WO2023123477A1

WO2023123477A1 - Wireless communication method, terminal device, and network device

Info

Publication number: WO2023123477A1
Application number: PCT/CN2021/143976
Authority: WO
Inventors: 张晋瑜; 胡荣贻
Original assignee: Oppo广东移动通信有限公司
Priority date: 2021-12-31
Filing date: 2021-12-31
Publication date: 2023-07-06

Abstract

Embodiments of the present application provide a wireless communication method, a terminal device, and a network device. The method comprises: receiving configuration information transmitted by a network device, the configuration information being used for configuring a first measurement object (MO) corresponding to a plurality of synchronization signal and/or physical broadcast channel block measurement timing configurations (SMTC); and when measuring the first MO on the basis of a first SMTC in the plurality of SMTCs, determining whether to use a measurement gap (MG). According to the method provided by the present application, for an MO corresponding to the plurality of SMTCs, it can be determined whether the MG is needed for measurement, and thus, the system performance can be improved.

Description

Wireless communication method, terminal device and network device

technical field

The embodiments of the present application relate to the communication field, and more specifically, to a wireless communication method, a terminal device, and a network device.

Background technique

In a terrestrial cellular network, a measurement object (MO) corresponds to a synchronization signal and/or physical broadcast channel block measurement timing configuration (SS/PBCH block measurement timing configuration, SMTC) and a measurement interval (Measurement Gap, MG) . When the terminal device determines the measurement time required by the MO, if the MO needs to use the MG for measurement, then determine the measurement time required for measuring the MO based on the period of the SMTC included in the MO and the period of the MG used by the MO ; If the MO does not need to use the MG for measurement, then determine the measurement time required for measuring the MO based on the period of the SMTC included in the MO.

However, in a non-terrestrial network (Non-Terrestrial Network, NTN), one MO is allowed to correspond to multiple SMTCs and multiple MGs. Therefore, when determining the measurement time required for measuring MOs, the measurement-related The program does not apply to NTN. For example, since one MO in the terrestrial cellular network only considers one SMTC, it can be determined directly based on whether the MO is an MO that needs to use MG for measurement. However, since NTN allows one MO to correspond to multiple SMTCs and multiple MGs, and there is no relevant technical solution in the art on how to determine whether to use the MG for an MO corresponding to multiple SMTCs and multiple MGs.

Therefore, there is an urgent need in the art for a scheme applicable to NTN to determine whether to use MG.

Contents of the invention

The embodiment of the present application provides a wireless communication method, a terminal device, and a network device. For each SMTC among a plurality of SMTCs corresponding to an MO, it is determined whether an MG is required for measurement, and further, it is beneficial to calculate the measurement time of the MO and improve the system performance.

In a first aspect, the present application provides a wireless communication method, including:

Receiving configuration information sent by the network device, the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

When measuring the first MO based on the first SMTC among the plurality of SMTCs, determine whether to use the measurement interval MG.

In a second aspect, the present application provides a wireless communication method, including:

Send configuration information to the terminal device, where the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

In a third aspect, the present application provides a terminal device configured to execute the method in the foregoing first aspect or various implementation manners thereof. Specifically, the terminal device includes a functional module configured to execute the method in the foregoing first aspect or its various implementation manners.

In an implementation manner, the terminal device may include a processing unit configured to perform functions related to information processing. For example, the processing unit may be a processor.

In an implementation manner, the terminal device may include a sending unit and/or a receiving unit. The sending unit is used to perform functions related to sending, and the receiving unit is used to perform functions related to receiving. For example, the sending unit may be a transmitter or transmitter, and the receiving unit may be a receiver or receiver. For another example, the terminal device is a communication chip, the sending unit may be an input circuit or interface of the communication chip, and the sending unit may be an output circuit or interface of the communication chip.

In a fourth aspect, the present application provides a network device configured to execute the method in the foregoing second aspect or various implementation manners thereof. Specifically, the network device includes a functional module configured to execute the method in the above second aspect or each implementation manner thereof.

In an implementation manner, the network device may include a processing unit configured to perform functions related to information processing. For example, the processing unit may be a processor.

In an implementation manner, the network device may include a sending unit and/or a receiving unit. The sending unit is used to perform functions related to sending, and the receiving unit is used to perform functions related to receiving. For example, the sending unit may be a transmitter or transmitter, and the receiving unit may be a receiver or receiver. For another example, the network device is a communication chip, the receiving unit may be an input circuit or interface of the communication chip, and the sending unit may be an output circuit or interface of the communication chip.

In a fifth aspect, the present application provides a terminal device, including a processor and a memory. The memory is used to store a computer program, and the processor is used to call and run the computer program stored in the memory, so as to execute the method in the above first aspect or each implementation manner thereof.

In an implementation manner, there are one or more processors, and one or more memories.

In an implementation manner, the memory may be integrated with the processor, or the memory may be separated from the processor.

In an implementation manner, the terminal device further includes a transmitter (transmitter) and a receiver (receiver).

In a sixth aspect, the present application provides a network device, including a processor and a memory. The memory is used to store a computer program, and the processor is used to call and run the computer program stored in the memory, so as to execute the method in the above second aspect or each implementation manner thereof.

In one implementation, the network device further includes a transmitter (transmitter) and a receiver (receiver).

In a seventh aspect, the present application provides a chip configured to implement any one of the above-mentioned first aspect to the second aspect or a method in each implementation manner thereof. Specifically, the chip includes: a processor, configured to call and run a computer program from the memory, so that the device installed with the chip executes any one of the above-mentioned first to second aspects or various implementations thereof method in .

In an eighth aspect, the present application provides a computer-readable storage medium for storing a computer program, and the computer program enables the computer to execute any one of the above-mentioned first to second aspects or the method in each implementation manner thereof .

In a ninth aspect, the present application provides a computer program product, including computer program instructions, the computer program instructions cause a computer to execute any one of the above first to second aspects or the method in each implementation manner.

In a tenth aspect, the present application provides a computer program, which, when run on a computer, causes the computer to execute any one of the above-mentioned first to second aspects or the method in each implementation manner.

Based on the above technical solution, when the terminal device measures the first SMTC among the multiple SMTCs included in the first MO, it determines whether to use the MG. The MO is refined into the SMTCs included in the first MO, that is to say, the present application can determine whether the MG needs to be measured for each SMTC among the multiple SMTCs corresponding to one MO, and further, it is beneficial to calculate the measurement of the MO time and improve system performance.

Description of drawings

Fig. 1 is an example of the system framework of the embodiment of the present application.

Fig. 2 is a schematic diagram of multiple SMTCs provided by the embodiment of the present application.

Fig. 3 is a schematic flowchart of a wireless communication method provided by an embodiment of the present application.

Fig. 4 is another schematic flowchart of the wireless communication method provided by the embodiment of the present application.

Fig. 5 is a schematic block diagram of a terminal device provided by an embodiment of the present application.

Fig. 6 is a schematic block diagram of a network device provided by an embodiment of the present application.

Fig. 7 is a schematic block diagram of a communication device provided by an embodiment of the present application.

Fig. 8 is a schematic block diagram of a chip provided by an embodiment of the present application.

Detailed ways

The technical solutions in the embodiments of the present application will be described below with reference to the accompanying drawings.

As shown in FIG. 1 , a communication system 100 may include a terminal device 110 and a network device 120 . The network device 120 may communicate with the terminal device 110 through an air interface. Multi-service transmission is supported between the terminal device 110 and the network device 120 .

It should be understood that the embodiment of the present application is only described by using the communication system 100 as an example, but the embodiment of the present application is not limited thereto. That is to say, the technical solutions of the embodiments of the present application can be applied to various communication systems, such as: Long Term Evolution (Long Term Evolution, LTE) system, LTE Time Division Duplex (Time Division Duplex, TDD), Universal Mobile Communication System (Universal Mobile Telecommunication System, UMTS), Internet of Things (Internet of Things, IoT) system, Narrow Band Internet of Things (NB-IoT) system, enhanced Machine-Type Communications (eMTC) system , 5G communication system (also known as New Radio (NR) communication system), or future communication systems, etc.

In the communication system 100 shown in FIG. 1 , the network device 120 may be an access network device that communicates with the terminal device 110 . The access network device can provide communication coverage for a specific geographic area, and can communicate with terminal devices 110 (such as UEs) located in the coverage area.

The network device 120 may be an evolved base station (Evolutional Node B, eNB or eNodeB) in a long-term evolution (Long Term Evolution, LTE) system, or a next-generation radio access network (Next Generation Radio Access Network, NG RAN) device, Either a base station (gNB) in the NR system, or a wireless controller in a cloud radio access network (Cloud Radio Access Network, CRAN), or the network device 120 can be a relay station, an access point, a vehicle-mounted device, a wearable Devices, hubs, switches, bridges, routers, or network devices in the future evolution of the Public Land Mobile Network (Public Land Mobile Network, PLMN), etc.

The terminal device 110 may be any terminal device, including but not limited to a terminal device connected to the network device 120 or other terminal devices by wire or wirelessly.

For example, the terminal equipment 110 may refer to an access terminal, a user equipment (User Equipment, UE), a subscriber unit, a subscriber station, a mobile station, a mobile station, a remote station, a remote terminal, a mobile device, a user terminal, a terminal, a wireless communication device, user agent, or user device. Access terminals can be cellular phones, cordless phones, Session Initiation Protocol (SIP) phones, IoT devices, satellite handheld terminals, Wireless Local Loop (WLL) stations, Personal Digital Assistant , PDA), handheld devices with wireless communication functions, computing devices or other processing devices connected to wireless modems, vehicle-mounted devices, wearable devices, terminal devices in 5G networks or terminal devices in future evolution networks, etc.

The terminal device 110 can be used for device-to-device (Device to Device, D2D) communication.

The wireless communication system 100 may also include a core network device 130 that communicates with the base station. The core network device 130 may be a 5G core network (5G Core, 5GC) device, for example, Access and Mobility Management Function (Access and Mobility Management Function , AMF), and for example, authentication server function (Authentication Server Function, AUSF), and for example, user plane function (User Plane Function, UPF), and for example, session management function (Session Management Function, SMF). Optionally, the core network device 130 may also be a packet core evolution (Evolved Packet Core, EPC) device of the LTE network, for example, a data gateway (Session Management Function+Core Packet Gateway, SMF+PGW- C) Equipment. It should be understood that SMF+PGW-C can realize the functions of SMF and PGW-C at the same time. In the process of network evolution, the above-mentioned core network equipment may be called by other names, or a new network entity may be formed by dividing functions of the core network, which is not limited in this embodiment of the present application.

Various functional units in the communication system 100 may also establish a connection through a next generation network (next generation, NG) interface to implement communication.

For example, the terminal device establishes an air interface connection with the access network device through the NR interface to transmit user plane data and control plane signaling; the terminal device can establish a control plane signaling connection with the AMF through the NG interface 1 (N1 for short); access Network equipment such as the next generation wireless access base station (gNB), can establish a user plane data connection with UPF through NG interface 3 (abbreviated as N3); access network equipment can establish control plane signaling with AMF through NG interface 2 (abbreviated as N2) connection; UPF can establish a control plane signaling connection with SMF through NG interface 4 (abbreviated as N4); UPF can exchange user plane data with the data network through NG interface 6 (abbreviated as N6); AMF can communicate with SMF through NG interface 11 (abbreviated as N11) The SMF establishes a control plane signaling connection; the SMF may establish a control plane signaling connection with the PCF through an NG interface 7 (N7 for short).

Figure 1 exemplarily shows a base station, a core network device, and two terminal devices. Optionally, the wireless communication system 100 may include multiple base station devices and each base station may include other numbers of terminals within the coverage area. The device is not limited in the embodiment of this application.

It should be understood that, in the embodiments of the present application, devices with a communication function in the network/system may be referred to as communication devices. Taking the communication system 100 shown in FIG. 1 as an example, the communication device may include a network device 120 and a terminal device 110 having a communication function, and the network device 120 and the terminal device 110 may be the devices described above, which will not be repeated here; The communication device may also include other devices in the communication system 100, such as network controllers, mobility management entities and other network entities, which are not limited in this embodiment of the present application.

It should be understood that the terms "system" and "network" are often used interchangeably herein. The term "and/or" in this article is just an association relationship describing associated objects, which means that there can be three relationships, for example, A and/or B can mean: A exists alone, A and B exist simultaneously, and there exists alone B these three situations. In addition, the character "/" in this article generally indicates that the contextual objects are an "or" relationship.

It should also be understood that the "correspondence" mentioned in the embodiments of the present application may mean that there is a direct correspondence or an indirect correspondence between the two, or that there is an association between the two, or that it indicates and is indicated. , configuration and configured relationship. It should also be understood that the "predefined" or "predefined rules" mentioned in the embodiments of this application can be used by pre-saving corresponding codes, tables or other It is implemented by indicating related information, and this application does not limit the specific implementation. For example, pre-defined may refer to defined in the protocol. It should also be understood that in the embodiment of the present application, the "protocol" may refer to a standard protocol in the communication field, for example, it may include the LTE protocol, the NR protocol, and related protocols applied to future communication systems, and this application does not limit this .

In a terrestrial cellular network, a measurement object (MO) will be configured according to a synchronization signal and/or physical broadcast channel block measurement timing configuration (SS/PBCH block measurement timing configuration, SMTC) and a measurement interval (Measurement Gap, MG ) to determine the measurement time index. When the terminal device determines the measurement time required by the MO, if the MO needs to use the MG for measurement, then determine the measurement time required for measuring the MO based on the period of the SMTC included in the MO and the period of the MG used by the MO ; If the MO does not need to use the MG for measurement, then determine the measurement time required for measuring the MO based on the period of the SMTC included in the MO.

However, in a non-terrestrial network (Non-Terrestrial Network, NTN), different satellites are in different orbital altitudes, positions, etc., resulting in a large difference in the propagation time between the terminal device and the satellite. From the perspective of the terminal equipment, the reference signal SSB received by it from other satellite cells is likely to deviate greatly from the SSB timing of the serving cell, and cannot be processed through the same SMTC window.

Therefore, NTN needs to support configuring multiple SMTCs with different time domain offsets on the same MO.

As shown in Figure 2, SMTC 1 and SMTC 2 are configured on the same MO, the SSB of cell 1 can be measured based on SMTC 1, and the SSB of cell 2 can be measured based on SMTC 2. The period of SMTC 1 is 40ms, its offset is 0ms, and its duration is 5ms; the period of SMTC 2 is 40ms, its offset is 10ms, and its duration is 5ms.

In order to facilitate the understanding of the solution provided by this application, the following describes the SMTC configured in the NTN network.

One or more SMTC configuration(s) associated to one frequency can be configured) can be configured. The SMTC configuration can be associated with a set of cells (e.g., per satellite or any other suitable set of cells determined by each gNB) (The SMTC configuration can be associated with a set of cells (e.g., per satellite or any other suitable set per gNB determination)). In addition to the traditional SMTC configuration, multiple SMTC configurations can be enabled by introducing different new offsets in addition to the legacy SMTC configuration.

In an MO with the same SSB frequency, the maximum number of SMTC configurations can be 4 (The specific maximum number of SMTC configuration in one measurement object with the same SSB Frequency can be 4).

In NTN, a NW-based solution is supported, i.e. the final SMTC and/or measurement interval configuration is generated by the NW in NTN and provided to a given UE (based on at least one target cell for a given UE and a given UE Propagation delay difference between serving cells in NTN)(In NTN,NW-based solution is supported,i.e.the final SMTC/measurement gap configuration is generated and provided by NW in NTN to a given UE(based on the propagation delay difference between at least one target cell and the serving cell of a given UE)). Further, in NTN, UE needs to report auxiliary information to NW (which can be configured by NW, or according to the requirements of NW) to assist NW to calculate the offset of SMTC configuration and/or measurement interval configuration (In NTN, it is necessary of the UE to report assistant information to the NW(which can be configured by NW or upon NW's request)to assist NW calculating the offset for SMTC/GAP configurations).

Multiple SMTCs can be configured for each carrier of the UE. However, although multiple SMTCs are configured, limited by network configuration or UE implementation, only a part of SMTCs can be used each time. You can further study whether UE can only use part or all of them in parallel. In this case, further research (For Further Study, FFS) can be implemented based on network configuration or UE (FFS if the UE can use only a partial set or all of them in parallel, and in case FFS whether based on network configuration or UE implementation).

In the following, a related solution for radio resource management (Radio Resource Management, RRM) measurement performed by a terminal device in a radio resource control (Radio Resource Control, RRC) connected state will be described.

RRM measurement includes co-frequency measurement and inter-frequency measurement, which can be further divided into measurement without MG (without MG) and measurement with MG (with MG). The measurement without MG mainly considers the SMTC cycle; the measurement with MG Synchronization signal and/or physical broadcast channel block measurement timing configuration (SS/PBCH block measurement timing configuration, SMTC) and measurement interval repetition period (Measurement Gap Repetition Period, MGRP) need to be considered.

It should be understood that the measurement interval involved in this application may refer to: a period of time agreed between the network device and the UE dedicated to measurement. During this period, since the network device has agreed that the UE is not required to transmit and receive, the UE can focus on measurement , without data sending and receiving; in essence, using MG is a time-sharing mechanism for data sending and receiving and mobility measurement. Since the frequency point to be measured configured on the network device side is not necessarily within the current working bandwidth of the UE, the relationship between mobility measurement and data transmission and reception needs to be coordinated during mobility measurement. If the UE wants to perform measurement on a frequency point outside the working bandwidth, the possible methods include the following two methods: the first one: if the UE does not have an idle radio frequency (radio frequency, RF) channel (channel), the UE can adjust a certain The parameters (such as center frequency, bandwidth, etc.) of a working RF channel can be measured. And after the measurement is completed, adjust the RF channel back to the parameters before the measurement to continue sending and receiving data. The second type: if the UE currently has an idle radio frequency channel (RF channel), the UE can use the idle radio frequency channel for measurement. For the first method, during the period from adjusting the radio frequency channel (RF channel) parameters to performing measurements and then adjusting back to the original radio frequency channel parameters, the original data transmission and reception of the UE cannot be performed. For the second method: it depends on the software and hardware capabilities of the UE, because a complete radio frequency channel needs the support of a complete set of resources such as radio frequency, baseband, and software protocol stack, and for cost considerations, the number of radio frequency channels supported by the UE is very limited. limited.

In addition, the frequency ranges of 5GNR are defined as different FRs: FR1 and FR2. Among them, the corresponding frequency range of FR1 includes 450MHz-6000MHz, also known as sub-6GHz frequency band) and the corresponding frequency range of FR2 includes 24250MHz-52600MHz, also known as above-6GHz or millimeter wave frequency band).

Based on whether MG is used, MO can be divided into the following four types: same frequency without MG (Intra-frequency without MG), same frequency with MG (Intra-frequency with MG), different frequency with MG (Inter-frequency with MG) ) and Inter-frequency without MG (Inter-frequency without MG). The calculation methods of the measurement time of these four types of MOs are described below in combination with Table 1 to Table 4. Table 1 can refer to the standard protocol 38 and take the measurement time of the same-frequency PSS/SSS detection in the FR1 frequency band (that is, Table 9.2.6.2-1 in the protocol 38.133) as an example, and can be adaptively modified for other measurement types. Table 1 corresponds to Table 9.2.5.1-1 in the protocol 38.133, indicating that the same frequency in the FR1 frequency band does not use MG’s PSS/SSS detection, and Table 2 corresponds to Table 9.2.6.2-1 in the protocol 38.133, indicating that the same frequency in the FR1 frequency band uses MG’s PSS/SSS detection, Table 3 corresponds to Table 9.3.4-1 in the protocol 38.133, indicating that the different frequency of the FR1 frequency band uses the PSS/SSS detection of the MG, Table 4 corresponds to Table 9.3.9.1-1 in the protocol 38.133, indicating the different frequency of the FR1 frequency band The PSS/SSS detection of the MG is not used frequently. Of course, the present application can also be applied to other measurement types. Correspondingly, Tables 1 to 4 can be adjusted and used as tables corresponding to other measurement types.

Table 1

As shown in Table 1, for an MO that does not use MG (Intra-frequency without MG) at the same frequency, the corresponding formula can be selected based on the DRX cycle to determine the measurement cycle of the MO.

Among them, K _p is a scaling factor considering the time domain overlap between SMTC and MG. Exemplarily, when the same-frequency SMTC is completely non-overlapping with the measurement interval or when the same-frequency SMTC is completely overlapping with the measurement interval, K _p =1 (When intra-frequency SMTC is fully non-overlapping with measurement gaps or intra-frequency SMTC is fully overlapping with MGs, _Kp = 1). When intra-frequency SMTC is partially overlapping with measurement gaps, K _p ＝1/(1-(SMTC period/MGRP)), where the SMTC period is less than MGRP (When intra-frequency SMTC is partially overlapping with measurement gaps, K _p ＝1/ (1-(SMTC period/MGRP)), where SMTC period<MGRP). For the calculation of _Kp , if the high-level signaling of SMTC2 is configured, for the cell indicated in the pci-List parameter in SMTC2, the SMTC period corresponds to the value of the high-level parameter SMTC2; for other cells, the SMTC period corresponds to the value of the high-level parameter SMTC1 Value (For calculation of Kp, if the high layer signaling of smtc2 is configured, for cells indicated in the pci-List parameter in smtc2, the SMTC periodicity corresponds to the value of higher layer parameter smtc2; for the other cells, the SMTC periodicity corresponds to the value of higher layer parameter smtc1).

Table 2

As shown in Table 2, for the MO that uses MG (Intra-frequency with MG) at the same frequency, the corresponding formula can be selected based on the DRX cycle to determine the measurement period of the MO.

table 3

As shown in Table 3, for the MO that uses MG (Inter-frequency with MG) at different frequencies, the corresponding formula can be selected based on the DRX cycle to determine the measurement period of the MO.

Table 4

As shown in Table 4, for MOs with inter-frequency without MG (Inter-frequency without MG), the corresponding formula can be selected based on the DRX cycle to determine the measurement cycle of the MO.

The CSSF _intra or CSSF _inter involved in the above Tables 1 to 4 will be described below.

The determination manner of CSSF _intra or CSSF _inter may include the determination manner within the MG (within MG) and the determination manner outside the MG (outside MG).

For L3RRM measurement, the following rules can be used to determine which way to determine CSSF _intra or CSSF _inter :

Exemplarily, for a measurement object (Measurement Object, MO) with the same frequency SSB and may not need MG, when its associated SMTC does not coincide with the MG occasion (occasion) at all, the determination method outside the MG is adopted; its associated When the timing of the SMTC and the MG partly coincide, the determination method outside the MG is adopted; when the timing of the associated SMTC completely coincides with the MG, the determination method within the MG is adopted.

Exemplarily, for an MO with an SSB of the same frequency and which may require an MG, only a determination method within the MG can be used, that is, the relationship between the SMTC and the MG is no longer considered.

Exemplarily, for inter-frequency SSB, when the UE supports version 16 no-interval inter-frequency measurement (interFrequencyMeas-Nogap-r16) capability, and the network device indicates version 16 no-interval inter-frequency measurement configuration (interFrequencyConfig-NoGap-r16) parameters, And when the inter-frequency SSB is within the active (active) bandwidth part (Bandwidth Part, BWP), the UE has the ability to measure the inter-frequency SSB outside the MG (outside MG). Further, which way to determine the CSSF _inter can be determined according to the relationship between the SMTC and the MG.

Exemplarily, for an MO with a different frequency SSB that may not require an MG, when its associated SMTC does not coincide with the MG at all, and the above-mentioned interFrequencyMeas-NoGap-r16 and interFrequencyConfig-NoGap-r16 conditions are met, the Determination method; when the associated SMTC overlaps with the MG occasion part, for a UE that supports CA capabilities and meets the above interFrequencyMeas-NoGap-r16 and interFrequencyConfig-NoGap-r16 conditions, the determination method outside the MG is adopted; When the associated SMTC is completely coincident with the MG, the determination method within the MG is used; for an MO with a different frequency SSB that may require the MG, only the determination method within the MG can be used.

Exemplarily, it may be directly specified in the agreement that the frequency band, frequency band combination or MO requires the MG or does not require the MG.

Exemplarily, the determining manner in the MG is to calculate the CSSF _intra or CSSF _inter by counting the number of MOs in the MG. The determination method outside the MG is to calculate CSSF _intra or CSSF _inter according to the number of statistically measured carriers. The CSSF _intra or CSSF _inter calculated in a definite way inside the MG is called CSSF _{within_gap,i} , and the CSSF _intra or CSSF _inter calculated in a definite way outside the MG is called CSSF _{outside_gap,i} . The calculation of CSSF _{outside_gap,i} and CSSF _{within_gap,i} is illustrated below.

Exemplarily, the network can allocate the proportion of the same frequency and different frequency measured in the MG through the parameter measGapSharingScheme.

If measGapSharingScheme is equal sharing/equal sharing (If measGapSharingScheme is equal sharing), CSSF _{within_gap,i} =max(ceil(R _i ×M _tot,i,j )),where j=0...(160/MGRP)-1.

If measGapSharingScheme is not equal sharing (If measGapSharingScheme is not equal sharing), measurement object i is an intra-frequency measurement object, CSSF _{within_gap, i} is the maximum value among subsequent multiple MG opportunities (measurement object i is an intra-frequency measurement object, CSSF _{within_gap,i} is the maximum among): ceil(R _i ×K _intra ×M intra,i,j ) in the interval M _inter _,i, j ≠0, where j=0...(160/MGRP)-1) , CSSF _{within_gap,i,j} =(ceil(R _i ×K _intra ×M _intra,i,j )in gaps where M _inter,i,j ≠0,where j=0...(160/MGRP)-1); ceil(R _i ×M _intra,i,j ) in the interval of M _inter, i,j =0, where j=0...(160/MGRP)-1), CSSF _{within_gap,i,j} =(ceil(R _i ×M _intra,i,j ) in gaps where M _inter,i,j =0,where j=0...(160/MGRP)-1). The measurement object i is an inter-frequency or inter-RAT measurement object or NR PRS measurement on any positioning frequency layer, CSSF _{within_gap, i} is the maximum value (measurement object i is an inter-frequency or inter-RAT measurement object or NR PRS measurement on any one positioning frequency layer, CSSF _{within_gap,i} is the maximum among): ceil(R _i ×K _inter ×M _inter,i,j ) in the interval of M _intra,i,j ≠0, where j= 0…(160/MGRP)-1(ceil(R _i ×K _inter ×M _inter,i,j ) in gaps where M _intra,i,j ≠0, where j=0…(160/MGRP)-1) ; ceil(R _i ×M _inter,i, _{j ) in the interval of M intra,i,} j =0 where j=0...(160/MGRP)-1).

Where R _i is the maximum ratio of the number of measurement intervals for which measurement object i is a candidate object to be measured to the number of measurement intervals for which measurement object i is a candidate and not used for the above-mentioned long-period measurement (Where R _i is the maximal ratio of the number of measurement gap where measurement object i is a candidate to be measured over the number of measurement gap where measurement object i is a candidate and not used for a long-periodicity measurement defined above).

M _intra,i,j : The number of measurement objects at the same frequency.

Exemplarily, M _intra,i,j is the number of candidate objects measured at the same frequency at interval j, including SSB, CSI-RS and RSSI/CO-based measurements, where measurement object i is also a candidate. Otherwise M _intra,i,j is equal to 0. (Number of intra-frequency measurement objects, including both SSB, CSI-RS based and RSSI/CO measurements, which are candidates to be measured in gap j where the measurement object i is also a candidate. Otherwise M _{intra, i, j} equals 0). M _intra,i,j represents the number of co-frequency MOs that can be measured within MG opportunity j.

M _inter,i,j : the number of NR inter-frequency layers.

Exemplarily, M _inter,i,j is the number of candidates for inter-frequency and inter-system (inter-RAT) measurement in interval j, including inter-RAT based on SSB and CSI-RS, EUTRA inter-RAT and UTRA inter- RAT frequency layer, at most one positioning frequency layer, RSSI/CO measurement, where measurement object i is also a candidate object, otherwise M _inter,i,j is equal to 0 (Number of NR inter-frequency layers including both SSB and CSI-RS based, EUTRA inter-RAT and UTRA inter-RAT frequency layers, up to one positioning frequency layer, RSSI/CO measurements, which are candidates to be measured in gap j where the measurement object i is also a candidate. Otherwise M _inter,i,j equals 0). M _inter,i,j represents the number of inter-frequency MOs that can be measured within MG opportunity j.

It should be noted that if the candidate measurement object i is configured with a received signal strength indication measurement timing configuration (Received Signal Strength Indication measurement timing configuration, RMTC) and SMTC at the same time, and both RMTC and SMTC belong to the candidate measurement object of interval opportunity j, The measurement object i in M _intra,i,j and M _inter,i,j is counted twice (A measurement object i in M _intra,i,j and in M _inter,i,j is counted twice if the measurement object is configured with both RMTC and SMTC which are candidates to be measured in gap j where the measurement object i is also a candidate). That is to say, if an MO is configured with RMTC and SMTC at the same time, it needs to be counted twice when performing MO statistics.

Exemplarily, the way of calculating the CSSF _{outside_gap,i} may include a way of calculating based on calculation formulas in various scenarios. For example, various scenarios include, but are not limited to: CA scenarios only for FR1, CA scenarios only for the same frequency band of FR2, CA scenarios only for different frequency bands of FR2, and FR1+FR2 CA. Further, CSSF _{outside_gap,i} may be determined by statistically measuring the number of carriers in each scenario. For example, the following CSSF _{outside_gap,i} are included: CSSF _{outside_gap,i} for FR1PCC (CSSF _{outside_gap,i} for FR1PCC), CSSF _{outside_gap,i} for FR1SCCC CSSF (CSSF _{outside_gap,i} for FR1SCC), CSSF _{outside_gap,i} for FR2 PCC (CSSF _{outside_gap,i} for FR2 PCC), CSSF _{outside_gap,i for} FR2 SCC that requires neighbor cell measurement (CSSF _{outside_gap,i} for FR2 SCC where neighbor cell measurement is required), for FR2 SCC that does not require neighbor cell measurement CSSF _{outside_gap,i} (CSSF _{outside_gap,i} for FR2 SCC where neighbor cell measurement is not required) and CSSF _{outside_gap,i} for inter-frequency MO without MG (CSSF _{outside_gap,i} for inter-frequency MO with no measurement gap) .

The calculation method of CSSF _{outside_gap,i} will be exemplarily described below in combination with Table 5.

table 5

As shown in Table 5, each carrier in each scenario may correspond to different methods for calculating CSSF _{outside_gap,i} .

Exemplarily, the FR1+FR2 inter-band CA only includes one FR1 operating band and one FR2 operating band (Only one FR1 operating band and one FR2 operating band are included for FR1+FR2 inter-band CA).

Exemplarily, when neighbor cell measurement is required, the selection of FR2 SCC follows clause 9.2.3.2 (Selection of FR2 SCC where neighbor cell measurement is required follows clause 9.2.3.2).

Exemplarily, CSSF _{outside_gap,i} =1, if only one SCell is configured and there is no inter-frequency MO without interval, and only SSB-based L3 measurement is configured on the SCC; CSSF _{outside_gap,i} =2, if only One SCell and there is no gapless inter-frequency MO, and SSB-based and CSI-RS-based L3 measurement or only CSI-RS-based L3 measurement is configured on the SCC (CSSF _{outside_gap,i} = 1 if only one SCell is configured and no inter-frequency MO without gap and only SSB based L3 measurement is configured on SCC; CSSF _{outside_gap,i} ＝2 if only one SCell is configured and no inter-frequency MO without gap and either both SSB and CSI-RS based L3 configured or only CSI-RS based L3 measurement is configured on SCC).

Exemplarily, Y is the number of configured inter-frequency MOs without MG, and these MOs can be measured outside the MG by CA-capable UEs; otherwise, it is 0 (Y is the number of configured inter-frequency MOs without MG that are being measured outside of MG for CA capable UE; otherwise, it is 0).

Exemplarily, the FR2 inter-band CA only includes two NR FR2 operating frequency bands (Only two NR FR2 operating bands are included for FR2 inter-band CA).

Exemplarily, N _{PCC_CSIRS} =1, if PCC is configured with SSB and CSI-RS based L3 or only CSI-RS based L3 measurement; otherwise, N _{PCC_CSIRS} =0(N _{PCC_CSIRS} =1 if PCC is with either both SSB and CSI-RS based L3 configured or only CSI-RS based L3 measurement configured; otherwise, N _{PCC_CSIRS} = 0).

Exemplarily, N _{SCC_CSIRS} = Number of configured SCell(s) with both SSB-based and CSI-RS-based L3 measurements configured or only CSI-RS-based L3 measurements configured ( _{NSCC_CSIRS} = Number of configured SCell(s) with either both SSB and CSI-RS based L3 measurement configured or only CSI-RS based L3 measurement configured).

Exemplarily, N _{SCC_CSIRS_FR2_NCM} =1, if FR2 SCC needs neighbor cell measurement, configure SSB and CSI-RS at the same time or only configure CSI-RS measurement; otherwise, N _{SCC_CSIRS_FR2_NCM} =0(N _{SCC_CSIRS_FR2_NCM} =1 if FR2 SCC, where neighbor cell measurement is required, is with either both SSB and CSI-RS configured or only CSI-RS measurement configured; otherwise, N _{SCC_CSIRS_FR2_NCM} = 0).

Exemplarily, N _{SCC_SSB} =Number of configured SCell(s) with only SSB based L3 measurement configured ( _{NSCC_SSB} =Number of configured SCell(s) with only SSB based L3 measurement configured).

Exemplarily, N _{PCC_CCA_RSSI/CO} = 1, if PSCC configures RSSI/CO measurement without MG when RMTC and SMTC overlap; N _{PCC_CCA_RSSI/CO} = 1, when RMTC and SMTC overlap, configure RSSI/CO measurement and Number of MOs for SCell(s) without MG (N _{PCC_CCA_RSSI/CO} ＝1 if PSCC is configured with RSSI/CO measurements without MG when RMTC and SMTC are overlapping; N _{SCC_CCA_RSSI/CO} ＝Number of MOs for SCell(s) configured with RSSI/CO measurements without MG when RMTC and SMTC are overlapping.).

In a non-terrestrial network (Non-Terrestrial Network, NTN), one MO is allowed to correspond to multiple SMTCs and multiple MGs. Therefore, when determining the measurement time required for measuring the MO, the measurement-related scheme in the terrestrial cellular network Not applicable to NTN. For example, since one MO in the terrestrial cellular network only considers one SMTC, it can be determined directly based on whether the MO is an MO that needs to use MG for measurement. However, since NTN allows one MO to correspond to multiple SMTCs and multiple MGs, and there is no relevant technical solution in the art on how to determine whether to use the MG for an MO corresponding to multiple SMTCs and multiple MGs.

In view of this, the embodiment of the present application provides a wireless communication method, a terminal device and a network device, for each SMTC among a plurality of SMTCs corresponding to one MO, it is determined whether the MG needs to be measured, and further, it is beneficial to calculate the MO Measure time and improve system performance.

Fig. 3 is a schematic flowchart of a wireless communication method 200 provided by an embodiment of the present application, and the wireless communication method 200 may be executed by a terminal device. For example, the wireless communication method 200 may be executed by the terminal device shown in FIG. 1 .

As shown in FIG. 3, the method 200 may include part or all of the following:

S210, the terminal device receives configuration information sent by the network device, where the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

S220. When the terminal device measures the first MO based on the first SMTC among the multiple SMTCs, determine whether to use the measurement interval MG.

In this embodiment, when the terminal device measures the first SMTC among the multiple SMTCs included in the first MO, it determines whether to use the MG. The MO is refined into the SMTCs included in the first MO, that is to say, the present application determines whether the MG is required for measurement for each of the multiple SMTCs corresponding to one MO, which is beneficial to the calculation of the measurement time of the MO and improve system performance.

In some embodiments, the S220 includes:

When the first MO is an MO that requires an MG to perform measurements, determine to use the MG;

When the first MO is a MO that does not need the MG to perform measurements, it is determined whether to use the MG based on whether there is an associated measurement interval MG in the first SMTC.

Exemplarily, when the first MO is an MO that requires an MG to perform measurements, the first SMTC uses MG by default; when the first MO is an MO that does not require an MG to perform measurements, based on the first SMTC Whether there is an associated measurement interval MG, determines whether the SMTC uses the MG.

In some embodiments, when there is no MG associated with the first SMTC, determine to use the MG or determine not to use the MG; when the number of MGs associated with the first SMTC is 1, determine to use the MG or determine not to use the MG; When the number of MGs associated with the first SMTC is greater than 1, it is determined to use the MG.

Exemplarily, when the first MO is an MO that does not require an MG to perform measurements, and the first SMTC is not associated with an MG, it is determined to use the MG or it is determined not to use the MG; the first MO does not require an MG When the MO that can perform measurements and the number of MGs associated with the first SMTC is 1, determine to use the MG or determine not to use the MG; the first MO is an MO that does not require the MG to perform measurements, and the first When the number of MGs associated with the SMTC is greater than 1, it is determined to use the MG.

Exemplarily, when the first SMTC does not have an associated MG, the first SMTC uses the MG by default or determines not to use the MG; when the number of MGs associated with the first SMTC is 1, the first SMTC defaults to No MG is used or the first SMTC uses the MG by default; when the number of MGs associated with the first SMTC is greater than 1, the first SMTC uses the MG by default.

It should be noted that, in this embodiment of the present application, it may be determined whether to use MG for each SMTC included in the first MO, or when it is determined that the first SMTC uses MG, and then calculate the value of each SMTC based on a corresponding formula. Measurement time required for one SMTC.

In some embodiments, the first SMTC does not have an associated MG or the number of associated MGs is greater than 1; the method 300 further includes:

When determining to use the MG, among the multiple MGs corresponding to the first SMTC, determine the first MG used by the first SMTC.

Exemplarily, since the first SMTC does not have an associated MG or the number of associated MGs is greater than 1, if the first SMTC does not use an MG by default, when calculating the measurement time required by the first SMTC, It is necessary to determine the first MG used by the first SMTC.

In some embodiments, the first MG is determined among the plurality of MGs based on at least one of the following information:

The period of each MG in the plurality of MGs, the period of the first SMTC, the time domain position of each MG, the time domain position of the first SMTC, and the measurement task associated with each MG.

Exemplarily, the terminal device may determine the first MG among the multiple MGs based on the cycle of each MG in the multiple MGs and the cycle of the first SMTC.

Exemplarily, the terminal device may determine the first MG among the multiple MGs based on the period of each MG in the multiple MGs.

Exemplarily, the terminal device may determine the first MG among the plurality of MGs based on the time domain position of each MG and the time domain position of the first SMTC.

Exemplarily, the terminal device may determine the first MG among the multiple MGs based on the measurement task associated with each MG.

Exemplarily, when the number of the multiple MGs is less than a certain threshold, the terminal device may determine the first MG among the multiple MGs based on the measurement task associated with each MG.

In some embodiments, the first MG is an MG whose cycle among the multiple MGs is the same as or closest to that of the first SMTC, or the first MG is a cycle among the multiple MGs The smallest or largest MG, or the first MG is the MG with the largest overlapping area with the first SMTC in the time domain among the multiple MGs, or the first MG is the MG associated with the multiple MGs The measurement task of the smallest MG.

Certainly, in other alternative embodiments, the first MG may also be an MG that satisfies at least one of the following: an MG whose cycle among the multiple MGs is the same as or closest to the cycle of the first SMTC , the MG with the smallest or largest cycle among the multiple MGs, the MG with the largest overlap area with the first SMTC in the time domain among the multiple MGs, and the smallest associated measurement task among the multiple MGs MG. This application does not specifically limit it.

In some embodiments, when the first SMTC does not have an associated MG, the multiple MGs are pre-configured MGs or MGs associated with the first MO; or, when the first SMTC has an associated MG , the multiple MGs are MGs associated with the first SMTC.

Exemplarily, the multiple MGs are predefined MGs.

Exemplarily, the MG associated with the first SMTC is a predefined MG.

Exemplarily, the terminal device acquires the MG associated with the first SMTC through an RRC message.

In some embodiments, when the measurement corresponding to the first SMTC is an intra-frequency measurement, it is used to determine the first MG information and when the measurement corresponding to the first SMTC is an inter-frequency measurement, it is used to determine the first MG. The information of the MG is the same or different; and/or, the method used to determine the first MG when the measurement corresponding to the first SMTC is a same-frequency measurement and the method used when the measurement corresponding to the first SMTC is a different-frequency measurement The methods for determining the first MG are the same or different.

Exemplarily, the terminal device may determine the method and/or information for determining the first MG based on whether the measurement corresponding to the first SMTC is an intra-frequency measurement or an inter-frequency measurement.

In some embodiments, the number of MGs associated with the first SMTC is 1; the method 300 further includes:

When determining to use the MG, determine the MG associated with the first SMTC as the first MG used by the first SMTC.

Exemplarily, when determining that the first SMTC uses the MG, the terminal device determines the MG associated with the first SMTC as the first MG used by the first SMTC.

In some embodiments, the terminal device receives first indication information sent by a network device, where the first indication information is used to indicate whether the first SMTC uses MG; information to determine whether to use MG.

Exemplarily, the network device indicates to the terminal device whether the first SMTC uses the MG.

Exemplarily, the first indication information may be carried in configuration information used to configure the first MO.

In some embodiments, the first indication information is further used to indicate the first MG used by the first SMTC.

Exemplarily, when the network device indicates to the terminal device that the first SMTC uses the MG, it also indicates to the terminal device the first MG used by the first SMTC.

In some embodiments, the first indication information is used to indicate that the MG used by the first SMTC is the MG associated with the first SMTC.

Exemplarily, when the network device indicates to the terminal device that the first SMTC uses the MG, it also indicates to the terminal device that the MG used by the first SMTC is the MG associated with the first SMTC.

In some embodiments, the first MO is an MO that requires an MG to perform measurements, and each SMTC in the plurality of SMTCs has an associated MG; or the first MO is an MO that does not require an MG to perform measurements , each of the multiple SMTCs has or does not have an associated MG.

Exemplarily, when the terminal device determines whether the first SMTC uses an MG and/or determines the first MG used by the first SMTC based on the first indication information, when the first SMTC has an associated MG, Then it is determined that the MG is used by the first SMTC, and further, the MG associated with the first SMTC may be determined as the first MG used by the first SMTC.

Exemplarily, when the first SMTC does not use an MG, the first SMTC has no associated MG; when the first SMTC uses an MG, the first SMTC is associated with an MG. That is to say, when the network device determines that the first SMTC does not use an MG, the first SMTC has no associated MG; when the network device determines that the first SMTC uses an MG, it can associate the first SMTC with the MG.

Exemplarily, when the first SMTC does not use an MG, the first SMTC has no associated MG or is associated with an MG.

Exemplarily, each of the multiple SMTCs is associated with an MG, or none of them is associated with an MG; that is, it is not allowed that only some of the SMTCs are equipped with an MG. In other words, the terminal device does not expect to configure the SMTC associated with the MG and the SMTC not associated with the MG in the same MO.

In some embodiments, the method 300 also includes:

Based on the measurement time of the SMTC with the largest period among the plurality of SMTCs, determining the first measurement time required for measuring the first MO; or

determining to measure the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs;

Wherein, when the i-th SMTC among the plurality of SMTCs does not use the MG, the measurement time of the i-th SMTC is determined according to the period of the i-th SMTC, and when the i-th SMTC uses an MG, the The measurement time of the i-th SMTC is determined according to the cycle of the i-th SMTC and the cycle of the MG used by the i-th SMTC.

Exemplarily, for the first MO including the multiple SMTCs, when determining the measurement time required by the first MO, the measurement time required for the first MO may be determined based on the measurement time required by a certain SMTC. The first measurement time may also determine the first measurement time required by the first MO in combination with the measurement time required by each SMTC in the plurality of SMTCs.

Exemplarily, the terminal device may determine, based on the capability of the terminal device and the number of the multiple SMTCs, the measurement time of the SMTC with the largest period among the multiple SMTCs, and determine the time to measure the first MO. The required first measurement time, or based on the measurement time of each SMTC in the plurality of SMTCs, determine to measure the first measurement time.

In some embodiments, when the terminal device supports simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use at the same time is greater than or equal to the number of the multiple SMTCs, the multiple SMTCs The measurement time of the SMTC with the largest medium period is determined as the first measurement time.

Exemplarily, when the terminal device supports simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use at the same time is greater than or equal to the number of the multiple SMTCs, if the period of the multiple SMTCs The largest SMTC uses the MG, then determine the first measurement time based on the period of the SMTC with the largest period among the multiple SMTCs and the period of the MG that is used by the SMTC with the largest period among the multiple SMTCs, otherwise, based on the period of each SMTC The cycle determines the measurement time it takes.

In some embodiments, when the terminal device does not support simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use simultaneously is less than the number of the multiple SMTCs, based on the multiple SMTCs The measurement time of each SMTC determines the first measurement time.

Exemplarily, when the terminal device does not support simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use simultaneously is less than the number of the multiple SMTCs, based on each of the multiple SMTCs The measurement time of the SMTC determines said first measurement time. For example, when each SMTC uses MG, determine the measurement time required by each SMTC based on the period of each SMTC and the period of the MG used by each SMTC; otherwise, based on the period of each SMTC The period of the SMTC is calculated as the measurement time hour of each SMTC.

In some embodiments, the SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs are divided into N SMTC groups, N>1; based on the measurement time of the N SMTC groups, determine the first - Measure time.

Exemplarily, N is a positive integer.

Exemplarily, the number of SMTCs included in each of the SMTC groups is less than or equal to the number of SMTCs that the terminal device supports to perform measurements at the same time.

Exemplarily, N is determined according to a ratio of the number of the multiple SMTCs to the number of SMTCs that the terminal device supports to perform simultaneous measurement. For example, N is a ratio of the number of the plurality of SMTCs to the number of SMTCs that the terminal device supports to perform measurement at the same time. For example, assuming that the multiple SMTCs are 4 SMTCs, but the terminal device can only support the simultaneous use of 2 SMTCs for measurement at most, then the number of SMTC groups that cannot be used in parallel is N=2.

In some embodiments, according to the following formula, the measurement times of the N SMTC groups are added to obtain the first measurement time:

Wherein, T _mo represents the first measurement time, T _i represents the measurement time of the i-th SMTC group among the N SMTC groups, and T _delta represents the time domain offset of the N SMTC groups.

Exemplarily, the terminal device may add the measurement times required by multiple SMTC packets that cannot be used in parallel (or in series) in a summation manner.

In this embodiment, when the terminal device supports simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use simultaneously is greater than or equal to the number of the multiple SMTCs, since the multiple SMTCs that cannot be used in parallel or can only be used in series are divided into N SMTC groups that can be used in series. Therefore, it is only necessary to add the measurement times of the N SMTC groups to obtain the first measurement time .

In some embodiments, T _delta =(N-1)×P _max , where P _max represents the period of the SMTC with the largest period among the multiple SMTCs and/or the measurement interval repetition period MGRP in the MG used by the multiple SMTCs Maximum MG period.

Exemplarily, when the multiple SMTCs do not use the MG, P _max represents the period of the SMTC with the largest period among the multiple SMTCs.

Exemplarily, when the multiple SMTCs all use MGs, P _max represents the maximum value of the MGRP and the SMTC period among the MGs used by the multiple SMTCs.

In some embodiments, the measurement time of the i-th SMTC group is the measurement time of the SMTC with the largest period in the i-th SMTC group.

It should be understood that the terminal device may measure the time of the SMTC with the largest period in the i-th SMTC group based on the corresponding formulas in Tables 1 to 4 above. To avoid repetition, details are not repeated here. In conjunction with Table 1, for example, assuming that the SMTC with the largest period in the ith SMTC group meets the condition of the same frequency and does not use MG, if there is no corresponding DRX for the SMTC with the largest period in the ith SMTC group, then Based on max(600ms, ceil(5×K _p )×SMTC period) ^{Note 1} ×CSSF _intra , determine the measurement time of the SMTC with the largest period in the ith SMTC group.

In some embodiments, the N SMTCs with the largest period among the plurality of SMTCs are respectively used as the SMTCs in the N SMTC groups; or the M SMTCs that overlap in the time domain among the plurality of SMTCs are divided Among different SMTC groups, M≤N.

Of course, in other alternative embodiments, M may also be greater than N. In this case, some SMTC packets or all SMTC packets in the N packets may include multiple SMTCs that overlap in the time domain. In addition, the terminal device may also determine the grouping based on other restrictive conditions, which is not specifically limited in this application.

In some embodiments, the terminal device determines the measurement of each SMTC based on the scaling factor of the SMTC level of each SMTC or the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs Time: the terminal device determines the first measurement time based on the measurement time of each SMTC.

Exemplarily, the terminal device may determine the measurement time of each SMTC based on the value obtained by correcting the period or K _p of each SMTC based on the scaling factor of the SMTC level of each SMTC, and then The first measurement time is determined based on the measurement time of each SMTC. That is to say, the scaling factor of the SMTC level of each SMTC can be used to adjust or modify the period or K _p of each SMTC.

Exemplarily, the terminal device may determine the measurement time of each SMTC based on the CSSF _intra or CSSF _inter determined by the number of SMTCs that cannot be used in parallel or can only be used in series among the multiple SMTCs, and then based on the The measurement time of each SMTC is determined to determine the first measurement time. That is to say, the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs can be used to determine CSSF _intra or CSSF _inter .

In some embodiments, the measurement time of the SMTC with the largest measurement time among the measurement times of the plurality of SMTCs is determined as the first measurement time.

In this embodiment, when determining the measurement time of each SMTC, the scaling factor of the SMTC level of each SMTC or the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs has been taken into account, Therefore, the measurement time of the SMTC with the largest measurement time among the measurement times of the plurality of SMTCs may be directly determined as the first measurement time.

In some embodiments, the i-th SMTC among the plurality of SMTCs is used for co-frequency measurement without using MG; the measurement time of the i-th SMTC is determined according to at least one of the following:

When there is no DRX, T _SMTCi =max(T _min ,ceil(N _sample ×K _p )×P _SMTCi )×CSSF _intra ;

When the period of DRX is less than or equal to 320ms, T _SMTCi =max(T _min ,ceil(M ₂ ×N _sample ×K _p )×max(P _SMTCi ,P _DRX ))×CSSF _intra ;

When the DRX period is greater than 320ms, T _SMTCi =ceil(N _sample ×K _p )×P _DRX ×CSSF _intra ;

Wherein, T _SMTCi represents the measurement time of the i-th SMTC, T _min is determined according to the type of the reference signal and/or the measurement purpose, N _sample is determined according to the type of the reference signal and/or the measurement purpose, and K _p is determined according to The overlap between the i-th SMTC and the MG corresponding to the i-th SMTC in the time domain is determined, P _SMTCi is determined according to the cycle of the i-th SMTC, P _DRX represents the cycle of DRX, and _M2 is determined according to the period of the network equipment The configuration information is determined, CSSF _intra indicates the scaling factor of the carrier level measured at the same frequency, ceil() indicates the rounding up operation, and max() indicates the maximum value operation;

Wherein, K _p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF _intra is determined according to the The number of SMTCs used in parallel or only in series is determined.

Exemplarily, T _min is a threshold value, and its value may be 0.

Exemplarily, N _sample is the number of samples.

Exemplarily, the measurement purpose includes but not limited to: PSS/SSS detection, SSB index detection, or mobility measurement.

Exemplarily, for the same-frequency PSS/SSS detection in the FR1 frequency band, T _min is 600 ms, and N _sample is 5.

Exemplarily, when K _p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, P _SMTCi is the period of the i-th SMTC, and CSSF _intra does not consider that the multiple SMTCs cannot be used in parallel or The number of SMTCs that can only be used serially.

Exemplarily, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, K _p does not consider the scaling factor of the SMTC level of the i-th SMTC, and CSSF _intra does not consider the multiple SMTCs The number of SMTCs that cannot be used in parallel or can only be used serially.

Exemplarily, when CSSF _intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, P _SMTCi is the period of the i-th SMTC, and K _p does not consider the i-th SMTC SMTC-level scaling factor for SMTCs.

Exemplarily, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, P _SMTCi =P _{SMTCi_initial} ×K _SMTCi ; wherein, P _{SMTCi_initial} represents the cycle of the i-th SMTC, and K _SMTCi represents the Scaling factor for the SMTC level of the i-th SMTC.

Exemplarily, K _p is also determined according to the scaling factor of the SMTC level of the ith SMTC. For example, for an MO that can be measured without an MG, when the i-th SMTC and the MG used by the i-th SMTC do not overlap or completely overlap in time domain, K _p =K _SMTCi ; and/or, When the i-th SMTC partially overlaps with the MG used by the i-th SMTC in the time domain, then K _p =K _SMTCi /(1-(P _{SMTCi_initial} /T _MGRPi )), where K _SMTCi represents the The scaling factor of the SMTC level of the i SMTC, P _{SMTCi_initial} indicates the period of the i th SMTC, and T _MGRPi indicates the measurement interval repetition period MGRP of the i th SMTC using MG.

Exemplarily, the terminal device may determine the measurement time for the i-th SMTC to perform same-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 6-1.

Table 6-1

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×K _p)×P _SMTCi)×CSSF _intra max(600ms,ceil(5×K _p )×P _SMTCi )×CSSF _intra
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(M ₂×5×K _p)×max(P _SMTCi,P _DRX))×CSSF _intra max(600ms,ceil(M ₂ ×5×K _p )×max(P _SMTCi ,P _DRX ))×CSSF _intra
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p)×P _DRX×CSSF _intra ceil(5×K _p )×P _DRX ×CSSF _intra

As shown in Table 6-1, for an SMTC with Intra-frequency without MG (Intra-frequency without MG) on the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. Wherein, K _p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF _intra is determined according to the The number of SMTCs used in parallel or only in series is determined.

Exemplarily, _Kp is also determined according to the scaling factor of the SMTC level of the i-th SMTC, which can also be understood as: modifying the K involved in Table 1 above through the scaling factor of the SMTC level of the i-th SMTC _p , that is to say, the terminal device can determine the measurement time for the ith SMTC to perform same-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 6-2.

Table 6-2

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×K _p×K _SMTCi)×P _SMTCi)×CSSF _intra max(600ms,ceil(5×K _p ×K _SMTCi )×P _SMTCi )×CSSF _intra
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(M ₂×5×K _p×K _SMTCi)×max(P _SMTCi,P _DRX))×CSSF _intra max(600ms,ceil(M ₂ ×5×K _p ×K _SMTCi )×max(P _SMTCi ,P _DRX ))×CSSF _intra
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p×K _SMTCi)×P _DRX×CSSF _intra ceil(5×K _p ×K _SMTCi )×P _DRX ×CSSF _intra

As shown in Table 6-2, for an SMTC with Intra-frequency without MG (Intra-frequency without MG) on the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, K _p , P _SMTCi , and CSSF _intra in the table can be respectively equivalent to K _p , the period of SMTC, and CSSF _intra in Table 1. To avoid repetition, details are not repeated here.

Exemplarily, P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, which can also be understood as: modifying the cycle of the ith SMTC through the scaling factor of the SMTC level of the i-th SMTC, That is to say, the terminal device can determine the measurement time for the i-th SMTC to perform same-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 6-3.

Table 6-3

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×K _p)×P _SMTCi×K _SMTCi)×CSSF _intra max(600ms,ceil(5×K _p )×P _SMTCi ×K _SMTCi )×CSSF _intra
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(M ₂×5×K _p)×max(P _SMTCi×K _SMTCi,P _DRX))×CSSF _intra max(600ms,ceil(M ₂ ×5×K _p )×max(P _SMTCi ×K _SMTCi ,P _DRX ))×CSSF _intra
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p)×P _DRX×CSSF _intra ceil(5×K _p )×P _DRX ×CSSF _intra

As shown in Table 6-3, for an SMTC with Intra-frequency without MG (Intra-frequency without MG) on the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, K _p , P _SMTCi , and CSSF _intra in the table can be respectively equivalent to K _p , the period of SMTC, and CSSF _intra in Table 1. To avoid repetition, details are not repeated here.

Exemplarily, CSSF _intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, and can also be understood as: correcting the i-th SMTC by the scaling factor of the SMTC level of the i-th SMTC The CSSF _intra of the i SMTC, that is to say, the terminal device can determine the measurement time for the i-th SMTC to perform intra-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 6-4.

Table 6-4

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×K _p)×P _SMTCi)×CSSF _intra×K _SMTCi max(600ms,ceil(5×K _p )×P _SMTCi )×CSSF _intra ×K _SMTCi
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(M ₂×5×K _p)×max(P _SMTCi,P _DRX))×CSSF _intra×K _SMTCi max(600ms,ceil(M ₂ ×5×K _p )×max(P _SMTCi ,P _DRX ))×CSSF _intra ×K _SMTCi
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p)×P _DRX×CSSF _intra×K _SMTCi ceil(5×K _p )×P _DRX ×CSSF _intra ×K _SMTCi

As shown in Table 6-4, for an SMTC with Intra-frequency without MG (Intra-frequency without MG) on the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, K _p , P _SMTCi , and CSSF _intra in the table can be respectively equivalent to K _p , the period of SMTC, and CSSF _intra in Table 1. To avoid repetition, details are not repeated here.

In some embodiments, the i-th SMTC among the plurality of SMTCs is used for co-frequency measurement and uses an MG; the measurement time for the i-th SMTC to perform PSS/SSS detection is determined according to at least one of the following:

When there is no DRX, T _SMTCi =max(T _min ,N _sample ×max(T _MGRPi ,P _SMTCi ))×CSSF _intra ;

When the period of DRX is less than or equal to 320ms, T _SMTCi =max(T _min ,ceil(M ₂ ×N _sample )×max(T _MGRPi ,P _SMTCi ,P _DRX ))×CSSF _intra ;

When the DRX period is greater than 320ms, T _SMTCi =N _sample ×max(T _MGRPi ,P _DRX )×CSSF _intra ;

Wherein, T _SMTCi represents the measurement time of the i-th SMTC, T _MGRPi represents the measurement interval repetition period MGRP of the i-th SMTC using MG, P _SMTCi is determined according to the cycle of the i-th SMTC, and P _DRX represents the DRX period, _M2 is determined according to the information configured by the network device, CSSF _intra represents the scaling factor of the carrier level measured at the same frequency, ceil() represents an upward rounding operation, and max() represents the maximum value operation;

Wherein, _PSMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF _intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.

Exemplarily, T _min is a threshold value, and its value may be 0.

Exemplarily, N _sample is the number of samples.

Exemplarily, for PSS/SSS detection, T _min is 600ms, and N _sample is 5.

Exemplarily, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the ith SMTC, CSSF _intra does not consider the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.

Exemplarily, when CSSF _intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, P _SMTCi is the period of the ith SMTC.

Exemplarily, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, the P _SMTCi =P _{SMTCi_initial} ×K _SMTCi ; wherein, P _{SMTCi_initial} represents the period of the i-th SMTC, and K _SMTCi Indicates the scaling factor of the SMTC level of the i-th SMTC.

Exemplarily, the terminal device may determine the measurement time for the i-th SMTC to perform same-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 7-1.

Table 7-1

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,5×max(T _MGRPii,P _SMTCi))×CSSF _intra max(600ms,5×max(T _MGRPii ,P _SMTCi ))×CSSF _intra
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(M ₂×5)×max(T _MGRPi,P _SMTCi,P _DRX))×CSSF _intra max(600ms,ceil(M ₂ ×5)×max(T _MGRPi ,P _SMTCi ,P _DRX ))×CSSF _intra
DRX的周期>320msDRX cycle>320ms	5×max(T _MGRPi,P _DRX)×CSSF _intra 5×max(T _MGRPi ,P _DRX )×CSSF _intra

As shown in Table 7-1, for the SMTC using MG (Intra-frequency with MG) at the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. Wherein, _PSMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF _intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.

Exemplarily, P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, which can also be understood as: modifying the cycle of the ith SMTC through the scaling factor of the SMTC level of the i-th SMTC, That is to say, the terminal device can determine the measurement time for the i-th SMTC to perform same-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 7-2 or Table 7-3.

Table 7-2

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,5×max(T _MGRPii,P _SMTCi×K _SMTC))×CSSF _intra max(600ms,5×max(T _MGRPii ,P _SMTCi ×K _SMTC ))×CSSF _intra
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(M ₂×5)×max(T _MGRPi,P _SMTCi×K _SMTCi,P _DRX))×CSSF _intra max(600ms,ceil(M ₂ ×5)×max(T _MGRPi ,P _SMTCi ×K _SMTCi ,P _DRX ))×CSSF _intra
DRX的周期>320msDRX cycle>320ms	5×max(T _MGRPi,P _DRX)×CSSF _intra 5×max(T _MGRPi ,P _DRX )×CSSF _intra

Table 7-3

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,5×max(T _MGRPii,P _SMTCi)×K _SMTC)×CSSF _intra max(600ms,5×max(T _MGRPii ,P _SMTCi )×K _SMTC )×CSSF _intra
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(M ₂×5)×max(T _MGRPi,P _SMTCi,P _DRX)×K _SMTC)×CSSF _intra max(600ms,ceil(M ₂ ×5)×max(T _MGRPi ,P _SMTCi ,P _DRX )×K _SMTC )×CSSF _intra
DRX的周期>320msDRX cycle>320ms	5×max(T _MGRPi,P _DRX)×K _SMTC×CSSF _intra 5×max(T _MGRPi ,P _DRX )×K _SMTC ×CSSF _intra

As shown in Table 7-2 or 7-3, for the SMTC using MG (Intra-frequency with MG) at the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, T _MGRPi , P _SMTCi , and CSSF _intra in the table can be respectively equivalent to MGRP, SMTC period, and CSSF _intra of the MG in Table 2. To avoid repetition, details are not repeated here.

Exemplarily, CSSF _intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, and can also be understood as: correcting the i-th SMTC by the scaling factor of the SMTC level of the i-th SMTC The CSSF _intra of the i SMTC, that is to say, the terminal device can determine the measurement time for the i-th SMTC to perform intra-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 7-4.

Table 7-4

As shown in Table 7-4, for an SMTC with Intra-frequency without MG (Intra-frequency without MG) on the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, T _MGRPi , P _SMTCi , and CSSF _intra in the table can be respectively equivalent to MGRP, SMTC period, and CSSF _intra of the MG in Table 2. To avoid repetition, details are not repeated here.

In some embodiments, the i-th SMTC among the plurality of SMTCs is used for inter-frequency measurement and uses an MG; the measurement time for the i-th SMTC to perform PSS/SSS detection is determined according to at least one of the following:

When there is no DRX, T _SMTCi =max(T _min ,N _sample ×max(T _MGRPi ,P _SMTCi ))×CSSF _inter ;

When the DRX period is less than or equal to 320ms, T _SMTCi =max(T _min ,Ceil(N _sample ×M ₃ )×max(T _MGRPi ,P _SMTCi ,P _DRX ))×CSSF _inter ;

When the DRX cycle is greater than 320ms, T _SMTCi = N _sample × P _DRX × CSSF _inter ;

Wherein, T _SMTCi represents the measurement time of the i-th SMTC, T _min is determined according to the type of the reference signal and/or the measurement purpose, N _sample is determined according to the type of the reference signal and/or the measurement purpose, and T _MGRPi represents The i-th SMTC uses the MG measurement interval repetition cycle MGRP, P _SMTCi is determined according to the cycle of the i-th SMTC, P _DRX represents the cycle of DRX, M ₃ is determined according to the information configured by the network device, and CSSF _inter represents inter-frequency The scaling factor of the measured carrier level, ceil() means the rounding up operation, max() means the maximum value operation;

Wherein, P _SMTCi is also determined according to the scaling factor of the SMTC level of the ith SMTC, or CSSF _inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the multiple SMTCs.

Exemplarily, T _min is a threshold value, and its value may be 0.

Exemplarily, N _sample is the number of samples.

Exemplarily, for inter-frequency PSS/SSS detection of FR1, T _min is 600 ms, and N _sample is 8.

Exemplarily, for inter-frequency PSS/SSS detection of FR1, M ₃ is 1 or 1.5.

Exemplarily, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the ith SMTC, CSSF _inter does not consider the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.

Exemplarily, when CSSF _inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, T _MGRPi is the measurement interval repetition period MGRP of the MG used by the ith SMTC.

Exemplarily, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, the P _{SMTCi i} =P _{SMTCii_initial} ×K _SMTCi ; wherein, P _{SMTCi_initial} represents the period of the i-th SMTC, K _SMTCi represents the scaling factor of the SMTC level of the i-th SMTC.

Exemplarily, the terminal device may determine the measurement time for the i-th SMTC to perform inter-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 8-1.

Table 8-1

DRX的周期DRX cycle	T _{PSS/SSS_sync_inter} T _{PSS/SSS_sync_inter}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,8×max(T _MGRPi,P _SMTCi))×CSSF _inter max(600ms,8×max(T _MGRPi ,P _SMTCi ))×CSSF _inter
DRX的周期≤320msDRX cycle≤320ms	max(600ms,Ceil(8×1.5)×max(T _MGRPi,P _SMTCi,P _DRX))×CSSF _inter max(600ms, Ceil(8×1.5)×max(T _MGRPi ,P _SMTCi ,P _DRX ))×CSSF _inter
DRX的周期>320msDRX cycle>320ms	8×P _DRX×CSSF _inter 8×P _DRX ×CSSF _inter

As shown in Table 8-1, for the SMTC with inter-frequency with MG (Inter-frequency with MG), you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. Wherein, P _SMTCi is also determined according to the scaling factor of the SMTC level of the ith SMTC, or CSSF _inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the multiple SMTCs.

Exemplarily, P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, which can also be understood as: modifying the cycle of the ith SMTC through the scaling factor of the SMTC level of the i-th SMTC, That is to say, the terminal device can determine the measurement time for the i-th SMTC to perform inter-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 8-2 or Table 8-3.

Table 8-2

DRX的周期DRX cycle	T _{PSS/SSS_sync_inter} T _{PSS/SSS_sync_inter}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,8×max(T _MGRPi,P _SMTCi×K _SMTCi))×CSSF _inter max(600ms,8×max(T _MGRPi ,P _SMTCi ×K _SMTCi ))×CSSF _inter
DRX的周期≤320msDRX cycle≤320ms	max(600ms,Ceil(8×1.5)×max(T _MGRPi,P _SMTCi×K _SMTCi,P _DRX))×CSSF _inter max(600ms,Ceil(8×1.5)×max(T _MGRPi ,P _SMTCi ×K _SMTCi ,P _DRX ))×CSSF _inter
DRX的周期>320msDRX cycle>320ms	8×P _DRX×CSSF _inter 8×P _DRX ×CSSF _inter

Table 8-3

DRX的周期DRX cycle	T _{PSS/SSS_sync_inter} T _{PSS/SSS_sync_inter}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,8×max(T _MGRPi,P _SMTCi))×K _SMTCi×CSSF _inter max(600ms,8×max(T _MGRPi ,P _SMTCi ))×K _SMTCi ×CSSF _inter
DRX的周期≤320msDRX cycle≤320ms	max(600ms,Ceil(8×1.5)×max(T _MGRPi,P _SMTCi,P _DRX)×K _SMTCi)×CSSF _inter max(600ms,Ceil(8×1.5)×max(T _MGRPi ,P _SMTCi ,P _DRX )×K _SMTCi )×CSSF _inter
DRX的周期>320msDRX cycle>320ms	8×P _DRX×CSSF _inter 8×P _DRX ×CSSF _inter

As shown in Table 8-2 or 8-3, for SMTC using MG (Inter-frequency with MG) at different frequencies, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement period. At this time, T _MGRPi , P _SMTCi , and CSSF _inter in the table can be respectively equivalent to MGRP, SMTC period, and CSSF _inter of the MG in Table 2. To avoid repetition, details are not repeated here.

Exemplarily, the CSSF _inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, and can also be understood as: modifying the SMTC level scaling factor of the i-th SMTC The CSSF _inter of the i SMTC, that is to say, the terminal device can determine the measurement time for the i-th SMTC to perform inter-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 8-4.

Table 8-4

DRX的周期DRX cycle	T _{PSS/SSS_sync_intra} T _{PSS/SSS_sync_intra}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,8×max(T _MGRPi,P _SMTCi))×CSSF _inter×K _SMTCi max(600ms,8×max(T _MGRPi ,P _SMTCi ))×CSSF _inter ×K _SMTCi
DRX的周期≤320msDRX cycle≤320ms	max(600ms,Ceil(8×1.5)×max(T _MGRPi,P _SMTCi,P _DRX))×CSSF _inter×K _SMTCi max(600ms,Ceil(8×1.5)×max(T _MGRPi ,P _SMTCi ,P _DRX ))×CSSF _inter ×K _SMTCi
DRX的周期>320msDRX cycle>320ms	8×P _DRX×CSSF _inter×K _SMTCi 8×P _DRX ×CSSF _inter ×K _SMTCi

As shown in Table 8-4, for an SMTC with Intra-frequency without MG (Intra-frequency without MG) on the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, T _MGRPi , P _SMTCi , and CSSF _inter in the table may be respectively equivalent to the SMTC period, SMTC period, and CSSF _inter in Table 2. To avoid repetition, details are not repeated here.

In some embodiments, the i-th SMTC among the plurality of SMTCs is used for inter-frequency measurement and does not use MG; the measurement time of the i-th SMTC is determined according to at least one of the following:

When there is no DRX, T _SMTCi =max(T _min ,ceil(N _sample ×Kp)×P _SMTCi )×CSSF _inter ;

When the DRX period is less than or equal to 320ms, T _SMTCi =max(T _min ,ceil(M ₃ ×N _sample ×K _p )×max(P _SMTCi ,P _DRX ))×CSSF _inter ;

When the DRX period is greater than 320ms, T _SMTCi =ceil(N _sample ×K _p )×P _DRX ×CSSF _inter ;

Wherein, T _SMTCi represents the measurement time of the i-th SMTC, T _min is determined according to the type of the reference signal and/or the measurement purpose, N _sample is determined according to the type of the reference signal and/or the measurement purpose, and K _p is determined according to The overlap between the i-th SMTC and the MG corresponding to the i-th SMTC in the time domain is determined, P _SMTCi is determined according to the cycle of the i-th SMTC, P _DRX represents the cycle of DRX, and _M3 is determined according to the period of the network equipment The configuration information is determined, CSSF _inter indicates the scaling factor of the carrier level of the inter-frequency measurement, ceil() indicates the upward rounding operation, and max() indicates the maximum value operation;

Wherein, K _p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF _inter is determined according to the The number of SMTCs used in parallel or only in series is determined.

Exemplarily, T _min is a threshold value, and its value may be 0.

Exemplarily, N _sample is the number of samples.

Exemplarily, for inter-frequency PSS/SSS detection in the FR1 frequency band, T _min is 600 ms, and N _sample is 5.

Exemplarily, for inter-frequency PSS/SSS detection of FR1, M ₃ is 1 or 1.5.

Exemplarily, when _Kp is also determined according to the scaling factor of the SMTC level of the i-th SMTC, P _SMTCi is the period of the i-th SMTC, and CSSF _inter does not consider that the multiple SMTCs cannot be used in parallel or The number of SMTCs that can only be used serially.

Exemplarily, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, K _p does not consider the scaling factor of the SMTC level of the i-th SMTC, and CSSF _inter does not consider the multiple SMTC The number of SMTCs that cannot be used in parallel or can only be used serially.

Exemplarily, when CSSF _inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, P _SMTCi is the period of the i-th SMTC, and K _p does not consider the i-th SMTC SMTC-level scaling factor for SMTCs.

Exemplarily, K _p is also determined according to the scaling factor of the SMTC level of the ith SMTC. For example, when the i-th SMTC and the MG used by the i-th SMTC do not overlap or completely overlap in the time domain, K _p =K _SMTCi ; and/or, the i-th SMTC and the i-th SMTC When the MGs used by i SMTC partially overlap in the time domain, then K _p =K _SMTCi /(1-(P _{SMTCi_initial} /T _MGRPi )), where K _SMTCi represents the scaling factor of the SMTC level of the i-th SMTC , P _{SMTCi_initial} represents the cycle of the i-th SMTC, and T _MGRPi represents the measurement interval repetition cycle MGRP of the i-th SMTC using the MG.

Exemplarily, the terminal device may determine the measurement time for the i-th SMTC to perform inter-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 9-1.

Table 9-1

DRX的周期DRX cycle	T _{PSS/SSS_sync_inter} T _{PSS/SSS_sync_inter}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×Kp)×P _SMTCi)×CSSF _inter max(600ms, ceil(5×Kp)×P _SMTCi )×CSSF _inter
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(1.5×5×K _p)×max(P _SMTCi，P _DRX))×CSSF _inter max(600ms,ceil(1.5×5×K _p )×max(P _SMTCi ,P _DRX ))×CSSF _inter
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p)×P _DRX×CSSF _inter ceil(5×K _p )×P _DRX ×CSSF _inter

As shown in Table 9-1, for SMTC with inter-frequency without MG (Inter-frequency without MG), you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. Wherein, K _p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF _intra is determined according to the The number of SMTCs used in parallel or only in series is determined.

Exemplarily, _Kp is also determined according to the scaling factor of the SMTC level of the i-th SMTC, which can also be understood as: modifying the above mentioned table 4 through the scaling factor of the SMTC level of the i-th SMTC K _p , that is to say, the terminal device can determine the measurement time for the ith SMTC to perform inter-frequency PSS/SSS detection in the FR1 frequency band according to Table 9-2 below.

Table 9-2

DRX的周期DRX cycle	T _{PSS/SSS_sync_inter} T _{PSS/SSS_sync_inter}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×Kp×K _SMTCi)×P _SMTCi)×CSSF _inter max(600ms,ceil(5×Kp×K _SMTCi )×P _SMTCi )×CSSF _inter
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(1.5×5×K _p×K _SMTCi)×max(P _SMTCi，P _DRX))×CSSF _inter max(600ms,ceil(1.5×5×K _p ×K _SMTCi )×max(P _SMTCi ,P _DRX ))×CSSF _inter
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p×K _SMTCi)×P _DRX×CSSF _inter ceil(5×K _p ×K _SMTCi )×P _DRX ×CSSF _inter

As shown in Table 9-2, for SMTC with inter-frequency without MG (Inter-frequency without MG), you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, K _p , P _SMTCi , and CSSF _inter in the table can be respectively equivalent to K _p , the period of SMTC, and CSSF _inter in Table 4. To avoid repetition, details are not repeated here.

Exemplarily, P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, which can also be understood as: through the period of the i-th SMTC, that is to say, the terminal device can follow the following table 9- 3 or Table 9-4 to determine the measurement time for the ith SMTC to perform inter-frequency PSS/SSS detection in the FR1 frequency band.

Table 9-3

DRX cycle

T _{PSS/SSS_sync_inter}

不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×Kp)×P _SMTCi×K _SMTCi)×CSSF _inter max(600ms,ceil(5×Kp)×P _SMTCi ×K _SMTCi )×CSSF _inter
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(1.5×5×K _p)×max(P _SMTCi×K _SMTCi，P _DRX))×CSSF _inter max(600ms, ceil(1.5×5×K _p )×max(P _SMTCi ×K _SMTCi ,P _DRX ))×CSSF _inter
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p)×P _DRX×CSSF _inter ceil(5×K _p )×P _DRX ×CSSF _inter

Table 9-4

DRX的周期DRX cycle	T _{PSS/SSS_sync_inter} T _{PSS/SSS_sync_inter}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×Kp)×P _SMTCi×K _SMTCi)×CSSF _inter max(600ms,ceil(5×Kp)×P _SMTCi ×K _SMTCi )×CSSF _inter
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(1.5×5×K _p)×max(P _SMTCi，P _DRX)×K _SMTCi)×CSSF _inter max(600ms,ceil(1.5×5×K _p )×max(P _SMTCi ,P _DRX )×K _SMTCi )×CSSF _inter
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p)×P _DRX×CSSF _inter ceil(5×K _p )×P _DRX ×CSSF _inter

As shown in Table 9-3 or Table 9-4, for SMTC with inter-frequency without MG (Inter-frequency without MG), you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, K _p , P _SMTCi , and CSSF _inter in the table can be respectively equivalent to K _p , the period of SMTC, and CSSF _inter in Table 4. To avoid repetition, details are not repeated here.

Exemplarily, the CSSF _inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs, and can also be understood as: modifying the SMTC level scaling factor of the i-th SMTC The CSSF _inter of the i SMTC, that is to say, the terminal device can determine the measurement time for the i-th SMTC to perform inter-frequency PSS/SSS detection in the FR1 frequency band according to the following Table 9-5.

Table 9-5

DRX的周期DRX cycle	T _{PSS/SSS_sync_inter} T _{PSS/SSS_sync_inter}
不存在DRX(No DRX)There is no DRX (No DRX)	max(600ms,ceil(5×Kp)×P _SMTCi)×CSSF _inter×K _SMTCi max(600ms,ceil(5×Kp)×P _SMTCi )×CSSF _inter ×K _SMTCi
DRX的周期≤320msDRX cycle≤320ms	max(600ms,ceil(1.5×5×K _p)×max(P _SMTCi，P _DRX))×CSSF _inter×K _SMTCi max(600ms,ceil(1.5×5×K _p )×max(P _SMTCi ,P _DRX ))×CSSF _inter ×K _SMTCi
DRX的周期>320msDRX cycle>320ms	ceil(5×K _p)×P _DRX×CSSF _inter×K _SMTCi ceil(5×K _p )×P _DRX ×CSSF _inter ×K _SMTCi

As shown in Table 9-5, for an SMTC with Intra-frequency without MG (Intra-frequency without MG) on the same frequency, you can select the corresponding formula based on the DRX cycle to determine the SMTC measurement cycle. At this time, K _p , P _SMTCi , and CSSF _inter in the table can be respectively equivalent to K _p , the period of SMTC, and CSSF _inter in Table 4. To avoid repetition, details are not repeated here.

In some embodiments, the method 300 also includes:

Based on the overlapping of the i-th SMTC and the MG associated with the i-th SMTC, determine the CSSF _intra or CSSF _inter determination method, the CSSF _intra or CSSF _inter determination method includes: using the CSSF _intra to determine outside the MG Either the first determination method of CSSF _inter , or the second determination method of determining CSSF _intra or CSSF _inter in the MG.

Exemplarily, when the i-th SMTC does not use an MG, the method for determining CSSF _intra or CSSF _inter is determined based on the overlap between the i-th SMTC and the MG associated with the i-th SMTC.

Exemplarily, when the number of MGs associated with the i-th SMTC is 1, the terminal device determines CSSF _intra or CSSF _inter based on the overlap between the i-th SMTC and the MG associated with the i-th SMTC Way.

Exemplarily, when the i-th SMTC does not have an associated MG, the terminal device may associate an MG with the i-th SMTC, and then based on the i-th SMTC and the i-th SMTC associated MG In case of overlap, determine how to determine CSSF _intra or CSSF _inter .

Exemplarily, when the number of MGs associated with the i-th SMTC is greater than 1, the terminal device may select an MG among multiple MGs associated with the i-th SMTC, and then based on the i-th SMTC and the selected MG The overlap of CSSF _intra or CSSF _inter is determined.

It should be understood that the present application does not limit the specific implementation manner in which the terminal device associates an MG with the i-th SMTC and the terminal device selects an MG from multiple MGs associated with the i-th SMTC. For example, the scheme that the terminal device associates an MG with the i-th SMTC may associate an MG with the i-th SMTC among preset multiple MGs. For another example, the solution for the terminal device to select an MG among the plurality of MGs associated with the ith SMTC may refer to the above-described solution for the terminal device to determine the first MG used by the first SMTC.

Exemplarily, the first determining manner calculates CSSF _intra or CSSF _inter according to the number of statistically measured carriers. The second determining manner calculates CSSF _intra or CSSF _inter by counting the number of MOs in the MG. The CSSF _intra or CSSF _inter calculated by the first determination method is called CSSF _{outside_gap,i} . The CSSF _intra or CSSF _inter calculated by the second determination method is called CSSF _{within_gap,i} , and the calculation of CSSF _{outside_gap,i} and CSSF _{within_gap,i} will be exemplified below.

Exemplarily, when the i-th SMTC does not use an MG, the terminal device determines the CSSF _intra or CSSF _inter is CSSF _{outside_gap,i} or CSSF _{within_gap,i} .

In some embodiments, when the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, it is determined to use the first determination method; the i-th SMTC is associated with the i-th SMTC When the MGs of the i-th SMTC and the MG associated with the i-th SMTC completely overlap, determine to use the second determination method.

Exemplarily, when the i-th SMTC uses an MG, and the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, it is determined to use the first determination method; the i-th SMTC When MG is used, and the i-th SMTC and the MG part associated with the i-th SMTC overlap, it is determined to use the first determination method; the i-th SMTC uses an MG, and the i-th SMTC and When the MG associated with the i-th SMTC is completely coincident, it is determined to use the second determination manner.

In some embodiments, when the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, it is determined to use the first determination method; the i-th SMTC is associated with the i-th SMTC When the MGs of the i-th SMTC and the MG associated with the i-th SMTC are completely overlapped, determine to use the first determination method when the terminal device has the capability of carrier aggregation CA; Describe the second determination method.

Exemplarily, when the i-th SMTC uses an MG, and the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, it is determined to use the first determination method; the i-th SMTC When the MG is used, the i-th SMTC and the MG associated with the i-th SMTC overlap partially, and the terminal device has the capability of carrier aggregation CA, determine to use the first determination method; the i-th SMTC When an MG is used and the i-th SMTC is completely coincident with the MG associated with the i-th SMTC, it is determined to use the second determination manner.

In some embodiments, the method 300 also includes:

The determining manner of determining CSSF _intra or CSSF _inter is to use the second determining manner of determining CSSF _intra or CSSF _inter within the MG.

Exemplarily, when the i-th SMTC uses the MG, the terminal device determines that the CSSF _intra or CSSF _inter of the i-th SMTC is CSSF _{within_gap,i} .

In some embodiments, the method 300 also includes:

When using the first determination method, counting the number of carriers configured based on SSB measurement among at least one carrier configured for the terminal device;

Wherein, the at least one carrier includes the first carrier corresponding to the first MO, and the number of statistics of the first carrier is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

The CSSF _intra or CSSF _inter of the i-th SMTC is determined based on the number of carriers configured with SSB-based measurements in the at least one carrier.

Exemplarily, the counting times of the first carrier is the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.

Exemplarily, the calculation manner of CSSF _{outside_gap,i} is exemplarily described below in conjunction with Table 10.

Table 10

As shown in Table 10, K represents the number of SMTCs that cannot be used in parallel or can only be used in series on each carrier configured based on SSB measurement, and N _{SCC_SSB_Multi-SMTC} represents that the number of configured SMTCs is greater than or equal to that the terminal device can The number of SMTCs used at the same time is the number of carriers; at this time, K×N _{SCC_SSB_Multi-SMTC} can be added to the formula related to the number of carriers measured based on SSB in Table 5.

For example, the formula in Table 5: N _{SCC_SSB} +Y+2x N _{SCC_CSIRS} +N _{SCC_CCA_RSSI/CO} can be modified as:

CSSF _inter = N _{SCC_SSB} + K×N _{SCC_SSB_Multi-SMTC} + Y+2×N _{SCC_CSIRS} + N _{SCC_CCA_RSSI/CO} .

Of course, if the value of K on each carrier is different, the calculation is performed by summation, for example, it can be converted into the following formula:

CSSF _inter =N _{SCC_SSB} +ΣK _i +Y+2×N _{SCC_CSIRS} +N _{SCC_CCA_RSSI/CO} ;

Among them, K _i is the value of K on the i-th carrier.

It should be understood that some of the parameters in Table 10 are the same as those in Table 5. Correspondingly, their meanings and related descriptions can refer to the relevant content described in Table 5. To avoid repetition, details are not repeated here.

In some embodiments, the method 300 also includes:

When using the second determination method, count the number of same-frequency MOs and the number of different-frequency MOs configured for the terminal device and in the MG used by the i-th SMTC;

Wherein, the same-frequency MO or the different-frequency MO includes a first MO, and the number of statistics of the first MO is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

Determine the CSSF _intra or CSSF _inter of the i-th SMTC based on the number of same-frequency MOs and the number of inter-frequency MOs.

Exemplarily, the number of statistics of the first MO is the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.

Exemplarily, the first MO includes K MGs that cannot be measured simultaneously, and the first MO is counted K times when calculating CSSF _{within_gap,i} .

Exemplarily, if K SMTCs configured simultaneously by a candidate measurement object i are measured in an interval j, the measurement object i in M _intra,i,j and M _inter,i,j is counted K times (A measurement object i in M _intra,i,j and in M _inter,i,j is counted K times if the measurement object is configured with K SMTC which are candidates to be measured in gap j where the measurement object i is also a candidate)

In some embodiments, the method 300 also includes:

K _SMTCi is determined based on the number of the multiple SMTCs and the number of SMTCs that can be used by the terminal device at the same time.

In some embodiments, K _SMTCi is the scaling factor of the SMTC level shared by the multiple SMTCs, K _SMTCi =ceil(A/B); wherein, A represents the number of the multiple SMTCs, and B represents the terminal device The number of SMTCs that can be used at the same time, A>B, ceil() means rounding up.

In some embodiments, K _SMTCi is determined according to information configured or indicated by the network device.

In some embodiments, K _SMTCi is determined according to the activation pattern of the plurality of SMTCs, the activation pattern includes a plurality of bit values, and the scaling factor of the SMTC level of the ith SMTC is based on the number of the plurality of bit values The ratio to the number of the first value in the plurality of bit values is determined.

Exemplarily, the scaling factor of the SMTC level of the ith SMTC is a ratio of the number of the multiple bit values to the number of the first numerical value in the multiple bit values.

Exemplarily, the scaling factor of the SMTC level of the ith SMTC is a value obtained by rounding the ratio of the number of the plurality of bit values to the number of the first value in the plurality of bit values. For example, the scaling factor of the SMTC level of the ith SMTC is obtained after performing an upward or downward rounding operation on the ratio of the number of the multiple bit values to the number of the first numerical value in the multiple bit values value.

Exemplarily, the first value may be 0 or 1.

Exemplarily, the activation patterns corresponding to different SMTCs among the plurality of SMTCs may be the same or different.

The number of SMTCs includes SMTC1 and SMTC2, and the activation patterns corresponding to SMTC1 and SMTC2 are different as an example, the activation pattern of SMTC1 can be 100; the activation pattern of SMTC2 can be 011, and the bit value is 1 to indicate SMTC activation, 0 means deactivation, it can be deduced that K _SMTC1 =3, K _SMTC2 =3/2=1.5 or K _SMTC2 =ceil(3/2)=2.

Exemplarily, the activation patterns of the multiple SMTCs may be shared. For example, the multiple bit values are respectively used to indicate whether to activate the multiple SMTCs.

Exemplarily, the value of K _SMTCi is greater than or equal to 1.

In some embodiments, the multiple SMTCs are associated with multiple cells; and/or, the multiple SMTCs are associated with multiple network devices; and/or, the multiple SMTCs are associated with multiple reference signals.

The preferred embodiments of the present application have been described in detail above in conjunction with the accompanying drawings. However, the present application is not limited to the specific details in the above embodiments. Within the scope of the technical concept of the present application, various simple modifications can be made to the technical solutions of the present application. These simple modifications all belong to the protection scope of the present application. For example, the various specific technical features described in the above specific implementation manners can be combined in any suitable manner if there is no contradiction. Separately. As another example, any combination of various implementations of the present application can also be made, as long as they do not violate the idea of the present application, they should also be regarded as the content disclosed in the present application.

The wireless communication method provided according to the embodiment of the present application is described in detail from the perspective of the terminal device above in conjunction with FIG. 3 . The wireless communication method provided according to the embodiment of the present application will be described below from the perspective of the network device in conjunction with FIG. 4 .

FIG. 4 is a schematic flowchart of a wireless communication method 300 provided by an embodiment of the present application. The method 300 may be executed by a network device, for example, the method 300 may be executed by a network device as shown in FIG. 1 .

As shown in FIG. 4, the method 300 may include:

S310. Send configuration information to the terminal device, where the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

S320. When measuring the first MO based on the first SMTC among the multiple SMTCs, determine whether to use a measurement interval MG.

In some embodiments, the S320 may include:

In some embodiments, the method 300 also includes:

Sending first indication information to the terminal device; where the first indication information is used to indicate whether the first SMTC uses the MG.

In some embodiments, the method 300 also includes:

In some embodiments, the measurement time of each SMTC is determined based on the scaling factor of the SMTC level of each SMTC or the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs; The first measurement time is determined based on the measurement time of each SMTC.

In some embodiments, the i-th SMTC among the plurality of SMTCs is used for co-frequency measurement and uses an MG; the measurement time of the i-th SMTC is determined according to at least one of the following:

In some embodiments, the i-th SMTC among the plurality of SMTCs is used for inter-frequency measurement and uses an MG; the measurement time of the i-th SMTC is determined according to at least one of the following:

In some embodiments, when P _SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, P _SMTCi =P _{SMTCi_initial} ×K _SMTCi ; wherein, P _{SMTCi_initial} represents the cycle of the i-th SMTC, K _SMTCi Indicates the scaling factor of the SMTC level of the i-th SMTC.

In some embodiments, when the i-th SMTC and the MG used by the i-th SMTC do not overlap or completely overlap in the time domain, K _p =K _SMTCi ; and/or, the i-th SMTC When it partially overlaps with the MG used by the i-th SMTC in the time domain, then K _p =K _SMTCi /(1-(P _{SMTCi_initial} /T _MGRPi )), where K _SMTCi represents the SMTC of the i-th SMTC The scaling factor of the level, P _{SMTCi_initial} represents the cycle of the i-th SMTC, and T _MGRPi represents the measurement interval repetition cycle MGRP of the i-th SMTC using the MG.

In some embodiments, the method 300 also includes:

It should be understood that, for steps in the wireless communication method 300, reference may be made to corresponding steps in the wireless communication method 200, and for brevity, details are not repeated here.

The method embodiment of the present application is described in detail above with reference to FIG. 1 to FIG. 4 , and the device embodiment of the present application is described in detail below in conjunction with FIG. 5 to FIG. 8 .

Fig. 5 is a schematic block diagram of a terminal device 400 according to an embodiment of the present application.

As shown in FIG. 5, the terminal device 400 may include:

The receiving unit 410 is configured to receive the configuration information sent by the network device, the configuration information is used to configure the first measurement object MO corresponding to the timing configuration of the SMTC for multiple synchronization signals and/or physical broadcast channel block measurement;

The determining unit 420 is configured to determine whether to use a measurement interval MG when measuring the first MO based on the first SMTC among the plurality of SMTCs.

In some embodiments, the determining unit 420 is specifically configured to:

When the first SMTC does not have an associated MG, determine to use the MG or determine not to use the MG;

When the number of MGs associated with the first SMTC is 1, determine to use the MG or determine not to use the MG;

When the number of MGs associated with the first SMTC is greater than 1, it is determined to use the MG.

In some embodiments, the first SMTC does not have an associated MG or the number of associated MGs is greater than 1; the determining unit 420 is further configured to:

In some embodiments, the determining unit 420 is specifically configured to:

Determining the first MG among the plurality of MGs based on at least one of the following information:

In some embodiments, the number of MGs associated with the first SMTC is 1; the determining unit 420 is further configured to:

In some embodiments, the determining unit 420 is specifically configured to:

receiving first indication information sent by the network device, where the first indication information is used to indicate whether the first SMTC uses MG;

Determine whether to use the MG based on the first indication information.

In some embodiments, the determining unit 420 is also used to:

In some embodiments, the determining unit 420 is specifically configured to:

When the terminal device supports simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use at the same time is greater than or equal to the number of the multiple SMTCs, set the SMTC with the largest period among the multiple SMTCs to The measurement time is determined as the first measurement time.

In some embodiments, the determining unit 420 is specifically configured to:

When the terminal device does not support simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use simultaneously is less than the number of the multiple SMTCs, based on the measurement time of each SMTC in the multiple SMTCs The first measurement time is determined.

In some embodiments, the determining unit 420 is specifically configured to:

Divide the SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs into N SMTC groups, N>1;

The first measurement time is determined based on the measurement times of the N SMTC packets.

In some embodiments, the determining unit 420 is specifically configured to:

According to the following formula, the measurement times of the N SMTC groups are added to obtain the first measurement time:

In some embodiments, the determining unit 420 is specifically configured to:

Using the N SMTCs with the largest period among the plurality of SMTCs as the SMTCs in the N SMTC groups respectively; or

Divide M SMTCs that overlap in the time domain among the multiple SMTCs into different SMTC groups, where M≤N.

In some embodiments, the determining unit 420 is specifically configured to:

Determine the measurement time of each SMTC based on the scaling factor of the SMTC level of each SMTC or the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

The first measurement time is determined based on the measurement time of each SMTC.

In some embodiments, the determining unit 420 is specifically configured to:

The measurement time of the SMTC with the largest measurement time among the measurement times of the plurality of SMTCs is determined as the first measurement time.

In some embodiments, the i-th SMTC among the multiple SMTCs is used for co-frequency measurement without using MG; the determining unit 420 is specifically configured to:

Determine the measurement time of the i-th SMTC according to at least one of the following:

In some embodiments, the i-th SMTC among the multiple SMTCs is used for co-frequency measurement and uses MG; the determining unit 420 is specifically configured to:

In some embodiments, the i-th SMTC among the multiple SMTCs is used for inter-frequency measurement and uses MG; the determining unit 420 is specifically configured to:

In some embodiments, the i-th SMTC among the multiple SMTCs is used for inter-frequency measurement and does not use the MG; the determining unit 420 is specifically configured to:

In some embodiments, the determining unit 420 is also used to:

In some embodiments, the measurement signal indicated by the first MO is an intra-frequency synchronization signal and/or a physical broadcast channel block SSB; the determining unit 420 is specifically configured to:

When the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, determine to use the first determination method;

When the i-th SMTC overlaps with the MG part associated with the i-th SMTC, determine to use the first determination method;

When the i-th SMTC is completely coincident with the MG associated with the i-th SMTC, it is determined to use the second determination manner.

In some embodiments, the measurement signal indicated by the first MO is an inter-frequency SSB; the determining unit 420 is specifically configured to:

When the i-th SMTC overlaps with the MG associated with the i-th SMTC and the terminal device is capable of carrier aggregation CA, determine to use the first determination method;

In some embodiments, the determining unit 420 is also used to:

It should be understood that the device embodiment and the method embodiment may correspond to each other, and similar descriptions may refer to the method embodiment. Specifically, the terminal device 400 shown in FIG. 5 may correspond to the corresponding subject in the method 200 of the embodiment of the present application, and the foregoing and other operations and/or functions of each unit in the terminal device 400 are for realizing the implementation of the present application. For the sake of brevity, the corresponding processes in each method provided by the example are not repeated here.

Fig. 6 is a schematic block diagram of a network device 500 according to an embodiment of the present application.

As shown in FIG. 6, the network device 500 may include:

The sending unit 510 is configured to send configuration information to the terminal device, where the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

The determining unit 520 is configured to determine whether to use a measurement interval MG when measuring the first MO based on the first SMTC among the plurality of SMTCs.

In some embodiments, the determining unit 520 is specifically configured to:

In some embodiments, the first SMTC does not have an associated MG or the number of associated MGs is greater than 1; the determining unit 520 is further configured to:

In some embodiments, the determining unit 520 is specifically configured to:

In some embodiments, the number of MGs associated with the first SMTC is 1; the determining unit 520 is further configured to:

In some embodiments, the network device 500 also includes:

A sending unit, configured to send first indication information to the terminal device; wherein, the first indication information is used to indicate whether the first SMTC uses the MG.

In some embodiments, the determining unit 520 is further configured to:

In some embodiments, the determining unit 520 is specifically configured to:

In some embodiments, the i-th SMTC among the multiple SMTCs is used for co-frequency measurement without using MG; the determining unit 520 is specifically configured to:

In some embodiments, the i-th SMTC among the multiple SMTCs is used for intra-frequency measurement and uses MG; the determining unit 520 is specifically configured to:

In some embodiments, the i-th SMTC among the multiple SMTCs is used for inter-frequency measurement and uses MG; the determining unit 520 is specifically configured to:

In some embodiments, the i-th SMTC among the multiple SMTCs is used for inter-frequency measurement and does not use the MG; the determining unit 520 is specifically configured to:

In some embodiments, the determining unit 520 is further configured to:

In some embodiments, the measurement signal indicated by the first MO is an intra-frequency synchronization signal and/or a physical broadcast channel block SSB; the determining unit 520 is specifically configured to:

In some embodiments, the measurement signal indicated by the first MO is an inter-frequency SSB; the determining unit 520 is specifically configured to:

In some embodiments, the determining unit 520 is further configured to:

It should be understood that the device embodiment and the method embodiment may correspond to each other, and similar descriptions may refer to the method embodiment. Specifically, the network device 500 shown in FIG. 6 may correspond to the corresponding subject in the method 300 of the embodiment of the present application, and the aforementioned and other operations and/or functions of each unit in the network device 500 are for realizing the implementation of the present application. For the sake of brevity, the corresponding processes in each method provided by the example are not repeated here.

The above describes the communication device in the embodiment of the present application from the perspective of functional modules with reference to the accompanying drawings. It should be understood that the functional modules may be implemented in the form of hardware, may also be implemented by instructions in the form of software, and may also be implemented by a combination of hardware and software modules. Specifically, each step of the method embodiment in the embodiment of the present application can be completed by an integrated logic circuit of hardware in the processor and/or instructions in the form of software, and the steps of the method disclosed in the embodiment of the present application can be directly embodied as hardware The execution of the decoding processor is completed, or the combination of hardware and software modules in the decoding processor is used to complete the execution. Optionally, the software module may be located in a mature storage medium in the field such as random access memory, flash memory, read-only memory, programmable read-only memory, electrically erasable programmable memory, and registers. The storage medium is located in the memory, and the processor reads the information in the memory, and completes the steps in the above method embodiments in combination with its hardware.

For example, the receiving unit 410 or the sending unit 510 mentioned above may be implemented by a transceiver, and the processing unit 420 or the processing unit 520 mentioned above may be implemented by a processor.

Fig. 7 is a schematic structural diagram of a communication device 600 according to an embodiment of the present application.

As shown in FIG. 7 , the communication device 600 may include a processor 610 .

Wherein, the processor 610 may invoke and run a computer program from the memory, so as to implement the method in the embodiment of the present application.

As shown in FIG. 7 , the communication device 600 may further include a memory 620 .

Wherein, the memory 620 may be used to store indication information, and may also be used to store codes, instructions, etc. executed by the processor 610 . Wherein, the processor 610 can invoke and run a computer program from the memory 620, so as to implement the method in the embodiment of the present application. The memory 620 may be an independent device independent of the processor 610 , or may be integrated in the processor 610 .

As shown in FIG. 7 , the communication device 600 may further include a transceiver 630 .

Wherein, the processor 610 can control the transceiver 630 to communicate with other devices, specifically, can send information or data to other devices, or receive information or data sent by other devices. Transceiver 630 may include a transmitter and a receiver. The transceiver 630 may further include antennas, and the number of antennas may be one or more.

It should be understood that various components in the communication device 600 are connected through a bus system, wherein the bus system includes not only a data bus, but also a power bus, a control bus, and a status signal bus.

It should also be understood that the communication device 600 may be the terminal device in the embodiment of the present application, and the communication device 600 may implement the corresponding processes implemented by the terminal device in each method of the embodiment of the present application, that is, the terminal device in the embodiment of the present application The communication device 600 may correspond to the terminal device 400 in the embodiment of the present application, and may correspond to a corresponding subject in performing the method 200 according to the embodiment of the present application. For the sake of brevity, details are not repeated here. Similarly, the communication device 600 may be the network device of the embodiment of the present application, and the communication device 600 may implement the corresponding processes implemented by the network device in the various methods of the embodiment of the present application. That is to say, the communication device 600 in the embodiment of the present application may correspond to the network device 500 in the embodiment of the present application, and may correspond to the corresponding subject in performing the method 300 according to the embodiment of the present application. For the sake of brevity, no further repeat.

In addition, the embodiment of the present application also provides a chip.

For example, the chip may be an integrated circuit chip, which has signal processing capabilities, and can implement or execute the methods, steps and logic block diagrams disclosed in the embodiments of the present application. The chip can also be called system-on-chip, system-on-chip, system-on-chip or system-on-chip, etc. Optionally, the chip can be applied to various communication devices, so that the communication device installed with the chip can execute the methods, steps and logic block diagrams disclosed in the embodiments of the present application.

FIG. 8 is a schematic structural diagram of a chip 700 according to an embodiment of the present application.

As shown in FIG. 8 , the chip 700 includes a processor 710 .

Wherein, the processor 710 can invoke and run a computer program from the memory, so as to implement the method in the embodiment of the present application.

As shown in FIG. 8 , the chip 700 may further include a memory 720 .

Wherein, the processor 710 can invoke and run a computer program from the memory 720, so as to implement the method in the embodiment of the present application. The memory 720 may be used to store indication information, and may also be used to store codes, instructions, etc. executed by the processor 710 . The memory 720 may be an independent device independent of the processor 710 , or may be integrated in the processor 710 .

As shown in FIG. 8 , the chip 700 may further include an input interface 730 .

Wherein, the processor 710 may control the input interface 730 to communicate with other devices or chips, specifically, may obtain information or data sent by other devices or chips.

As shown in FIG. 8 , the chip 700 may further include an output interface 740 .

Wherein, the processor 710 can control the output interface 740 to communicate with other devices or chips, specifically, can output information or data to other devices or chips.

It should be understood that the chip 700 can be applied to the network device in the embodiment of the present application, and the chip can realize the corresponding process implemented by the network device in the various methods of the embodiment of the present application, and can also realize the various methods of the embodiment of the present application For the sake of brevity, the corresponding process implemented by the terminal device in , will not be repeated here.

It should also be understood that the various components in the chip 700 are connected through a bus system, wherein the bus system includes not only a data bus, but also a power bus, a control bus, and a status signal bus.

Processors mentioned above may include, but are not limited to:

General-purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC), field programmable gate arrays (Field Programmable Gate Array, FPGA) or other programmable logic devices, discrete gates Or transistor logic devices, discrete hardware components, and so on.

The processor may be used to implement or execute the methods, steps and logic block diagrams disclosed in the embodiments of the present application. The steps of the method disclosed in connection with the embodiments of the present application may be directly implemented by a hardware decoding processor, or implemented by a combination of hardware and software modules in the decoding processor. The software module may be located in a mature storage medium in the field such as random access memory, flash memory, read-only memory, programmable read-only memory or erasable programmable memory, register. The storage medium is located in the memory, and the processor reads the information in the memory, and completes the steps of the above method in combination with its hardware.

The memory mentioned above includes but not limited to:

volatile memory and/or non-volatile memory. Among them, the non-volatile memory can be read-only memory (Read-Only Memory, ROM), programmable read-only memory (Programmable ROM, PROM), erasable programmable read-only memory (Erasable PROM, EPROM), electronically programmable Erase Programmable Read-Only Memory (Electrically EPROM, EEPROM) or Flash. The volatile memory can be Random Access Memory (RAM), which acts as external cache memory. By way of illustration and not limitation, many forms of RAM are available, such as Static Random Access Memory (Static RAM, SRAM), Dynamic Random Access Memory (Dynamic RAM, DRAM), Synchronous Dynamic Random Access Memory (Synchronous DRAM, SDRAM), double data rate synchronous dynamic random access memory (Double Data Rate SDRAM, DDR SDRAM), enhanced synchronous dynamic random access memory (Enhanced SDRAM, ESDRAM), synchronous connection dynamic random access memory (synch link DRAM, SLDRAM) and Direct Memory Bus Random Access Memory (Direct Rambus RAM, DR RAM).

It should be noted that the memories described herein are intended to include these and any other suitable types of memories.

Embodiments of the present application also provide a computer-readable storage medium for storing computer programs. The computer-readable storage medium stores one or more programs, and the one or more programs include instructions. When the instructions are executed by a portable electronic device including a plurality of application programs, the portable electronic device can perform the wireless communication provided by the application. communication method. Optionally, the computer-readable storage medium can be applied to the network device in the embodiments of the present application, and the computer program enables the computer to execute the corresponding processes implemented by the network device in the methods of the embodiments of the present application. For brevity, here No longer. Optionally, the computer-readable storage medium can be applied to the mobile terminal/terminal device in the embodiments of the present application, and the computer program enables the computer to execute the corresponding processes implemented by the mobile terminal/terminal device in the various methods of the embodiments of the present application , for the sake of brevity, it is not repeated here.

The embodiment of the present application also provides a computer program product, including a computer program. Optionally, the computer program product can be applied to the network device in the embodiment of the present application, and the computer program enables the computer to execute the corresponding processes implemented by the network device in the methods of the embodiment of the present application. For the sake of brevity, the repeat. Optionally, the computer program product can be applied to the mobile terminal/terminal device in the embodiments of the present application, and the computer program enables the computer to execute the corresponding processes implemented by the mobile terminal/terminal device in the methods of the embodiments of the present application, for It is concise and will not be repeated here.

The embodiment of the present application also provides a computer program. When the computer program is executed by the computer, the computer can execute the wireless communication method provided in this application. Optionally, the computer program can be applied to the network device in the embodiment of the present application. When the computer program is run on the computer, the computer executes the corresponding process implemented by the network device in each method of the embodiment of the present application. For the sake of brevity , which will not be repeated here. Optionally, the computer program can be applied to the mobile terminal/terminal device in the embodiment of the present application. When the computer program is run on the computer, the computer executes each method in the embodiment of the present application to be implemented by the mobile terminal/terminal device For the sake of brevity, the corresponding process will not be repeated here.

An embodiment of the present application also provides a communication system, which may include the above-mentioned terminal device and network device to form a communication system 100 as shown in FIG. 1 , which is not repeated here for brevity. It should be noted that the terms "system" and the like in this document may also be referred to as "network management architecture" or "network system".

It should also be understood that the terms used in the embodiments of the present application and the appended claims are only for the purpose of describing specific embodiments, and are not intended to limit the embodiments of the present application. For example, the singular forms "a", "said", "above" and "the" used in the embodiments of this application and the appended claims are also intended to include plural forms unless the context clearly indicates otherwise. meaning.

Those skilled in the art can appreciate that the units and algorithm steps of the examples described in conjunction with the embodiments disclosed herein can be implemented by electronic hardware, or a combination of computer software and electronic hardware. Whether these functions are executed by hardware or software depends on the specific application and design constraints of the technical solution. Professionals and technicians may use different methods to implement the described functions for each specific application, but such implementation should not be regarded as exceeding the scope of the embodiments of the present application. If implemented in the form of a software function unit and sold or used as an independent product, it can be stored in a computer-readable storage medium. Based on this understanding, the technical solution of the embodiment of the present application is essentially or the part that contributes to the prior art or the part of the technical solution can be embodied in the form of a software product, and the computer software product is stored in a storage medium , including several instructions to make a computer device (which may be a personal computer, a server, or a network device, etc.) execute all or part of the steps of the method described in the embodiment of the present application. The aforementioned storage medium includes: various media capable of storing program codes such as U disk, mobile hard disk, read-only memory, random access memory, magnetic disk or optical disk.

Those skilled in the art can also realize that for the convenience and brevity of description, the specific working process of the above-described system, device, and unit can refer to the corresponding process in the foregoing method embodiment, and details are not repeated here. In the several embodiments provided in this application, it should be understood that the disclosed systems, devices and methods may be implemented in other ways. For example, the division of units or modules or components in the above-described device embodiments is only a logical function division, and there may be other division methods in actual implementation, for example, multiple units or modules or components can be combined or integrated to another system, or some units or modules or components may be ignored, or not implemented. For another example, the units/modules/components described above as separate/display components may or may not be physically separated, that is, they may be located in one place, or may also be distributed to multiple network units. Part or all of the units/modules/components can be selected according to actual needs to achieve the purpose of the embodiments of the present application. Finally, it should be noted that the mutual coupling or direct coupling or communication connection shown or discussed above may be through some interfaces, and the indirect coupling or communication connection of devices or units may be in electrical, mechanical or other forms .

The above content is only the specific implementation of the embodiment of the application, but the scope of protection of the embodiment of the application is not limited thereto. Anyone familiar with the technical field can easily think of Any changes or substitutions shall fall within the protection scope of the embodiments of the present application. Therefore, the protection scope of the embodiments of the present application should be determined by the protection scope of the claims.

Claims

A wireless communication method, characterized in that the method is applicable to a terminal device, and the method includes:

Receiving configuration information sent by the network device, the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

When measuring the first MO based on the first SMTC among the plurality of SMTCs, determine whether to use the measurement interval MG.
The method according to claim 1, wherein, when measuring the first MO based on the first SMTC in the plurality of SMTCs, determining whether to use the measurement interval MG includes:

When the first MO is an MO that requires an MG to perform measurements, determine to use the MG;

When the first MO is a MO that does not need the MG to perform measurements, it is determined whether to use the MG based on whether there is an associated measurement interval MG in the first SMTC.
The method according to claim 2, wherein the determining whether to use the MG based on whether there is an associated measurement interval MG in the first SMTC includes:

When the first SMTC does not have an associated MG, determine to use the MG or determine not to use the MG;

When the number of MGs associated with the first SMTC is 1, determine to use the MG or determine not to use the MG;

When the number of MGs associated with the first SMTC is greater than 1, it is determined to use the MG.
The method according to any one of claims 1 to 3, wherein the first SMTC has no associated MG or the number of associated MG is greater than 1;

The method also includes:

When determining to use the MG, among the multiple MGs corresponding to the first SMTC, determine the first MG used by the first SMTC.
The method according to claim 4, wherein, among the plurality of MGs corresponding to the first SMTC, determining the first MG used by the first SMTC includes:

Determining the first MG among the plurality of MGs based on at least one of the following information:

The period of each MG in the plurality of MGs, the period of the first SMTC, the time domain position of each MG, the time domain position of the first SMTC, and the measurement task associated with each MG.
The method according to claim 4 or 5, wherein the first MG is an MG whose period among the plurality of MGs is the same as or closest to that of the first SMTC, or the first MG is the MG with the smallest or largest period among the multiple MGs, or the first MG is the MG with the largest overlap area with the first SMTC in the time domain among the multiple MGs, or the first MG The MG is the MG with the smallest associated measurement task among the plurality of MGs.
The method according to any one of claims 4 to 6, wherein when there is no MG associated with the first SMTC, the multiple MGs are pre-configured MGs or MGs associated with the first MO ; or, when the first SMTC has associated MGs, the multiple MGs are MGs associated with the first SMTC.
The method according to any one of claims 4 to 7, wherein the measurement corresponding to the first SMTC is the same-frequency measurement used to determine the information of the first MG and the measurement corresponding to the first SMTC When the measurement is an inter-frequency measurement, the information used to determine the first MG is the same or different; and/or, when the measurement corresponding to the first SMTC is an intra-frequency measurement, the method for determining the first MG is the same as the method for determining the first MG. When the measurement corresponding to the first SMTC is an inter-frequency measurement, the method for determining the first MG is the same or different.
The method according to any one of claims 1 to 4, wherein the number of MGs associated with the first SMTC is 1;

The method also includes:

When determining to use the MG, determine the MG associated with the first SMTC as the first MG used by the first SMTC.
The method according to claim 1, wherein, when measuring the first MO based on the first SMTC in the plurality of SMTCs, determining whether to use the measurement interval MG includes:

receiving first indication information sent by the network device, where the first indication information is used to indicate whether the first SMTC uses MG;

Determine whether to use the MG based on the first indication information.
The method according to claim 10, wherein the first indication information is also used to indicate the first MG used by the first SMTC.
The method according to claim 10 or 11, wherein the first indication information is used to indicate that the MG used by the first SMTC is the MG associated with the first SMTC.
The method according to any one of claims 10 to 12, wherein the first MO is an MO that requires an MG to perform measurements, and each SMTC in the plurality of SMTCs has an associated MG; or When the first MO is an MO that does not require an MG to perform measurements, each SMTC in the plurality of SMTCs has or does not have an associated MG.
The method according to any one of claims 1 to 13, further comprising:

Based on the measurement time of the SMTC with the largest period among the plurality of SMTCs, determining the first measurement time required for measuring the first MO; or

determining to measure the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs;

Wherein, when the i-th SMTC among the plurality of SMTCs does not use the MG, the measurement time of the i-th SMTC is determined according to the period of the i-th SMTC, and when the i-th SMTC uses an MG, the The measurement time of the i-th SMTC is determined according to the cycle of the i-th SMTC and the cycle of the MG used by the i-th SMTC.
The method according to claim 14, wherein, determining the first measurement time required for measuring the first MO based on the measurement time of the SMTC with the largest period among the plurality of SMTCs includes:

When the terminal device supports simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use at the same time is greater than or equal to the number of the multiple SMTCs, set the SMTC with the largest period among the multiple SMTCs to The measurement time is determined as the first measurement time.
The method according to claim 14 or 15, wherein said determining and measuring the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs comprises:

When the terminal device does not support simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use simultaneously is less than the number of the multiple SMTCs, based on the measurement time of each SMTC in the multiple SMTCs The first measurement time is determined.
The method according to any one of claims 14 to 16, wherein the determining to measure the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs includes:

Divide the SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs into N SMTC groups, N>1;

The first measurement time is determined based on the measurement times of the N SMTC packets.
The method according to claim 17, wherein the determination of the first measurement time based on the measurement time of the N SMTC packets includes:

According to the following formula, the measurement times of the N SMTC groups are added to obtain the first measurement time:

Wherein, T mo represents the first measurement time, T i represents the measurement time of the i-th SMTC group among the N SMTC groups, and T delta represents the time domain offset of the N SMTC groups.
The method according to claim 18, characterized in that, T delta = (N-1) × P max , P max represents the period of the SMTC with the largest period among the multiple SMTCs and/or the period used by the multiple SMTCs The period of the MG with the largest measurement interval repetition period MGRP in the MG.
The method according to claim 17 or 19, wherein the measurement time of the ith SMTC grouping is the measurement time of the SMTC with the largest period in the ith SMTC grouping.
The method according to any one of claims 17 to 20, wherein, the SMTCs that cannot be used in parallel or can only be used in series in the plurality of SMTCs are divided into N SMTC groups, including:

Using the N SMTCs with the largest period among the plurality of SMTCs as the SMTCs in the N SMTC groups respectively; or

Divide M SMTCs that overlap in the time domain among the multiple SMTCs into different SMTC groups, where M≤N.
The method according to any one of claims 14 to 16, wherein the determining to measure the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs includes:

Determine the measurement time of each SMTC based on the scaling factor of the SMTC level of each SMTC or the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

The first measurement time is determined based on the measurement time of each SMTC.
The method according to claim 22, wherein the determining the first measurement time based on the measurement time of each SMTC comprises:

The measurement time of the SMTC with the largest measurement time among the measurement times of the plurality of SMTCs is determined as the first measurement time.
The method according to claim 22 or 23, wherein the i-th SMTC among the plurality of SMTCs is used for co-frequency measurement and does not use MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,ceil(N sample ×K p )×P SMTCi )×CSSF intra ;

When the period of DRX is less than or equal to 320ms, T SMTCi =max(T min ,ceil(M 2 ×N sample ×K p )×max(P SMTCi ,P DRX ))×CSSF intra ;

When the DRX period is greater than 320ms, T SMTCi =ceil(N sample ×K p )×P DRX ×CSSF intra ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T min is determined according to the type of the reference signal and/or the measurement purpose, N sample is determined according to the type of the reference signal and/or the measurement purpose, and K p is determined according to The overlap between the i-th SMTC and the MG corresponding to the i-th SMTC in the time domain is determined, P SMTCi is determined according to the cycle of the i-th SMTC, P DRX represents the cycle of DRX, and M2 is determined according to the period of the network equipment The configuration information is determined, CSSF intra indicates the scaling factor of the carrier level measured at the same frequency, ceil() indicates the rounding up operation, and max() indicates the maximum value operation;

Wherein, K p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF intra is determined according to the The number of SMTCs used in parallel or only in series is determined.
The method according to claim 22 or 23, wherein the i-th SMTC among the plurality of SMTCs is used for co-frequency measurement and uses MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,N sample ×max(T MGRPi ,P SMTCi ))×CSSF intra ;

When the period of DRX is less than or equal to 320ms, T SMTCi =max(T min ,ceil(M 2 ×N sample )×max(T MGRPi ,P SMTCi ,P DRX ))×CSSF intra ;

When the DRX period is greater than 320ms, T SMTCi =N sample ×max(T MGRPi ,P DRX )×CSSF intra ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T MGRPi represents the measurement interval repetition period MGRP of the i-th SMTC using MG, P SMTCi is determined according to the cycle of the i-th SMTC, and P DRX represents the DRX period, M2 is determined according to the information configured by the network device, CSSF intra represents the scaling factor of the carrier level measured at the same frequency, ceil() represents an upward rounding operation, and max() represents the maximum value operation;

Wherein, PSMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.
The method according to claim 22 or 23, wherein the i-th SMTC among the plurality of SMTCs is used for inter-frequency measurement and uses MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,N sample ×max(T MGRPi ,P SMTCi ))×CSSF inter ;

When the DRX period is less than or equal to 320ms, T SMTCi =max(T min ,Ceil(N sample ×M 3 )×max(T MGRPi ,P SMTCi ,P DRX ))×CSSF inter ;

When the DRX cycle is greater than 320ms, T SMTCi = N sample × P DRX × CSSF inter ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T min is determined according to the type of the reference signal and/or the measurement purpose, N sample is determined according to the type of the reference signal and/or the measurement purpose, and T MGRPi represents The i-th SMTC uses the MG measurement interval repetition cycle MGRP, P SMTCi is determined according to the cycle of the i-th SMTC, P DRX represents the cycle of DRX, M 3 is determined according to the information configured by the network device, and CSSF inter represents inter-frequency The scaling factor of the measured carrier level, ceil() means the rounding up operation, max() means the maximum value operation;

Wherein, P SMTCi is also determined according to the scaling factor of the SMTC level of the ith SMTC, or CSSF inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the multiple SMTCs.
The method according to claim 22 or 23, wherein the i-th SMTC among the plurality of SMTCs is used for inter-frequency measurement and does not use MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,ceil(N sample ×Kp)×P SMTCi )×CSSF inter ;

When the DRX period is less than or equal to 320ms, T SMTCi =max(T min ,ceil(M 3 ×N sample ×K p )×max(P SMTCi ,P DRX ))×CSSF inter ;

When the DRX period is greater than 320ms, T SMTCi =ceil(N sample ×K p )×P DRX ×CSSF inter ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T min is determined according to the type of the reference signal and/or the measurement purpose, N sample is determined according to the type of the reference signal and/or the measurement purpose, and K p is determined according to The overlap between the i-th SMTC and the MG corresponding to the i-th SMTC in the time domain is determined, P SMTCi is determined according to the cycle of the i-th SMTC, P DRX represents the cycle of DRX, and M3 is determined according to the period of the network equipment The configuration information is determined, CSSF inter indicates the scaling factor of the carrier level of the inter-frequency measurement, ceil() indicates the upward rounding operation, and max() indicates the maximum value operation;

Wherein, K p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF inter is determined according to the The number of SMTCs used in parallel or only in series is determined.
The method according to any one of claims 24 to 27, wherein when P SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, P SMTCi =P SMTCi_initial ×K SMTCi ; where, P SMTCi_initial represents the period of the i-th SMTC, and K SMTCi represents the scaling factor of the SMTC level of the i-th SMTC.
The method according to claim 24 or 27, wherein when the i-th SMTC and the MG used by the i-th SMTC do not overlap or completely overlap in time domain, K p =K SMTCi ; and /or, when the i-th SMTC partially overlaps with the MG used by the i-th SMTC in the time domain, then K p =K SMTCi /(1-(P SMTCi_initial /T MGRPi )), where K SMTCi Indicates the scaling factor of the SMTC level of the i-th SMTC, P SMTCi_initial indicates the period of the i-th SMTC, and T MGRPi indicates the measurement interval repetition period MGRP of the i-th SMTC using MG.
The method according to claim 24 or 27, further comprising:

Based on the overlapping of the i-th SMTC and the MG associated with the i-th SMTC, determine the CSSF intra or CSSF inter determination method, the CSSF intra or CSSF inter determination method includes: using the CSSF intra to determine outside the MG Either the first determination method of CSSF inter , or the second determination method of determining CSSF intra or CSSF inter in the MG.
The method according to claim 30, wherein the measurement signal indicated by the first MO is an intra-frequency synchronization signal and/or a physical broadcast channel block SSB; wherein, the i-th SMTC and the The overlapping situation of the MG associated with the i-th SMTC determines how to determine CSSF intra or CSSF inter , including:

When the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, determine to use the first determination method;

When the i-th SMTC overlaps with the MG part associated with the i-th SMTC, determine to use the first determination method;

When the i-th SMTC is completely coincident with the MG associated with the i-th SMTC, it is determined to use the second determination manner.
The method according to claim 30, wherein the measurement signal indicated by the first MO is an inter-frequency SSB; wherein, the overlapping of the MG based on the i-th SMTC and the i-th SMTC The way to determine CSSF intra or CSSF inter , including:

When the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, determine to use the first determination method;

When the i-th SMTC overlaps with the MG associated with the i-th SMTC and the terminal device is capable of carrier aggregation CA, determine to use the first determination method;

When the i-th SMTC is completely coincident with the MG associated with the i-th SMTC, it is determined to use the second determination manner.
The method according to claim 25 or 26, further comprising:

The determining manner of determining CSSF intra or CSSF inter is to use the second determining manner of determining CSSF intra or CSSF inter within the MG.
The method according to any one of claims 30 to 32, further comprising:

When using the first determination method, counting the number of carriers configured based on SSB measurement among at least one carrier configured for the terminal device;

Wherein, the at least one carrier includes the first carrier corresponding to the first MO, and the number of statistics of the first carrier is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

The CSSF intra or CSSF inter of the i-th SMTC is determined based on the number of carriers configured with SSB-based measurements in the at least one carrier.
The method according to any one of claims 30 to 33, further comprising:

When using the second determination method, count the number of same-frequency MOs and the number of different-frequency MOs configured for the terminal device and in the MG used by the i-th SMTC;

Wherein, the same-frequency MO or the different-frequency MO includes a first MO, and the number of statistics of the first MO is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

Determine the CSSF intra or CSSF inter of the i-th SMTC based on the number of same-frequency MOs and the number of inter-frequency MOs.
The method according to any one of claims 24 to 35, further comprising:

K SMTCi is determined based on the number of the multiple SMTCs and the number of SMTCs that can be used by the terminal device at the same time.
The method according to claim 36, wherein K SMTCi is a scaling factor of the SMTC level shared by the multiple SMTCs, K SMTCi =ceil(A/B); wherein, A represents the number of the multiple SMTCs , B represents the number of SMTCs that the terminal device can use at the same time, A>B, and ceil() represents an upward rounding operation.
The method according to any one of claims 24 to 37, characterized in that K SMTCi is determined according to information configured or indicated by network equipment.
The method according to claim 38, wherein K SMTCi is determined according to the activation pattern of the plurality of SMTCs, the activation pattern includes a plurality of bit values, and the scaling factor of the SMTC level of the ith SMTC is determined according to the The ratio of the quantity of the plurality of bit values to the quantity of the first numerical value in the plurality of bit values is determined.
The method according to any one of claims 1 to 39, wherein the multiple SMTCs are associated with multiple cells; and/or, the multiple SMTCs are associated with multiple network devices; and/or, the Multiple SMTCs are associated to multiple reference signals.
A wireless communication method, characterized in that the method is applicable to network equipment, and the method includes:

Send configuration information to the terminal device, where the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

When measuring the first MO based on the first SMTC among the plurality of SMTCs, determine whether to use the measurement interval MG.
The method according to claim 41, wherein, when measuring the first MO based on the first SMTC among the plurality of SMTCs, determining whether to use the measurement interval MG includes:

When the first MO is an MO that requires an MG to perform measurements, determine to use the MG;

When the first MO is a MO that does not need the MG to perform measurements, it is determined whether to use the MG based on whether there is an associated measurement interval MG in the first SMTC.
The method according to claim 42, wherein the determining whether to use the MG based on whether there is an associated measurement interval MG in the first SMTC comprises:

When the first SMTC does not have an associated MG, determine to use the MG or determine not to use the MG;

When the number of MGs associated with the first SMTC is 1, determine to use the MG or determine not to use the MG;

When the number of MGs associated with the first SMTC is greater than 1, it is determined to use the MG.
The method according to any one of claims 41 to 43, wherein the first SMTC has no associated MG or the number of associated MG is greater than 1;

The method also includes:

When determining to use the MG, among the multiple MGs corresponding to the first SMTC, determine the first MG used by the first SMTC.
The method according to claim 44, wherein the determining the first MG used by the first SMTC among the multiple MGs corresponding to the first SMTC comprises:

Determining the first MG among the plurality of MGs based on at least one of the following information:

The period of each MG in the plurality of MGs, the period of the first SMTC, the time domain position of each MG, the time domain position of the first SMTC, and the measurement task associated with each MG.
The method according to claim 44 or 45, wherein the first MG is an MG whose period among the plurality of MGs is the same as or closest to that of the first SMTC, or the first MG is the MG with the smallest or largest period among the multiple MGs, or the first MG is the MG with the largest overlap area with the first SMTC in the time domain among the multiple MGs, or the first MG The MG is the MG with the smallest associated measurement task among the plurality of MGs.
The method according to any one of claims 44 to 46, wherein when there is no MG associated with the first SMTC, the multiple MGs are pre-configured MGs or MGs associated with the first MO ; or, when the first SMTC has associated MGs, the multiple MGs are MGs associated with the first SMTC.
The method according to any one of claims 44 to 47, wherein the measurement corresponding to the first SMTC is co-frequency measurement used to determine the information of the first MG and the measurement corresponding to the first SMTC When the measurement is an inter-frequency measurement, the information used to determine the first MG is the same or different; and/or, when the measurement corresponding to the first SMTC is an intra-frequency measurement, the method for determining the first MG is the same as the method for determining the first MG. When the measurement corresponding to the first SMTC is an inter-frequency measurement, the method for determining the first MG is the same or different.
The method according to any one of claims 41 to 44, wherein the number of MGs associated with the first SMTC is 1;

The method also includes:

When determining to use the MG, determine the MG associated with the first SMTC as the first MG used by the first SMTC.
The method according to claim 41, further comprising:

Sending first indication information to the terminal device; where the first indication information is used to indicate whether the first SMTC uses the MG.
The method according to claim 50, wherein the first indication information is also used to indicate the first MG used by the first SMTC.
The method according to claim 50 or 51, wherein the first indication information is used to indicate that the MG used by the first SMTC is the MG associated with the first SMTC.
The method according to any one of claims 50 to 52, wherein the first MO is an MO that requires an MG to perform measurements, and each SMTC in the plurality of SMTCs has an associated MG; or When the first MO is an MO that can be measured without an MG, each SMTC in the plurality of SMTCs has or does not have an associated MG.
The method according to any one of claims 41 to 53, further comprising:

Based on the measurement time of the SMTC with the largest period among the plurality of SMTCs, determining the first measurement time required for measuring the first MO; or

determining to measure the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs;

Wherein, when the i-th SMTC among the plurality of SMTCs does not use the MG, the measurement time of the i-th SMTC is determined according to the period of the i-th SMTC, and when the i-th SMTC uses an MG, the The measurement time of the i-th SMTC is determined according to the cycle of the i-th SMTC and the cycle of the MG used by the i-th SMTC.
The method according to claim 54, wherein, determining the first measurement time required for measuring the first MO based on the measurement time of the SMTC with the largest period among the plurality of SMTCs includes:

When the terminal device supports simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use at the same time is greater than or equal to the number of the multiple SMTCs, set the SMTC with the largest period among the multiple SMTCs to The measurement time is determined as the first measurement time.
The method according to claim 54 or 55, wherein the determining and measuring the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs comprises:

When the terminal device does not support simultaneous measurement based on the multiple SMTCs or the number of SMTCs that the terminal device can use simultaneously is less than the number of the multiple SMTCs, based on the measurement time of each SMTC in the multiple SMTCs The first measurement time is determined.
The method according to any one of claims 54 to 56, wherein the determining to measure the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs includes:

Divide the SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs into N SMTC groups, N>1;

The first measurement time is determined based on the measurement times of the N SMTC packets.
The method according to claim 57, wherein, determining the first measurement time based on the measurement time of the N SMTC packets comprises:

According to the following formula, the measurement times of the N SMTC groups are added to obtain the first measurement time:

Wherein, T mo represents the first measurement time, T i represents the measurement time of the i-th SMTC group among the N SMTC groups, and T delta represents the time domain offset of the N SMTC groups.
The method according to claim 58, characterized in that, T delta = (N-1) × P max , P max represents the period of the SMTC with the largest period among the multiple SMTCs and/or the period used by the multiple SMTCs The period of the MG with the largest measurement interval repetition period MGRP in the MG.
The method according to claim 57 or 59, wherein the measurement time of the i-th SMTC group is the measurement time of the SMTC with the largest period in the i-th SMTC group.
The method according to any one of claims 57 to 60, wherein said dividing the SMTCs that cannot be used in parallel or can only be used in series into N SMTC groups in the plurality of SMTCs includes:

Using the N SMTCs with the largest period among the plurality of SMTCs as the SMTCs in the N SMTC groups respectively; or

Divide M SMTCs that overlap in the time domain among the multiple SMTCs into different SMTC groups, where M≤N.
The method according to any one of claims 54 to 56, wherein the determining to measure the first measurement time based on the measurement time of each SMTC in the plurality of SMTCs includes:

Determine the measurement time of each SMTC based on the scaling factor of the SMTC level of each SMTC or the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

The first measurement time is determined based on the measurement time of each SMTC.
The method according to claim 62, wherein the determining the first measurement time based on the measurement time of each SMTC comprises:

The measurement time of the SMTC with the largest measurement time among the measurement times of the plurality of SMTCs is determined as the first measurement time.
The method according to claim 62 or 63, wherein the i-th SMTC among the plurality of SMTCs is used for co-frequency measurement and does not use MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,ceil(N sample ×K p )×P SMTCi )×CSSF intra ;

When the period of DRX is less than or equal to 320ms, T SMTCi =max(T min ,ceil(M 2 ×N sample ×K p )×max(P SMTCi ,P DRX ))×CSSF intra ;

When the DRX period is greater than 320ms, T SMTCi =ceil(N sample ×K p )×P DRX ×CSSF intra ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T min is determined according to the type of the reference signal and/or the measurement purpose, N sample is determined according to the type of the reference signal and/or the measurement purpose, and K p is determined according to The overlap between the i-th SMTC and the MG corresponding to the i-th SMTC in the time domain is determined, P SMTCi is determined according to the cycle of the i-th SMTC, P DRX represents the cycle of DRX, and M2 is determined according to the period of the network equipment The configuration information is determined, CSSF intra indicates the scaling factor of the carrier level measured at the same frequency, ceil() indicates the rounding up operation, and max() indicates the maximum value operation;

Wherein, K p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF intra is determined according to the The number of SMTCs used in parallel or only in series is determined.
The method according to claim 62 or 63, wherein the i-th SMTC among the plurality of SMTCs is used for co-frequency measurement and uses MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,N sample ×max(T MGRPi ,P SMTCi ))×CSSF intra ;

When the period of DRX is less than or equal to 320ms, T SMTCi =max(T min ,ceil(M 2 ×N sample )×max(T MGRPi ,P SMTCi ,P DRX ))×CSSF intra ;

When the DRX period is greater than 320ms, T SMTCi =N sample ×max(T MGRPi ,P DRX )×CSSF intra ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T MGRPi represents the measurement interval repetition period MGRP of the i-th SMTC using MG, P SMTCi is determined according to the cycle of the i-th SMTC, and P DRX represents the DRX period, M2 is determined according to the information configured by the network device, CSSF intra represents the scaling factor of the carrier level measured at the same frequency, ceil() represents an upward rounding operation, and max() represents the maximum value operation;

Wherein, PSMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF intra is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs.
The method according to claim 62 or 63, wherein the i-th SMTC among the plurality of SMTCs is used for inter-frequency measurement and uses MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,N sample ×max(T MGRPi ,P SMTCi ))×CSSF inter ;

When the DRX period is less than or equal to 320ms, T SMTCi =max(T min ,Ceil(N sample ×M 3 )×max(T MGRPi ,P SMTCi ,P DRX ))×CSSF inter ;

When the DRX cycle is greater than 320ms, T SMTCi = N sample × P DRX × CSSF inter ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T min is determined according to the type of the reference signal and/or the measurement purpose, N sample is determined according to the type of the reference signal and/or the measurement purpose, and T MGRPi represents The i-th SMTC uses the MG measurement interval repetition cycle MGRP, P SMTCi is determined according to the cycle of the i-th SMTC, P DRX represents the cycle of DRX, M 3 is determined according to the information configured by the network device, and CSSF inter represents inter-frequency The scaling factor of the measured carrier level, ceil() means the rounding up operation, max() means the maximum value operation;

Wherein, P SMTCi is also determined according to the scaling factor of the SMTC level of the ith SMTC, or CSSF inter is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the multiple SMTCs.
The method according to claim 62 or 63, wherein the i-th SMTC among the plurality of SMTCs is used for inter-frequency measurement and does not use MG;

Wherein, the scaling factor based on the SMTC level of each SMTC, determining the measurement time of each SMTC includes:

Determine the measurement time of the i-th SMTC according to at least one of the following:

When there is no DRX, T SMTCi =max(T min ,ceil(N sample ×Kp)×P SMTCi )×CSSF inter ;

When the DRX period is less than or equal to 320ms, T SMTCi =max(T min ,ceil(M 3 ×N sample ×K p )×max(P SMTCi ,P DRX ))×CSSF inter ;

When the DRX period is greater than 320ms, T SMTCi =ceil(N sample ×K p )×P DRX ×CSSF inter ;

Wherein, T SMTCi represents the measurement time of the i-th SMTC, T min is determined according to the type of the reference signal and/or the measurement purpose, N sample is determined according to the type of the reference signal and/or the measurement purpose, and K p is determined according to The overlap between the i-th SMTC and the MG corresponding to the i-th SMTC in the time domain is determined, P SMTCi is determined according to the cycle of the i-th SMTC, P DRX represents the cycle of DRX, and M3 is determined according to the period of the network equipment The configuration information is determined, CSSF inter indicates the scaling factor of the carrier level of the inter-frequency measurement, ceil() indicates the upward rounding operation, and max() indicates the maximum value operation;

Wherein, K p is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or P SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, or CSSF inter is determined according to the The number of SMTCs used in parallel or only in series is determined.
The method according to any one of claims 64 to 67, wherein when P SMTCi is also determined according to the scaling factor of the SMTC level of the i-th SMTC, P SMTCi =P SMTCi_initial ×K SMTCi ; where, P SMTCi_initial represents the period of the i-th SMTC, and K SMTCi represents the scaling factor of the SMTC level of the i-th SMTC.
The method according to claim 64 or 67, wherein when the i-th SMTC and the MG used by the i-th SMTC do not overlap or completely overlap in time domain, K p =K SMTCi ; and /or, when the i-th SMTC partially overlaps with the MG used by the i-th SMTC in the time domain, then K p =K SMTCi /(1-(P SMTCi_initial /T MGRPi )), where K SMTCi Indicates the scaling factor of the SMTC level of the i-th SMTC, P SMTCi_initial indicates the period of the i-th SMTC, and T MGRPi indicates the measurement interval repetition period MGRP of the i-th SMTC using MG.
The method according to claim 64 or 67, further comprising:

Based on the overlapping of the i-th SMTC and the MG associated with the i-th SMTC, determine the CSSF intra or CSSF inter determination method, the CSSF intra or CSSF inter determination method includes: using the CSSF intra to determine outside the MG Either the first determination method of CSSF inter , or the second determination method of determining CSSF intra or CSSF inter in the MG.
The method according to claim 70, wherein the measurement signal indicated by the first MO is an intra-frequency synchronization signal and/or a physical broadcast channel block SSB; wherein, the i-th SMTC and the The overlapping situation of the MG associated with the i-th SMTC determines how to determine CSSF intra or CSSF inter , including:

When the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, determine to use the first determination method;

When the i-th SMTC overlaps with the MG part associated with the i-th SMTC, determine to use the first determination method;

When the i-th SMTC is completely coincident with the MG associated with the i-th SMTC, it is determined to use the second determination manner.
The method according to claim 70, wherein the measurement signal indicated by the first MO is an inter-frequency SSB; wherein the overlapping of the MG based on the i-th SMTC and the i-th SMTC is The way to determine CSSF intra or CSSF inter , including:

When the i-th SMTC and the MG associated with the i-th SMTC do not overlap at all, determine to use the first determination method;

When the i-th SMTC overlaps with the MG associated with the i-th SMTC and the terminal device is capable of carrier aggregation CA, determine to use the first determination method;

When the i-th SMTC is completely coincident with the MG associated with the i-th SMTC, it is determined to use the second determination manner.
The method according to claim 65 or 66, further comprising:

The determining manner of determining CSSF intra or CSSF inter is to use the second determining manner of determining CSSF intra or CSSF inter within the MG.
The method according to any one of claims 70 to 72, further comprising:

When using the first determination method, counting the number of carriers configured based on SSB measurement among at least one carrier configured for the terminal device;

Wherein, the at least one carrier includes the first carrier corresponding to the first MO, and the number of statistics of the first carrier is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

The CSSF intra or CSSF inter of the i-th SMTC is determined based on the number of carriers configured with SSB-based measurements in the at least one carrier.
The method according to any one of claims 70 to 73, further comprising:

When using the second determination method, count the number of same-frequency MOs and the number of different-frequency MOs configured for the terminal device and in the MG used by the i-th SMTC;

Wherein, the same-frequency MO or the different-frequency MO includes a first MO, and the number of statistics of the first MO is determined according to the number of SMTCs that cannot be used in parallel or can only be used in series among the plurality of SMTCs;

Determine the CSSF intra or CSSF inter of the i-th SMTC based on the number of same-frequency MOs and the number of inter-frequency MOs.
The method according to any one of claims 64 to 75, further comprising:

K SMTCi is determined based on the number of the multiple SMTCs and the number of SMTCs that can be used by the terminal device at the same time.
The method according to claim 76, wherein K SMTCi is a scaling factor of the SMTC level shared by the multiple SMTCs, K SMTCi =ceil(A/B); wherein, A represents the number of the multiple SMTCs , B represents the number of SMTCs that the terminal device can use at the same time, A>B, and ceil() represents an upward rounding operation.
The method according to any one of claims 64 to 77, characterized in that K SMTCi is determined according to information configured or indicated by network equipment.
The method according to claim 78, wherein K SMTCi is determined according to the activation pattern of the plurality of SMTCs, the activation pattern includes a plurality of bit values, and the scaling factor of the SMTC level of the ith SMTC is determined according to the The ratio of the quantity of the plurality of bit values to the quantity of the first numerical value in the plurality of bit values is determined.
The method according to any one of claims 41 to 79, wherein the multiple SMTCs are associated with multiple cells; and/or, the multiple SMTCs are associated with multiple network devices; and/or, the Multiple SMTCs are associated to multiple reference signals.
A terminal device, characterized in that it includes:

The receiving unit is configured to receive configuration information sent by the network device, and the configuration information is used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

The determining unit is configured to determine whether to use the measurement interval MG when measuring the first MO based on the first SMTC among the plurality of SMTCs.
A network device, characterized in that it includes:

A sending unit, configured to send configuration information to the terminal device, the configuration information being used to configure a first measurement object MO corresponding to a plurality of synchronization signals and/or physical broadcast channel block measurement timing configuration SMTC;

The determining unit is configured to determine whether to use the measurement interval MG when measuring the first MO based on the first SMTC among the plurality of SMTCs.
A terminal device, characterized in that it includes:

A processor and a memory, the memory is used to store a computer program, and the processor is used to call and run the computer program stored in the memory to execute the method according to any one of claims 1 to 40.
A network device, characterized in that it includes:

A processor and a memory, the memory is used to store a computer program, and the processor is used to call and run the computer program stored in the memory to execute the method according to any one of claims 41 to 80.
A chip, characterized in that it comprises:

A processor, for calling and running a computer program from the memory, so that the device equipped with the chip executes the method according to any one of claims 1 to 40 or any one of claims 41 to 80 Methods.
A computer-readable storage medium, characterized in that it is used to store a computer program, the computer program causes the computer to execute the method according to any one of claims 1 to 40 or any one of claims 41 to 80 the method described.
A computer program product, characterized in that it includes computer program instructions, the computer program instructions cause a computer to perform the method according to any one of claims 1 to 40 or any one of claims 41 to 80 Methods.
A computer program, characterized in that the computer program causes a computer to execute the method according to any one of claims 1 to 40 or the method according to any one of claims 41 to 80.