的功率获取方法,其中,所述第二配置功率包括为MT主小区组配置的最大发送功率Q MCG和为MT辅小区组配置的最大发送功率Q SCG;所述MT的发送功率包括为MT配置的最大发送功率、协议约定的MT的最大发送功率或MT的实际最大发送功率;
    根据MT的发送功率或预设功率固定值,确定MT至少一个小区组的发送功率,包括:
    根据所述Q MCG和Q SCG,按照预设功率共享规则,获取MT主小区组的最大发送功率和MT辅小区组的最大发送功率;
    其中,所述预设功率共享规则包括第一功率共享规则、第二功率共享规则和第三功率共享规则;
    所述第一功率共享规则是指在Q MCG与Q SCG之和大于目标功率的情况下,进行动态功率共享;
    所述第二功率共享规则是指在Q MCG与Q SCG之和小于或者等于目标功率的情况下,进行半静态功率共享;
    所述第三功率共享规则是进行动态功率共享;
    其中,所述目标功率为所述MT的发送功率或预设功率固定值。
  13. 根据权利要求12所述的功率获取方法,其中,获取MT主小区组的最大发送功率和MT辅小区组的最大发送功率之前,还包括:
    在预设功率固定值与MT的发送功率不同的情况下,根据预设功率固定值与MT的发送功率的差值,对Q MCG和Q SCG中的至少一项进行调整。
  14. 根据权利要求1所述的功率获取方法,其中,所述第一配置功率为Q DU,Q DU是指为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q 1和Q 2,Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组的配置发送功率或最大发送功率;
    确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
    在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级的情况下,根据min(Q x,P total-sum(pwr y)),确定所述第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,所述第二单元包括所述DU、MT辅小区组或MT主小区组,且所述第一单元与所述第二单元不同;
    Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率,P total为所述IAB节点的总功率。
  15. 根据权利要求14所述的功率获取方法,其中,Q DU+Q 1+Q 2>P total
  16. 根据权利要求1所述的功率获取方法,其中,所述第一配置功率包括Q DU,Q DU是指为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q 1和Q 2,Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组的配置发送功率或最大发送功率;
    确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
    在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且Q 1+Q 2>P cmax的情况下,根据min(P cmax–sum(pwr k),Q x,P total-sum(pwr y)),确定第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,第二单元为MT中的一个小区组,且所述第一单元与所述第二单元不同;pwr k表示MT中的k单元的发送功率,且k单元的发送优先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率。
  17. 根据权利要求1所述的功率获取方法,其中,所述第一配置功率包括P DU,所述第二配置功率包括P 1和P 2,所述P DU是指为所述DU配置的最小保证功率,所述P 1是指为MT主小区组配置的最小保证功率,所述P 2是指为 MT辅小区组配置的最小保证功率;
    确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
    在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据P total–sum(pwr y)–sum(P z),确定所述第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
    所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2
  18. 根据权利要求1所述的功率获取方法,其中,所述第一配置功率包括Q DU和P DU,所述第二配置功率包括Q 1、Q 2、P 1和P 2,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为DU配置的最小保证功率;Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组配置的发送功率或最大发送功率,P 1是指为MT主小区组配置的最小保证功率,P 2是指为所述MT辅小区组配置的最小保证功率;
    确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
    在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据min{Q x,P total–sum(pwr y)–sum(P z)},确定所述第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
    所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2
  19. 根据权利要求1所述的功率获取方法,其中,所述第一配置功率包括Q DU和P DU,所述第二配置功率包括Q 1、Q 2、P 1和P 2,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为DU配置的最小保证功率;Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组配置的发送功率或最大发送功率,P 1是指为MT主小区组配置的最小保证功率,P 2是指为所述MT辅小区组配置的最小保证功率;
    确定所述DU的发送功率和所述MT至少一项小区组的发送功率,包括:
    在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,且Q 1+Q 2>P cmax的情况下,根据min(P cmax-sum(pwr k)-sum(P s),Q x,P total-sum(pwr y)–sum(P z)),确定第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为MT中的一个小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
    所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2;pwr k表示MT中的k单元的发送功率,且k单元的发送优先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;P s表示为MT中的s单元配置的最小保证功率,且s单元的发送优先级低于第二单元的发送优先级。
  20. 根据权利要求1所述的功率获取方法,其中,所述确定所述DU的发送功率和所述MT至少一项小区组的发送功率之后,还包括:
    上报至少一个功率余量报告PHR;
    其中,所述PHR计算的功率上限假设为以下至少一项:
    至少一个配置的最大发送功率;
    至少一个协议约定的最大功率;
    至少一个实际最大发送功率;
    至少一个配置的最小保证功率。
  21. 根据权利要求1所述的功率获取方法,其中,所述发送优先级是通过以下至少一种方式确定的:
    协议约定;
    网络配置;
    物理层的传输优先级。
  22. 一种功率获取装置,应用于节点设备,包括:
    第一获取模块,用于获取配置功率,所述配置功率包括第一配置功率和第二配置功率中的至少一项,所述第一配置功率是指为自回传IAB节点的分布单元DU配置的功率,所述第二配置功率包括所述IAB节点中MT的配置的功率和为所述MT至少一个小区组配置的功率,或者,所述第二配置功率包括为所述MT至少一个小区组配置的功率;
    第一确定模块,用于确定所述DU的发送功率和所述MT至少一项小区组的发送功率,其中,所述DU的发送功率和所述MT至少一个小区组的发送功率中的至少一项是根据所述配置功率和发送优先级确定的;
    其中,所述发送优先级包括:DU的发送优先级、MT的发送优先级和MT至少一个小区组的发送优先级中的至少一项。
  23. 根据权利要求22所述的功率获取装置,其中,所述第一确定模块包括:
    第一确定子模块,用于确定所述DU的发送功率和MT的发送功率,其中,所述DU的发送功率和所述MT的发送功率中的至少一项是根据所述配置功率和所述发送优先级确定的;
    第二确定子模块,用于根据所述MT的发送功率或预设功率固定值,确定MT至少一个小区组的发送功率。
  24. 根据权利要求23所述的功率获取装置,其中,所述第一配置功率是为所述DU配置的发送功率或最大发送功率Q DU,所述第二配置功率是为所述MT配置的发送功率或最大发送功率Q MT
    所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,确定DU的发送功率,所述DU的发送功率小于或者等于Q DU
  25. 根据权利要求23所述的功率获取装置,其中,所述第一配置功率Q DU是为所述DU配置的发送功率或最大发送功率,所述第二配置功率Q MT是为所述MT配置的发送功率或最大发送功率;
    所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,确定MT的发送功率,所述MT的发送功率小于或者等于Q MT
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。
  26. 根据权利要求24或25所述的功率获取装置,其中,Q DU+Q MT>P total
  27. 根据权利要求23所述的功率获取装置,其中,所述第一配置功率是为所述DU配置的最小保证功率P DU,所述第二配置功率为所述MT配置的最小保证功率P MT
    所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的第一差值,确定DU的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与P MT的第二差值,确定DU的发送功率。
  28. 根据权利要求23所述的功率获取装置,其中,所述第一配置功率是 为所述DU配置的最小保证功率P DU,所述第二配置功率为所述MT配置的最小保证功率P MT
    所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与P DU的第三差值,确定MT的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的第四差值,确定MT的发送功率。
  29. 根据权利要求28所述的功率获取装置,其中,所述第一确定子模块包括:
    第一确定单元,用于确定MT的实际最大发送功率;
    第二确定单元,用于至少根据所述MT的实际最大发送功率,确定MT的发送功率。
  30. 根据权利要求29所述的功率获取装置,其中,所述第一确定单元用于在所述MT存在P cmax的情况下,选取所述第三差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率;
    或者,在所述MT存在P cmax的情况下,选取所述第四差值和所述P cmax中较小的值,作为所述MT的实际最大发送功率,所述P cmax为协议约定的或预配置的MT的最大发送功率。
  31. 根据权利要求23所述的功率获取装置,其中,所述第一配置功率包括Q DU和/或P DU,所述第二配置功率包括Q MT和/或P MT,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为所述DU配置的最小保证功率;Q MT是指为所述MT配置的发送功率或最大发送功率,P MT是指为所述MT配置的最小保证功率;
    所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与MT的发送功率的差值以及Q DU,确定DU的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB 节点的总功率P total与P MT的差值以及Q DU,确定DU的发送功率。
  32. 根据权利要求23所述的功率获取装置,其中,所述第一配置功率包括Q DU和/或P DU,所述第二配置功率包括Q MT和/或P MT,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为所述DU配置的最小保证功率;Q MT是指为所述MT配置的发送功率或最大发送功率,P MT是指为所述MT配置的最小保证功率;
    所述第一确定子模块用于在MT的发送优先级高于DU的发送优先级的情况下,根据IAB节点的总功率P total与P DU的差值以及Q MT,确定MT的发送功率;
    或者,在DU的发送优先级高于MT的发送优先级的情况下,根据IAB节点的总功率P total与DU的发送功率的差值以及Q MT,确定MT的发送功率。
  33. 根据权利要求23所述的功率获取装置,其中,所述第二配置功率包括为MT主小区组配置的最大发送功率Q MCG和为MT辅小区组配置的最大发送功率Q SCG;所述MT的发送功率包括为MT配置的最大发送功率、协议约定的MT的最大发送功率或MT的实际最大发送功率;
    所述第二确定子模块用于根据所述Q MCG和Q SCG,按照预设功率共享规则,获取MT主小区组的最大发送功率和MT辅小区组的最大发送功率;
    其中,所述预设功率共享规则包括第一功率共享规则、第二功率共享规则和第三功率共享规则;
    所述第一功率共享规则是指在Q MCG与Q SCG之和大于目标功率的情况下,进行动态功率共享;
    所述第二功率共享规则是指在Q MCG与Q SCG之和小于或者等于目标功率的情况下,进行半静态功率共享;
    所述第三功率共享规则是进行动态功率共享;
    其中,所述目标功率为所述MT的发送功率或预设功率固定值。
  34. 根据权利要求33所述的功率获取装置,其中,所述第一确定模块还包括:调整子模块,用于第二确定子模块获取MT主小区组的最大发送功率 和MT辅小区组的最大发送功率之前,在预设功率固定值与MT的发送功率不同的情况下,根据预设功率固定值与MT的发送功率的差值,对Q MCG和Q SCG中的至少一项进行调整。
  35. 根据权利要求22所述的功率获取装置,其中,所述第一配置功率为Q DU,Q DU是指为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q 1和Q 2,Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组的配置发送功率或最大发送功率;
    所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级的情况下,根据min(Q x,P total-sum(pwr y)),确定所述第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,所述第二单元包括所述DU、MT辅小区组或MT主小区组,且所述第一单元与所述第二单元不同;
    Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率,P total为所述IAB节点的总功率。
  36. 根据权利要求35所述的功率获取装置,其中,Q DU+Q 1+Q 2>P total
  37. 根据权利要求22所述的功率获取装置,其中,所述第一配置功率包括Q DU,Q DU是指为所述DU配置的发送功率或最大发送功率,所述第二配置功率包括Q 1和Q 2,Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组的配置发送功率或最大发送功率;
    所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且Q 1+Q 2>P cmax的情况下,根据min(P cmax–sum(pwr k),Q x,P total-sum(pwr y)),确定第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组和MT主小区组中的至少一个,第二单元为MT中的一个小区组,且所述第一单元与所述第二单元不同;pwr k表示MT中的k单元的发送功率,且k单元的发送优 先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2,pwr y表示第一单元的发送功率。
  38. 根据权利要求22所述的功率获取装置,其中,所述第一配置功率包括P DU,所述第二配置功率包括P 1和P 2,所述P DU是指为所述DU配置的最小保证功率,所述P 1是指为MT主小区组配置的最小保证功率,所述P 2是指为MT辅小区组配置的最小保证功率;
    所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据P total–sum(pwr y)–sum(P z),确定所述第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
    所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2
  39. 根据权利要求22所述的功率获取装置,其中,所述第一配置功率包括Q DU和P DU,所述第二配置功率包括Q 1、Q 2、P 1和P 2,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为DU配置的最小保证功率;Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组配置的发送功率或最大发送功率,P 1是指为MT主小区组配置的最小保证功率,P 2是指为所述MT辅小区组配置的最小保证功率;
    所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,且所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,根据min{Q x,P total–sum(pwr y)–sum(P z)},确定所述第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
    所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2
  40. 根据权利要求22所述的功率获取装置,其中,所述第一配置功率包括Q DU和P DU,所述第二配置功率包括Q 1、Q 2、P 1和P 2,其中,Q DU是指为所述DU配置的发送功率或最大发送功率,P DU是指为DU配置的最小保证功率;Q 1是指为MT主小区组配置的发送功率或最大发送功率,Q 2是指为MT辅小区组配置的发送功率或最大发送功率,P 1是指为MT主小区组配置的最小保证功率,P 2是指为所述MT辅小区组配置的最小保证功率;
    所述第一确定模块用于在所述IAB节点中的第一单元y的发送优先级高于所述IAB节点中第二单元x的发送优先级,所述第二单元x的发送优先级高于所述IAB节点中的第三单元z的发送优先级的情况下,且Q 1+Q 2>P cmax的情况下,根据min(P cmax-sum(pwr k)-sum(P s),Q x,P total-sum(pwr y)–sum(P z)),确定第二单元的发送功率或实际最大发送功率;
    其中,所述第一单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,所述第二单元为MT中的一个小区组,所述第三单元为所述IAB节点中的DU、MT辅小区组或MT主小区组,且所述第一单元、所述第二单元和所述第三单元三者不相同;
    所述pwr y表示第一单元的发送功率,P z表示为所述第三单元配置的最小保证功率,P z等于P DU、P 1或P 2,Q x表示为所述第二单元配置的最大发送功率或发送功率,Q x为Q DU、Q 1或Q 2;pwr k表示MT中的k单元的发送功率,且k单元的发送优先级高于所述第二单元的发送优先级,P cmax为协议约定的MT的最大发送功率;P s表示为MT中的s单元配置的最小保证功率,且s单 元的发送优先级低于第二单元的发送优先级。
  41. 根据权利要求22所述的功率获取装置,还包括:
    上报模块,用于第一确定模块确定所述DU的发送功率和所述MT至少一项小区组的发送功率之后,上报至少一个功率余量报告PHR;
    其中,所述PHR计算的功率上限假设为以下至少一项:
    至少一个配置的最大发送功率;
    至少一个协议约定的最大功率;
    至少一个实际最大发送功率;
    至少一个配置的最小保证功率。
  42. 根据权利要求22所述的功率获取装置,其中,所述发送优先级是通过以下至少一种方式确定的:
    协议约定;
    网络配置;
    物理层的传输优先级。
  43. 一种节点设备,包括处理器,存储器及存储在所述存储器上并可在所述处理器上运行的程序或指令,所述程序或指令被所述处理器执行时实现如权利要求1至21任一项所述的功率获取方法的步骤。
  44. 一种可读存储介质,其中,所述可读存储介质上存储程序或指令,所述程序或指令被处理器执行时实现如权利要求1至21任一项所述的功率获取方法的步骤。
  45. 一种芯片,所述芯片包括处理器和通信接口,所述通信接口和所述处理器耦合,所述处理器用于运行程序或指令,实现如权利要求1至21任一项所述的功率获取方法的步骤。
  46. 一种节点设备,所述节点设备被配置为用于执行如权利要求1至21任一项所述的功率获取方法的步骤。
PCT/CN2021/108081 2020-07-24 2021-07-23 功率获取方法、装置及节点设备 WO2022017489A1 (zh)

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