WO2023108556A1 - Wireless communication method, terminal device and network device - Google Patents

Abstract

Provided in the embodiments of the present application are a wireless communication method, a terminal device and a network device. A plurality of MGs are introduced to measure different MOs, frequency layers, cell groups or SSB identifier groups, thereby improving measurement performance. The wireless communication method comprises: a terminal device receiving first information, wherein the first information is determined on the basis of capability information of the terminal device; the capability information of the terminal device comprises at least one of the following: the terminal device supporting simultaneous or parallel processing of a plurality of MGs, and the terminal device supporting simultaneous or parallel processing of a plurality of SMTCs; and the first information is used for indicating at least one of the following: each of at least one frequency layer being associated with a plurality of different MGs, each of at least one MO being associated with the plurality of different MGs, each of at least one cell group being associated with the plurality of different MGs, and each of at least one SSB identifier group being associated with the plurality of different MGs.

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, relate to a wireless communication method, a terminal device, and a network device.

Background technique

In the non-terrestrial network (Non-Terrestrial Networks, NTN) system, due to the large propagation delay of the NTN network, the actual time for the terminal equipment to receive the measurement reference signal of each serving cell and neighboring cells will vary with different propagation delays. with different offsets. How to realize the measurement based on multiple measurement intervals (Measurement Gap, MG) in the NTN system is an urgent problem to be solved.

Contents of the invention

The embodiment of the present application provides a wireless communication method, terminal equipment and network equipment, introducing multiple MGs to implement multiple MG patterns or multiple MGs with different MG offsets to measure different MOs or frequency layers or cell groups Or the SSB identification group, which solves the measurement problem of different SMTCs caused by the different time domain offsets of different satellite orbit cells in the NTN network, and improves the measurement performance.

In a first aspect, a wireless communication method is provided, and the method includes:

The terminal device receives first information, where the first information is determined based on capability information of the terminal device;

Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple MGs, and the terminal device supports simultaneous or parallel processing of multiple SMTCs;

Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, each MO in at least one MO is associated with multiple different MGs, at least one cell group Each cell group in the cell group is associated with multiple different MGs, and each SSB identity group in at least one SSB identity group is associated with multiple different MGs.

In a second aspect, a wireless communication method is provided, and the method includes:

The network device sends first information to the terminal device, where the first information is determined based on capability information of the terminal device;

Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple MGs, and the terminal device supports simultaneous or parallel processing of multiple SMTCs;

Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, each MO in at least one MO is associated with multiple different MGs, at least one cell group Each cell group in the cell group is associated with multiple different MGs, and each SSB identity group in at least one SSB identity group is associated with multiple different MGs.

In a third aspect, a terminal device is provided, configured to execute the method in the first aspect above.

Specifically, the terminal device includes a functional module for executing the method in the first aspect above.

In a fourth aspect, a network device is provided, configured to execute the method in the second aspect above.

Specifically, the network device includes a functional module for executing the method in the second aspect above.

In a fifth aspect, a terminal device is provided, including a processor and a memory. The memory is used to store a computer program, and the processor is used to invoke and run the computer program stored in the memory to execute the method in the first aspect above.

A sixth aspect 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 to execute the method in the second aspect above.

In a seventh aspect, an apparatus is provided for implementing the method in any one of the first aspect to the second aspect above.

Specifically, the device includes: a processor, configured to invoke and run a computer program from the memory, so that the device installed with the device executes the method in any one of the above first to second aspects.

In an eighth aspect, there is provided a computer-readable storage medium for storing a computer program, and the computer program causes a computer to execute the method in any one of the above-mentioned first aspect to the second aspect.

In a ninth aspect, a computer program product is provided, including computer program instructions, the computer program instructions causing a computer to execute the method in any one of the above first to second aspects.

In a tenth aspect, a computer program is provided, which, when running on a computer, causes the computer to execute the method in any one of the above first to second aspects.

Through the above technical solution, the network device configures multiple MGs based on the capability information of the terminal device, wherein each frequency layer in at least one frequency layer is associated with multiple different MGs, and/or each MO in at least one MO is associated with Multiple different MGs, and/or, each cell group in at least one cell group is associated with multiple different MGs, and/or, each SSB identity group in at least one SSB identity group is associated with multiple different MGs. That is, multiple MGs can be introduced to implement multiple MG patterns or multiple MGs with different MG offsets to measure different MOs or frequency layers or cell groups or SSB identification groups, which solves the problem of different satellite orbit cells in the NTN network. Different time-domain offsets lead to different measurement problems for SMTC, improving measurement performance.

Description of drawings

FIG. 1 is a schematic diagram of a communication system architecture applied in an embodiment of the present application.

Fig. 2 is a schematic diagram of an SMTC configuration provided by the present application.

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

Fig. 4 is a schematic block diagram of a terminal device provided according to an embodiment of the present application.

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

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

Fig. 7 is a schematic block diagram of an apparatus provided according to an embodiment of the present application.

Fig. 8 is a schematic block diagram of a communication system provided according to 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 drawings in the embodiments of the present application. Obviously, the described embodiments are part of the embodiments of the present application, but not all of the embodiments. With regard to the embodiments in this application, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the scope of protection of this application.

The technical solution of the embodiment of the present application can be applied to various communication systems, such as: Global System of Mobile communication (Global System of Mobile communication, GSM) system, code division multiple access (Code Division Multiple Access, CDMA) system, broadband code division multiple access (Wideband Code Division Multiple Access, WCDMA) system, General Packet Radio Service (GPRS), Long Term Evolution (LTE) system, Advanced long term evolution (LTE-A) system , New Radio (NR) system, evolution system of NR system, LTE (LTE-based access to unlicensed spectrum, LTE-U) system on unlicensed spectrum, NR (NR-based access to unlicensed spectrum) on unlicensed spectrum unlicensed spectrum (NR-U) system, Non-Terrestrial Networks (NTN) system, Universal Mobile Telecommunications System (UMTS), Wireless Local Area Networks (WLAN), Internet of Things ( internet of things, IoT), wireless fidelity (Wireless Fidelity, WiFi), fifth-generation communication (5th-Generation, 5G) system or other communication systems, etc.

Generally speaking, the number of connections supported by traditional communication systems is limited and easy to implement. However, with the development of communication technology, mobile communication systems will not only support traditional communication, but also support, for example, Device to Device (Device to Device, D2D) communication, Machine to Machine (M2M) communication, Machine Type Communication (MTC), Vehicle to Vehicle (V2V) communication, or Vehicle to everything (V2X) communication, etc. , the embodiments of the present application may also be applied to these communication systems.

In some embodiments, the communication system in the embodiment of the present application can be applied to a carrier aggregation (Carrier Aggregation, CA) scenario, can also be applied to a dual connectivity (Dual Connectivity, DC) scenario, and can also be applied to an independent (Standalone, SA ) network deployment scenarios, or applied to non-independent (Non-Standalone, NSA) network deployment scenarios.

In some embodiments, the communication system in the embodiment of the present application may be applied to an unlicensed spectrum, where the unlicensed spectrum may also be considered as a shared spectrum; or, the communication system in the embodiment of the present application may also be applied to a licensed spectrum, Wherein, the licensed spectrum can also be regarded as a non-shared spectrum.

In some embodiments, the communication system in the embodiment of the present application can be applied to the FR1 frequency band (corresponding to the frequency range of 410MHz to 7.125GHz), can also be applied to the FR2 frequency band (corresponding to the frequency range of 24.25GHz to 52.6GHz), and can also be applied to The new frequency band corresponds to, for example, a frequency range from 52.6 GHz to 71 GHz or a high-frequency frequency range from 71 GHz to 114.25 GHz.

The embodiments of the present application describe various embodiments in conjunction with network equipment and terminal equipment, wherein the terminal equipment may also be referred to as user equipment (User Equipment, UE), access terminal, user unit, user station, mobile station, mobile station, remote station, remote terminal, mobile device, user terminal, terminal, wireless communication device, user agent or user device, etc.

The terminal device can be a station (STATION, ST) in a WLAN, a cellular phone, a cordless phone, a Session Initiation Protocol (Session Initiation Protocol, SIP) phone, a wireless local loop (Wireless Local Loop, WLL) station, a personal digital assistant (Personal Digital Assistant, PDA) devices, handheld devices with wireless communication functions, computing devices or other processing devices connected to wireless modems, vehicle-mounted devices, wearable devices, next-generation communication systems such as terminal devices in NR networks, or future Terminal equipment in the evolved public land mobile network (Public Land Mobile Network, PLMN) network, etc.

In the embodiment of this application, the terminal device can be deployed on land, including indoor or outdoor, handheld, wearable or vehicle-mounted; it can also be deployed on water (such as ships, etc.); it can also be deployed in the air (such as aircraft, balloons and satellites) superior).

In this embodiment of the application, the terminal device may be a mobile phone (Mobile Phone), a tablet computer (Pad), a computer with a wireless transceiver function, a virtual reality (Virtual Reality, VR) terminal device, an augmented reality (Augmented Reality, AR) terminal Equipment, wireless terminal equipment in industrial control, wireless terminal equipment in self driving, wireless terminal equipment in remote medical, wireless terminal equipment in smart grid , wireless terminal equipment in transportation safety, wireless terminal equipment in smart city or wireless terminal equipment in smart home, vehicle communication equipment, wireless communication chip/application-specific integrated circuit (application specific integrated circuit, ASIC)/system-on-chip (System on Chip, SoC), etc.

As an example but not a limitation, in this embodiment of the present application, the terminal device may also be a wearable device. Wearable devices can also be called wearable smart devices, which is a general term for the application of wearable technology to intelligently design daily wear and develop wearable devices, such as glasses, gloves, watches, clothing and shoes. A wearable device is a portable device that is worn directly on the body or integrated into the user's clothing or accessories. Wearable devices are not only a hardware device, but also achieve powerful functions through software support, data interaction, and cloud interaction. Generalized wearable smart devices include full-featured, large-sized, complete or partial functions without relying on smart phones, such as smart watches or smart glasses, etc., and only focus on a certain type of application functions, and need to cooperate with other devices such as smart phones Use, such as various smart bracelets and smart jewelry for physical sign monitoring.

In the embodiment of the present application, the network device may be a device for communicating with the mobile device, and the network device may be an access point (Access Point, AP) in WLAN, a base station (Base Transceiver Station, BTS) in GSM or CDMA , or a base station (NodeB, NB) in WCDMA, or an evolved base station (Evolutional Node B, eNB or eNodeB) in LTE, or a relay station or access point, or a vehicle-mounted device, a wearable device, and an NR network A network device or a base station (gNB) in a network device or a network device in a future evolved PLMN network or a network device in an NTN network.

As an example but not a limitation, in this embodiment of the present application, the network device may have a mobile feature, for example, the network device may be a mobile device. In some embodiments, the network equipment may be a satellite, balloon station. For example, the satellite can be a low earth orbit (low earth orbit, LEO) satellite, a medium earth orbit (medium earth orbit, MEO) satellite, a geosynchronous earth orbit (geosynchronous earth orbit, GEO) satellite, a high elliptical orbit (High Elliptical Orbit, HEO) satellite. ) Satellite etc. In some embodiments, the network device may also be a base station installed on land, in water, or other locations.

In this embodiment of the present application, the network device may provide services for a cell, and the terminal device communicates with the network device through the transmission resources (for example, frequency domain resources, or spectrum resources) used by the cell, and the cell may be a network device ( For example, a cell corresponding to a base station), the cell may belong to a macro base station, or may belong to a base station corresponding to a small cell (Small cell), and the small cell here may include: a metro cell (Metro cell), a micro cell (Micro cell), a pico cell ( Pico cell), Femto cell, etc. These small cells have the characteristics of small coverage and low transmission power, and are suitable for providing high-speed data transmission services.

Exemplarily, a communication system 100 applied in this embodiment of the application is shown in FIG. 1 . The communication system 100 may include a network device 110, and the network device 110 may be a device for communicating with a terminal device 120 (or called a communication terminal, terminal). The network device 110 can provide communication coverage for a specific geographical area, and can communicate with terminal devices located in the coverage area.

FIG. 1 exemplarily shows one network device and two terminal devices. In some embodiments, the communication system 100 may include multiple network devices and each network device may include other numbers of terminal devices within the coverage area. This embodiment of the present application does not limit it.

In some embodiments, the communication system 100 may further include other network entities such as a network controller and a mobility management entity, which is not limited in this embodiment of the present application.

It should be understood that a device with a communication function in the network/system in the embodiment of the present application may be referred to as a communication device. Taking the communication system 100 shown in FIG. 1 as an example, the communication equipment may include a network equipment 110 and a terminal equipment 120 with communication functions. The network equipment 110 and the terminal equipment 120 may be the specific equipment described above, and 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 be understood that this article involves a first communication device and a second communication device, and the first communication device may be a terminal device, such as a mobile phone, a machine facility, a customer premise equipment (Customer Premise Equipment, CPE), an industrial device, a vehicle, etc.; the second communication device The device may be a peer communication device of the first communication device, such as a network device, a mobile phone, an industrial device, a vehicle, and the like. Herein, description is made by taking the first communication device as a terminal device and the second communication device as a network device as a specific example.

The terms used in the embodiments of the present application are only used to explain specific embodiments of the present application, and are not intended to limit the present application. The terms "first", "second", "third" and "fourth" in the specification and claims of the present application and the drawings are used to distinguish different objects, rather than to describe a specific order . Furthermore, the terms "include" and "have", as well as any variations thereof, are intended to cover a non-exclusive inclusion.

It should be understood that the "indication" mentioned in the embodiments of the present application may be a direct indication, may also be an indirect indication, and may also mean that there is an association relationship. For example, A indicates B, which can mean that A directly indicates B, for example, B can be obtained through A; it can also indicate that A indirectly indicates B, for example, A indicates C, and B can be obtained through C; it can also indicate that there is an association between A and B relation.

In the description of the embodiments of the present application, the term "corresponding" may indicate that there is a direct or indirect correspondence between the two, or that there is an association between the two, or that it indicates and is indicated, configuration and is configuration etc.

In this embodiment of the application, "predefined" or "preconfigured" can be realized by pre-saving corresponding codes, tables or other methods that can be used to indicate relevant information in devices (for example, including terminal devices and network devices). The application does not limit its specific implementation. For example, pre-defined may refer to defined in the protocol.

In the embodiment of the present application, the "protocol" may refer to a standard protocol in the communication field, for example, may include the LTE protocol, the NR protocol, and related protocols applied to future communication systems, which is not limited in the present application.

In order to facilitate understanding of the technical solutions of the embodiments of the present application, the technical solutions of the present application are described in detail below through specific examples. The following related technologies may be optionally combined with the technical solutions of the embodiments of the present application as optional solutions, and all of them belong to the protection scope of the embodiments of the present application. The embodiment of the present application includes at least part of the following contents.

In order to better understand the embodiments of the present application, the synchronization signal block measurement timing configuration (synchronization signal block measurement timing configuration, SMTC) and its configuration related to the present application will be described.

SMTC field description: SSB period/offset/duration configuration of redirected Synchronization Signal Block (SSB) frequency. The SMTC is based on the timing of the Primary Cell (PCell). If there is no SMTC field, the terminal device uses the SMTC configured in the NR measurement object (measObjectNR) field with the same SSB frequency and subcarrier spacing.

SMTC configuration can support {5,10,20,40,80,160} millisecond (ms) period and {1,2,3,4,5}ms window length, corresponding offset (offset) and period of each SMTC The strong correlation takes the value {0,...,period-1,}. Since the measurement object (Measurement Object, MO) no longer includes the carrier frequency, the SMTC can be configured independently for each MO instead of each frequency point.

The first subframe (Subframe) in each system frame number (System Frame Number, SFN) of the corresponding NR special cell (Special Cell, SpCell) of each SMTC entity is also defined by the period and offset (periodicityAndOffset) fields of the SMTC To obtain, the following grammatical elements must be satisfied:

SFN mod T = (FLOOR(Offset/10));

if the Periodicity is larger than sf5:

subframe = Offset mod 10;

else:

subframe=Offset or(Offset+5);

with T＝CEIL(Periodicity/10).

For the intra-frequency measurement in the connected state, one intra-frequency layer can be configured with two SMTCs (SMTC1 and SMTC2), and these two SMTCs have the same offset (offset) but different periods. For inter-frequency measurement, only SMTC1 is configured. The period of SMTC2 is shorter than that of SMTC1; the timing offset of SMTC2 follows that of SMTC1; currently, SMTC2 only supports configuration for co-frequency measurement.

For example, the syntax elements corresponding to SMTC1 (that is, SMTC) and SMTC2 may be as follows:

The configuration granularity of SMTC can be per MO (per MO), and one frequency point can have multiple MOs, which correspond to a cell list (celllist). Specific syntax elements can be as follows, for example:

In order to better understand the embodiments of the present application, the relevant measurement intervals and features of the present application will be described.

In order for the terminal device to better realize mobility handover, the network can configure the terminal device to measure the reference signal received power (Reference Signal Received Power, RSRP) of the reference signal of the same frequency, different frequency or different network target neighboring cells in a specific time window, Reference Signal Received Quality (RSRQ) or Signal to Interference plus Noise Ratio (SINR), the specific time window is the measurement interval (Measurement Gap, MG).

The research of NR system mainly considers two frequency bands (Frequency range, FR), which are FR1 and FR2 respectively. Among them, the frequency ranges corresponding to FR1 and FR2 are shown in Table 1 below. FR1 is also called sub 6GHz frequency band, and FR2 is also called mm wave band. It should be noted that the frequency ranges corresponding to FR1 and FR2 are not limited to the frequency ranges shown in Table 1, and can also be adjusted.

Table 1

frequency band Frequency Range FR1 450MHz–6GHz FR2 24.25GHz–52.6GHz

According to whether the terminal device supports the ability of FR1 and FR2 to work independently, there are two types of gaps in the measurement interval, one is the user equipment granularity measurement interval (per UE gap), and the other is the frequency band granularity measurement interval (per FR gap). Further, per FR gap is divided into per FR1gap and per FR2gap. Among them, per UE gap is also called gapUE, per FR1gap is also called gapFR1, and per FR2gap is also called gapFR2. At the same time, the terminal device introduces a capability indication of whether to support FR1 and FR2 to work independently. This capability indication is called independentGapConfig. This capability indication is used by the network device to determine whether the measurement interval of the per FR type can be configured for the terminal device, such as per FR1gap , per FR2gap. Specifically, if the capability indication is used to indicate that the terminal device supports FR1 and FR2 to work independently, the network device can configure a per FR measurement interval; if the capability indication is used to indicate that the terminal device does not support FR1 and FR2 to work independently, the network device does not The measurement interval of per FR type can be configured, and only the measurement interval of per UE type (that is, per UE gap) can be configured for terminal devices.

The per FR1gap, per FR2gap, and per UE gap are described below.

per FR1gap (that is, gapFR1): The measurement interval belonging to the per FR1gap type is only applicable to the measurement of FR1. The per FR1gap and per UE gap do not support simultaneous configuration. The configuration rule of the MG is related to the frequency point of the serving cell and the frequency point of the target cell.

In the Evolved Universal Terrestrial Radio Access (E-UTRA) and NR Dual Connectivity (E-UTRA-NR Dual Connectivity, EN-DC) mode, the master node (Master Node, MN) is the long-term evolution ( Long Term Evolution, LTE) standard, the secondary node (Secondary Node, SN) is NR standard, only the MN can configure per FR1gap.

per FR2gap (that is, gapFR2): The measurement interval belonging to the per FR2gap type is only applicable to the measurement of FR2. Per FR2gap and per UE gap do not support simultaneous configuration. per FR2gap and per FR1gap support simultaneous configuration.

If the terminal device supports the ability of FR1 and FR2 to work independently (that is, the independent gap capability), the terminal device can perform independent measurements on FR1 and FR2, and the terminal device can be configured with a per FR gap type measurement interval, such as per FR1gap type measurement Interval, measurement interval per FR2gap type.

per UE gap (gapUE): The measurement interval belonging to the per UE gap type applies to measurements in all frequency bands (including FR1 and FR2).

Exemplarily, the syntax elements of the parameter configuration of the measurement interval may be as follows:

In some embodiments, NTN UE can also use multiple MGs to measure the same MO and SSB or different cells with different SMTCs on the same frequency point, or to measure different MOs on the same frequency point (SMTC may have same), it can also measure different MOs on different frequency points.

In order to better understand the embodiments of the present application, the problems solved in the present application are described.

For the intra-frequency measurement in the connected state, 2 SMTCs can be configured in 1 intra-frequency layer. These two SMTCs have the same offset but different periods. If terminal devices are configured at the same time, only one of the periods will be selected. The larger one is measured, as shown in Figure 2.

Since the current network can only configure a single gap pattern (single gap pattern) within the unit measurement time, it is likely that the SMTC configuration of the inter-frequency MO cannot be covered by the gap (gap cover).

For the network, this will limit the flexibility of network configuration MO, requiring the network to either align SSBs on the network side to ensure that a single interval pattern can cover SMTCs of different frequency SSBs; or configure MOs in a certain order, which in turn will cause some delays Measurement and reporting of candidate neighboring cells.

For different SMTCs on different MOs of traditional NR terminals (same offset but different period), for different SMTCs on the same MO of NTN terminals (offset and period can be different), they cannot be covered by a single gap pattern (single gap pattern) However, this will restrict the terminal equipment to perform measurements of the corresponding MO in sequence.

In particular, due to the large propagation delay of the NTN network, the actual time for the terminal to receive the measurement reference signal of each serving cell and neighboring cell will vary with different propagation delays. Therefore, when SMTC is configured for each satellite (or base station) in the NTN network, the offset offset of the measurement window needs auxiliary information reference to help whether the time deviation caused by the large path transmission delay is possible, so that the SMTCs of multiple cells can be aligned as much as possible , to ensure that the UE granularity (per UE) or frequency band granularity (per FR) measurement interval configured by the serving cell can cover as many measurement windows as possible.

Based on the above problems, this application proposes a measurement scheme based on multiple MGs, introducing multiple MGs to implement multiple MG patterns or multiple MGs with different MG offsets to measure different MOs or frequency layers or cell groups Or the SSB identification group, which solves the measurement problem of different SMTCs caused by the different time domain offsets of different satellite orbit cells in the NTN network, and improves the measurement performance.

The technical scheme of the present application is described in detail below through specific examples.

FIG. 3 is a schematic flowchart of a wireless communication method 200 according to an embodiment of the present application. As shown in FIG. 3 , the wireless communication method 200 may include at least part of the following content:

S210. The network device sends first information to the terminal device, where the first information is determined based on the capability information of the terminal device; where the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple MG, the terminal device supports simultaneous or parallel processing of multiple SMTCs; where the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, and at least one MO in Each MO is associated with multiple different MGs, each cell group in at least one cell group is associated with multiple different MGs, and each SSB identity group in at least one SSB identity group is associated with multiple different MGs;

S220. The terminal device receives the first information.

The embodiments of the present application may be applied to the NTN system, and may also be applied to the terrestrial network (Terrestrial Networks, TN) system, which is not limited in the present application.

In this embodiment of the present application, the network device may obtain the capability information of the terminal device through pre-configuration or relevant information stipulated in the protocol, or may obtain the capability information of the terminal device through the terminal device.

For example, the terminal device may report the capability information of the terminal device in advance.

In some embodiments, the terminal device performs measurements according to the first information.

In some embodiments, the first information is carried by one of the following:

Radio Resource Control (RRC) signaling, downlink control information (Downlink Control Information, DCI), media access control control element (Media Access Control Control Element, MAC CE).

In this embodiment of the application, "different MGs" may specifically refer to: MGs with different MG patterns, or MGs with different MG offsets (offsets), or MGs with different MG patterns and MG offsets . Wherein, the MG pattern may include the following parameters: measurement interval repetition period (Measurement Gap Repetition Period, MGRP) and measurement interval duration (Measurement Gap Length, MGL). That is, MGs with different MG patterns may specifically refer to MGs with different MGRPs, or MGs with different MGLs.

In some embodiments, when the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with a plurality of different MGs, at least one SMTC configured on each frequency layer has a different Periodic SMTCs are associated with different MGs, or SMTCs with different offsets in at least one SMTC configured on each frequency layer are associated with different MGs, or different MOs in at least one SMTC configured on each frequency layer correspond to The SMTCs are associated with different MGs.

For example, SMTC-1 to SMTC-4 are configured on frequency layer a, where SMTC-1 and SMTC-2 have the same cycle, SMTC-3 and SMTC-4 have the same cycle, and are grouped according to the SMTC cycle. SMTC- 1. SMTC-2 is correspondingly associated with MG1, and SMTC-3 and SMTC-4 with the same period are correspondingly associated with MG2. Optionally, in this case, the periods of MG1 and MG2 may be different.

For another example, SMTC-1 to SMTC-4 are configured on frequency layer a, where the offsets of SMTC-1 and SMTC-2 are the same, and the offsets of SMTC-3 and SMTC-4 are the same. They are grouped according to the SMTC offset. SMTC-1 and SMTC-2 with the same offset are associated with MG1, and SMTC-3 and SMTC-4 with the same offset are associated with MG2. Optionally, in this case, the offsets of MG1 and MG2 may be different.

For another example, SMTC-1 and SMTC-2 are configured on MO1 of frequency layer a, and SMTC-3 and SMTC-4 are configured on MO2 of frequency layer a. According to MO grouping, SMTC-1 and SMTC-2 of MO1 are correspondingly associated To MG1, SMTC-3 and SMTC-4 of MO2 correspond to MG2. Optionally, in this case, the measurement objects or measurement types associated with MG1 and MG2 are different.

In some embodiments, the at least one frequency layer is a part or all of the frequency layers in all NTN frequency layers supported by the terminal device; or, the at least one frequency layer is in all NTN frequency layers supported by the terminal device. Part or all of the frequency layers of an SMTC frequency layer; or, the at least one frequency layer is part or all of the frequency layers supported by the terminal device; or, the at least one frequency layer is supported by the terminal device In all frequency layers, some or all of the frequency layers in which multiple SMTCs are allowed to be configured.

In some embodiments, when the first information is at least used to indicate that each MO in the at least one MO is associated with a plurality of different MGs, the at least one SMTC configured on each MO has an SMTC with a different period Different MGs are associated, or SMTCs with different offsets among at least one SMTC configured on each MO are associated with different MGs.

For example, if SMTC-1 to SMTC-4 are configured on a certain MO, SMTC-1 and SMTC-2 have the same period, and SMTC-3 and SMTC-4 have the same period. They are grouped according to the SMTC period. SMTC- 1. SMTC-2 is correspondingly associated with MG1, and SMTC-3 and SMTC-4 with the same period are correspondingly associated with MG2. Optionally, in this case, the periods of MG1 and MG2 may be different.

For another example, SMTC-1 to SMTC-4 are configured on a certain MO. SMTC-1 and SMTC-2 have the same offset, and SMTC-3 and SMTC-4 have the same offset. They are grouped according to the SMTC offset. SMTC-1 and SMTC-2 with the same offset are associated with MG1, and SMTC-3 and SMTC-4 with the same offset are associated with MG2. Optionally, in this case, the offsets of MG1 and MG2 may be different.

In some embodiments, when the first information is at least used to indicate that each cell group in the at least one cell group is associated with multiple different MGs, the at least one SMTC corresponding to each cell group has different periods The SMTCs of the cell groups are associated with different MGs, or the SMTCs with different offsets among at least one SMTC corresponding to each cell group are associated with different MGs.

For example, a certain cell group corresponds to SMTC-1 to SMTC-4, among them, SMTC-1 and SMTC-2 have the same cycle, SMTC-3 and SMTC-4 have the same cycle, grouped according to SMTC cycle, SMTC- 1. SMTC-2 is correspondingly associated with MG1, and SMTC-3 and SMTC-4 with the same period are correspondingly associated with MG2. Optionally, in this case, the periods of MG1 and MG2 may be different.

For another example, a certain cell group corresponds to SMTC-1 to SMTC-4, wherein, the offsets of SMTC-1 and SMTC-2 are the same, and the offsets of SMTC-3 and SMTC-4 are the same, and they are grouped according to the SMTC offset. SMTC-1 and SMTC-2 with the same offset are associated with MG1, and SMTC-3 and SMTC-4 with the same offset are associated with MG2. Optionally, in this case, the offsets of MG1 and MG2 may be different.

In some embodiments, when the first information is at least used to indicate that each SSB identity group in the at least one SSB identity group is associated with multiple different MGs, the at least one SMTC corresponding to each SSB identity group SMTCs with different periods are associated with different MGs, or SMTCs with different offsets among at least one SMTC corresponding to each SSB identification group are associated with different MGs.

For example, a certain SSB identification group corresponds to SMTC-1 to SMTC-4, among which, SMTC-1 and SMTC-2 have the same cycle, SMTC-3 and SMTC-4 have the same cycle, grouped according to SMTC cycle, SMTC with the same cycle -1. SMTC-2 is correspondingly associated with MG1, and SMTC-3 and SMTC-4 with the same period are correspondingly associated with MG2. Optionally, in this case, the periods of MG1 and MG2 can be different.

For another example, a certain SSB identification group corresponds to SMTC-1 to SMTC-4, wherein, the offsets of SMTC-1 and SMTC-2 are the same, and the offsets of SMTC-3 and SMTC-4 are the same, grouped according to the SMTC offset, SMTC-1 and SMTC-2 with the same offset are associated with MG1, and SMTC-3 and SMTC-4 with the same offset are associated with MG2. Optionally, in this case, the offsets of MG1 and MG2 may be different.

In some embodiments, one MO may correspond to one or more cell groups, and/or one MO may correspond to one or more SSB identification groups, and/or one frequency point may correspond to one or more cell groups, and /Or, one frequency point may correspond to one or more SSB identification groups.

In some embodiments, when the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with a plurality of different MGs, the granularity at which the terminal device performs measurement is frequency point granularity or MO granularity . Specifically, the terminal device determines the measurement time according to the ability to simultaneously process X ₁ SMTCs on the i-th frequency layer; wherein, X ₁ and i are both positive integers, and 1≤i≤the number of frequency layers in the at least one frequency layer , X ₁ is the number of SMTCs on each frequency layer that the terminal device supports to process simultaneously or in parallel.

In some embodiments, when the granularity of measurement performed by the terminal device is frequency point granularity or MO granularity, the measurement time of the i-th frequency layer may be determined through the following ways 1 to 4.

Mode 1, the measurement time of the i-th frequency layer is determined based on the SMTC with the largest period among the SMTCs corresponding to all MOs in the i-th frequency layer.

In some implementations of mode 1, for the measurement of the idle state or the deactivated state, the measurement time T _i of the i-th frequency layer is determined based on the following formula 1:

T _i =a*SSB samples*max(SMTC 1,...SMTC X)*M1 Formula 1

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and M1 is based on the correspondence of all MOs in the i-th frequency layer It is determined by the SMTC with the largest period in the SMTC, and max() means to take the maximum value.

Optionally, in the case that the period of the SMTC with the largest period is greater than 20ms and the period of the Discontinuous Reception (DRX) is less than or equal to 0.64s, M1=2; otherwise, M1=1.

In some implementations of mode 1, for the same-frequency and no-interval measurement of the connected state, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula 2:

T _{i_same frequency} = a*SSB sample*max(SMTC 1,...SMTC X) Formula 2

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and max() represents the maximum value.

In some implementations of mode 1, for the measurement of the connection state with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula 3:

T _{i_different frequency} = a*SSB sample*max(SMTC 1,...SMTC X, MG _i ) Formula 3

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, MG _i represents the MG corresponding to the i-th frequency layer, max () means to take the maximum value.

In some implementations of mode 1, for the same-frequency and no-interval measurement of the connected state, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula 4:

T _{i_same frequency} = a*SSB sample*max(SMTC 1,...SMTC X)*CSSF Formula 4

Wherein, a represents the SSB sample number corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, CSSF represents a carrier scaling factor (Carrier Specific Scaling Factor, CSSF), max() means to take the maximum value.

In some implementations of mode 1, for the measurement of the connection state with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula 5:

T _{i_different frequency} = a*SSB sample*max(SMTC 1,...SMTC X, MG _i )*CSSF Formula 5

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, MG _i represents the MG corresponding to the i-th frequency layer, CSSF Represents the carrier scaling factor, and max() represents the maximum value.

Mode 2, the measurement time of the i-th frequency layer is the sum of the measurement time of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the SMTC corresponding to each MO Determined by the SMTC with the largest mid-period.

In some implementations of mode 2, the i-th frequency layer includes w MOs, and w is a positive integer; for measurements with the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is based on Determined by Equation 6 below:

T _{i_same frequency} = a ₁ *SSB sample*max(SMTC 1,...SMTC x)+...+a _w *SSB sample*max(SMTC x+n,...SMTC X) Equation 6

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, and a _w represents the number of SSB samples among the w MOs The number of SSB samples corresponding to the wth MO, SMTC x+n to SMTC X represents the SMTC corresponding to the wth MO among the w MOs, and the SMTC corresponding to the i-th frequency layer is SMTC1 to SMTC X, max() Indicates the maximum value.

In some implementations of mode 2, the i-th frequency layer includes w MOs, and w is a positive integer; for measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is based on Determined by Equation 7 below:

T _{i_interval} = a ₁ *SSB sample*max(SMTC 1,...SMTC x,MG _i )+...+a _w *SSB sample*max(SMTC x+n,...SMTC X,MG _i ) Formula 7

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, and a _w represents the number of SSB samples among the w MOs The number of SSB samples corresponding to the w-th MO, SMTC x+n to SMTC X represents the SMTC corresponding to the w-th MO among the w-th MOs, MG _i represents the MG corresponding to the i-th frequency layer, and the i-th frequency The SMTCs corresponding to the layers are SMTC 1 to SMTC X, and max() means to take the maximum value.

In some implementations of mode 2, the i-th frequency layer includes w MOs, and w is a positive integer; for measurements with the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is based on Determined by Equation 8 below:

T _{i_same frequency} = a ₁ *SSB sample*max(SMTC 1,...SMTC x)+...+a _w *SSB sample*max(SMTC x+n,...SMTC X)*CSSF Formula 8

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, and a _w represents the number of SSB samples among the w MOs The number of SSB samples corresponding to the w-th MO, SMTC x+n to SMTC X represents the SMTC corresponding to the w-th MO among the w-th MOs, CSSF represents the carrier scaling factor, and the SMTC corresponding to the i-th frequency layer is SMTC 1 To SMTC X, max() means take the maximum value.

In some implementations of mode 2, the i-th frequency layer includes w MOs, and w is a positive integer; for measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is based on Determined by Equation 9 below:

T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x,MG _i )+...+a _w *SSB sample*max(SMTC x+n,...SMTC X,MG _i )*CSSF formula 9

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, a _w represents the wth MO among the w MOs The number of SSB samples corresponding to each MO, SMTC x+n to SMTC X represent the SMTC corresponding to the wth MO among the w MOs, MG _i represents the MG corresponding to the i-th frequency layer, CSSF represents the carrier scaling factor, the The SMTCs corresponding to the i-th frequency layer are SMTC 1 to SMTC X, and max() indicates the maximum value.

Mode 3, the measurement time of the i-th frequency layer is the sum of the measurement time of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the cell corresponding to each MO It is determined by the SMTC corresponding to the group or SSB identification group.

In some implementations of mode 3, the i-th frequency layer includes MO1 and MO2; for measurements with the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula 10 :

T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1)+a ₂ *SSB sample*max(SMTC 2)+b ₁ *SSB sample*max(SMTC3)+b ₂ *SSB sample*max(SMTC 4) Formula 10

Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, and max() represents the maximum value; or,

Among them, a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, SMTC 2 Indicates the SMTC corresponding to SSB identification group 2 in MO1, b ₁ indicates the SSB sample number corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates the SSB identification in MO2 The number of SSB samples corresponding to group 2, SMTC 4 indicates the SMTC corresponding to the SSB identification group 2 in MO2, and max() indicates the maximum value.

In some implementations of mode 3, the i-th frequency layer includes MO1 and MO2; for measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula 11 :

T _{i_different frequency} = a ₁ * SSB sample * max(SMTC 1, MG _i ) + a ₂ * SSB sample * max (SMTC 2, MG _i ) + b ₁ * SSB sample * max (SMTC 3, MG _i ) +b ₂ *SSB samples*max(SMTC 4, MG _i ) Formula 11

Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG _i represents the MG corresponding to the i-th frequency layer, and max() represents the maximum value; or,

Among them, a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, SMTC 2 Indicates the SMTC corresponding to SSB identification group 2 in MO1, b ₁ indicates the SSB sample number corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates the SSB identification in MO2 The number of SSB samples corresponding to group 2, SMTC 4 indicates the SMTC corresponding to the SSB identification group 2 in MO2, MG _i indicates the MG corresponding to the i-th frequency layer, and max() indicates the maximum value.

In some implementations of Mode 3, the i-th frequency layer includes MO1 and MO2; for measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula 12 :

T _{i_different frequency} = a ₁ * SSB sample * max (SMTC 1, MG ₁ ) + a ₂ * SSB sample * max (SMTC 2, MG ₂ ) + b ₁ * SSB sample * max (SMTC 3, MG ₁ ) +b ₂ *SSB samples*max(SMTC 4, MG ₂ ) Formula 12

Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG ₁ represents the MG associated with cell group 1, MG ₂ represents the MG associated with cell group 2, and max() represents the maximum value; or,

Among them, a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, SMTC 2 Indicates the SMTC corresponding to SSB identification group 2 in MO1, b ₁ indicates the SSB sample number corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates the SSB identification in MO2 The number of SSB samples corresponding to group 2, SMTC 4 indicates the SMTC corresponding to the SSB identification group 2 in MO2, MG ₁ indicates the MG associated with cell group 1, MG ₂ indicates the MG associated with cell group 2, and max() indicates the maximum value.

In some embodiments, the measurement granularity of the terminal device is a cell group or an SSB identity group corresponding to a group of SMTCs in the MO. Specifically, the measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identity group on the frequency point in the at least one frequency layer; or, the measurement time for the terminal device to perform the measurement is based on The SMTC configuration corresponding to each cell group or SSB identity group on the MO in the at least one MO is determined.

Specifically, for example, for the measurement of the same frequency and no interval, the measurement time T _{j_same frequency} of the jth cell group is determined based on the following formula 13:

T _{j_same frequency} = a*SSB sample*max(SMTC j) Formula 13

Among them, a represents the number of SSB samples corresponding to the jth cell group, SMTC j represents the SMTC corresponding to the jth cell group, max() represents the maximum value, 1≤j≤the cell corresponding to each frequency point or MO Number of groups.

Specifically, for example, for measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth cell group is determined based on the following formula 14:

T _{j_different frequency} = a*SSB sample*max(SMTC j, MG _j ) Formula 14

Wherein, a represents the number of SSB samples corresponding to the j-th cell group, SMTC j represents the SMTC corresponding to the j-th cell group, MG _j represents the MG corresponding to the j-th cell group, and max() represents the maximum value, 1≤j≤the number of cell groups corresponding to each frequency point or MO.

Specifically, for example, for the measurement of the same frequency and no interval, the measurement time T _{j_same frequency} of the jth SSB identification group is determined based on the following formula 15:

T _{j_same frequency} = a*SSB sample*max(SMTC j) Formula 15

Among them, a indicates the number of SSB samples corresponding to the jth SSB identification group, SMTC j indicates the SMTC corresponding to the jth SSB identification group, max() indicates the maximum value, 1≤j≤ each frequency point or MO corresponding The number of SSB identification groups.

Specifically, for example, for measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth SSB identification group is determined based on the following formula 16:

T _{j_different frequency} = a*SSB sample*max(SMTC j, MG _j ) Formula 16

Among them, a represents the number of SSB samples corresponding to the j th SSB identification group, SMTC j represents the SMTC corresponding to the j th SSB identification group, MG _j represents the MG corresponding to the j th SSB identification group, and max() represents the The maximum value, 1≤j≤the number of SSB identification groups corresponding to each frequency point or MO.

In some embodiments, the terminal device supports simultaneous or parallel processing of multiple SMTCs, including but not limited to at least one of the following:

The terminal equipment supports simultaneous or parallel processing of up to X ₁ SMTCs on each of the N frequency layers;

The terminal equipment supports simultaneous or parallel processing of up to X ₂ SMTCs on each of the Q MOs;

The terminal equipment supports simultaneous or parallel processing of up to X ₃ SMTCs on N frequency layers;

Wherein, N, Q, X ₁ , X ₂ , and X ₃ are all positive integers.

In some embodiments, some or all of the periods, offsets, and durations corresponding to different SMTCs in the X ₁ SMTCs are different; and/or, the periods, offsets, and durations corresponding to different SMTCs in the X ₂ SMTCs Some or all of the durations are different; and/or, some or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₃ SMTCs are different.

In some embodiments, X ₁ <4, and/or, X ₂ <4, and/or, X ₃ <4.

For example, X ₁ =2.

For example, X ₂ =2.

For example, X ₃ =2.

In some embodiments, the N frequency layers are all NTN frequency layers supported by the terminal device; or, the N frequency layers are frequency layers that allow configuration of multiple SMTCs among all NTN frequency layers supported by the terminal device; or , the N frequency layers are all frequency layers supported by the terminal device; or, the N frequency layers are frequency layers that allow configuration of multiple SMTCs among all frequency layers supported by the terminal device.

For example, the NTN frequency layer supported by the terminal device may be the NTN SSB frequency layer.

Specifically, for example, all frequency layers supported by the terminal device include at least an NTN frequency layer and a TN frequency layer.

Therefore, in this embodiment of the application, the network device configures multiple MGs based on the capability information of the terminal device, where each frequency layer in at least one frequency layer is associated with multiple different MGs, and/or, at least one MO in Each MO is associated with multiple different MGs, and/or, each cell group in at least one cell group is associated with multiple different MGs, and/or, each SSB identity group in at least one SSB identity group is associated with multiple Different MGs. That is, multiple MGs can be introduced to implement multiple MG patterns or multiple MGs with different MG offsets to measure different MOs or frequency layers or cell groups or SSB identification groups, which solves the problem of different satellite orbit cells in the NTN network. Different time-domain offsets lead to different measurement problems for SMTC, improving measurement performance.

The method embodiment of the present application is described in detail above in conjunction with FIG. 3 , and the device embodiment of the present application is described in detail below in conjunction with FIG. 4 to FIG. 8 . It should be understood that the device embodiment and the method embodiment correspond to each other, and similar descriptions can be Refer to the method example.

Fig. 4 shows a schematic block diagram of a terminal device 300 according to an embodiment of the present application. As shown in Figure 4, the terminal device 300 includes:

A communication unit 310, configured to receive first information, where the first information is determined based on capability information of the terminal device;

Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple measurement interval MGs, and the terminal device supports simultaneous or parallel processing of multiple synchronization signal block measurement time configuration SMTC;

Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, each MO in at least one measurement object MO is associated with multiple different MGs, at least one Each cell group in the cell group is associated with multiple different MGs, and each SSB identification group in at least one synchronization signal block SSB identification group is associated with multiple different MGs.

In some embodiments, when the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with a plurality of different MGs, at least one SMTC configured on each frequency layer has a different Periodic SMTCs are associated with different MGs, or SMTCs with different offsets in at least one SMTC configured on each frequency layer are associated with different MGs, or different MOs in at least one SMTC configured on each frequency layer correspond to The SMTCs are associated with different MGs.

In some embodiments, when the first information is at least used to indicate that each MO in the at least one MO is associated with a plurality of different MGs, the at least one SMTC configured on each MO has an SMTC with a different period Different MGs are associated, or SMTCs with different offsets among at least one SMTC configured on each MO are associated with different MGs.

In some embodiments, when the first information is at least used to indicate that each cell group in the at least one cell group is associated with multiple different MGs, the at least one SMTC corresponding to each cell group has different periods The SMTCs of the cell groups are associated with different MGs, or the SMTCs with different offsets among at least one SMTC corresponding to each cell group are associated with different MGs.

In some embodiments, when the first information is at least used to indicate that each SSB identity group in the at least one SSB identity group is associated with multiple different MGs, the at least one SMTC corresponding to each SSB identity group SMTCs with different periods are associated with different MGs, or SMTCs with different offsets among at least one SMTC corresponding to each SSB identification group are associated with different MGs.

In some embodiments, the terminal device 300 also includes:

The processing unit 320 is configured to perform measurement according to the first information.

In some embodiments, when the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with a plurality of different MGs, the granularity at which the terminal device performs measurement is frequency point granularity or MO granularity ;

The processing unit 320 is also configured to determine the measurement time according to the capability of simultaneously processing X ₁ SMTCs on the i-th frequency layer;

Wherein, X ₁ and i are both positive integers, 1≤i≤the number of frequency layers in the at least one frequency layer, and X ₁ is the number of SMTCs that the terminal device supports to process simultaneously or in parallel on each frequency layer.

In some embodiments, the measurement time of the i-th frequency layer is determined based on the SMTC with the largest period among the SMTCs corresponding to all MOs in the i-th frequency layer.

In some embodiments, for the measurement of the idle state or the deactivated state, the measurement time T _i of the i-th frequency layer is determined based on the following formula: T _i =a*SSB sample*max(SMTC 1,...SMTC X )*M1;

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and M1 is based on the correspondence of all MOs in the i-th frequency layer It is determined by the SMTC with the largest period in the SMTC, and max() means to take the maximum value.

In some embodiments, when the period of the SMTC with the largest period is greater than 20ms, and the period of the discontinuous reception DRX is less than or equal to 0.64s, M1=2; otherwise, M1=1.

In some embodiments, for the measurement of the connected state at the same frequency without intervals, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample* max(SMTC 1, ...SMTC X); or,

For the measurement of inter-frequency and gaps in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1,... SMTC X,MG _i );

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, MG _i represents the MG corresponding to the i-th frequency layer, max () means to take the maximum value.

In some embodiments, for the measurement of the connected state at the same frequency without intervals, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample* max(SMTC 1, ...SMTC X)*CSSF; or,

For the measurement of inter-frequency and gaps in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1,... SMTC X,MG _i )*CSSF;

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, MG _i represents the MG corresponding to the i-th frequency layer, CSSF Represents the carrier scaling factor, and max() represents the maximum value.

In some embodiments, the measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the measurement time of each MO It is determined by the SMTC with the largest period among the corresponding SMTCs.

In some embodiments, the i-th frequency layer includes w MOs, where w is a positive integer;

For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x )+...+a _w *SSB samples*max(SMTC x+n,...SMTC x);

or,

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x , MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i );

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, and a _w represents the number of SSB samples among the w MOs The number of SSB samples corresponding to the w-th MO, SMTC x+n to SMTC X represents the SMTC corresponding to the w-th MO among the w-th MOs, MG _i represents the MG corresponding to the i-th frequency layer, and the i-th frequency The SMTCs corresponding to the layers are SMTC 1 to SMTC X, and max() means to take the maximum value.

In some embodiments, the i-th frequency layer includes w MOs, where w is a positive integer;

For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x )+...+a _w *SSB samples*max(SMTC x+n,...SMTC x)*CSSF;

or,

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x , MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i )*CSSF;

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, and a _w represents the number of SSB samples among the w MOs The number of SSB samples corresponding to the w-th MO, SMTC x+n to SMTC X represents the SMTC corresponding to the w-th MO among the w-th MOs, MG _i represents the MG corresponding to the i-th frequency layer, and CSSF represents the carrier scaling factor , the SMTCs corresponding to the i-th frequency layer are SMTC 1 to SMTC X, and max() means to take the maximum value.

In some embodiments, the measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the measurement time of each MO It is determined by the SMTC corresponding to the corresponding cell group or SSB identity group.

In some embodiments, the i-th frequency layer includes MO1 and MO2;

For the same frequency and no interval measurement, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1)+a ₂ * SSB samples * max(SMTC 2) + b ₁ * SSB samples * max(SMTC 3) + b ₂ * SSB samples * max(SMTC 4); or,

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB samples*max(SMTC 1, MG _i ) +a ₂ *SSB samples*max(SMTC 2, MG _i )+b ₁ *SSB samples*max(SMTC3, MG _i )+b ₂ *SSB samples*max(SMTC 4, MG _i );

Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG _i represents the MG corresponding to the i-th frequency layer, and max() represents the maximum value; or,

a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, and SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in MO2, b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG _i indicates the MG corresponding to the i-th frequency layer, and max() indicates the maximum value.

In some embodiments, the i-th frequency layer includes MO1 and MO2;

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula:

T _{i_different frequency} = a ₁ * SSB sample * max (SMTC 1, MG ₁ ) + a ₂ * SSB sample * max (SMTC 2, MG ₂ ) + b ₁ * SSB sample * max (SMTC 3, MG ₁ ) +b ₂ *SSB samples*max(SMTC 4, MG ₂ );

Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG ₁ represents the MG associated with cell group 1, MG ₂ represents the MG associated with cell group 2, and max() represents the maximum value; or,

a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, and SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in MO2, b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG ₁ indicates the MG associated with cell group 1, MG ₂ indicates the MG associated with cell group 2, and max() indicates the maximum value.

In some embodiments, the measurement granularity of the terminal device is a cell group or SSB identification group corresponding to a group of SMTCs in the MO;

The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identification group on a frequency point in the at least one frequency layer; or,

The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identity group on the MO in the at least one MO.

In some embodiments, for co-frequency and no interval measurement, the measurement time T _{j_same frequency} of the jth cell group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j );or,

For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth cell group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j );

Wherein, a represents the number of SSB samples corresponding to the j-th cell group, SMTC j represents the SMTC corresponding to the j-th cell group, MG _j represents the MG corresponding to the j-th cell group, and max() represents the maximum value, 1≤j≤the number of cell groups corresponding to each frequency point or MO.

In some embodiments, for the measurement of the same frequency and no interval, the measurement time T _{j_same frequency} of the jth SSB identification group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j); or,

For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth SSB identification group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j );

Among them, a represents the number of SSB samples corresponding to the j th SSB identification group, SMTC j represents the SMTC corresponding to the j th SSB identification group, MG _j represents the MG corresponding to the j th SSB identification group, and max() represents the The maximum value, 1≤j≤the number of SSB identification groups corresponding to each frequency point or MO.

In some embodiments, the terminal device supports simultaneous or parallel processing of multiple SMTCs, including at least one of the following:

The terminal equipment supports simultaneous or parallel processing of up to X ₁ SMTCs on each of the N frequency layers;

The terminal equipment supports simultaneous or parallel processing of up to X ₂ SMTCs on each of the Q MOs;

The terminal equipment supports simultaneous or parallel processing of up to X ₃ SMTCs on N frequency layers;

Wherein, N, Q, X ₁ , X ₂ , and X ₃ are all positive integers.

In some embodiments, some or all of the periods, offsets, and durations corresponding to different SMTCs in the X ₁ SMTCs are different; and/or, the periods, offsets, and durations corresponding to different SMTCs in the X ₂ SMTCs Some or all of the durations are different; and/or, some or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₃ SMTCs are different.

In some embodiments, X ₁ <4, and/or, X ₂ <4, and/or, X ₃ <4.

In some embodiments, the N frequency layers are all non-terrestrial communication network NTN frequency layers supported by the terminal device; or,

The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all NTN frequency layers supported by the terminal device; or,

The N frequency layers are all frequency layers supported by the terminal device; or,

The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all frequency layers supported by the terminal device.

In some embodiments, the first information is carried by one of the following:

Radio resource control RRC signaling, downlink control information DCI, media access control control element MAC CE.

In some embodiments, the above-mentioned communication unit may be a communication interface or a transceiver, or an input-output interface of a communication chip or a system-on-chip. The aforementioned processing unit may be one or more processors.

It should be understood that the terminal device 300 according to the embodiment of the present application may correspond to the terminal device in the method embodiment of the present application, and the above-mentioned and other operations and/or functions of each unit in the terminal device 300 are for realizing the method shown in FIG. 3 For the sake of brevity, the corresponding process of the terminal device in 200 will not be repeated here.

Fig. 5 shows a schematic block diagram of a network device 400 according to an embodiment of the present application. As shown in Figure 5, the network device 400 includes:

A communication unit 410, configured to send first information to the terminal device, where the first information is determined based on capability information of the terminal device;

Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple measurement interval MGs, and the terminal device supports simultaneous or parallel processing of multiple synchronization signal block measurement time configuration SMTC;

Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, each MO in at least one measurement object MO is associated with multiple different MGs, at least one Each cell group in the cell group is associated with multiple different MGs, and each SSB identification group in at least one synchronization signal block SSB identification group is associated with multiple different MGs.

In some embodiments, when the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with a plurality of different MGs, at least one SMTC configured on each frequency layer has a different Periodic SMTCs are associated with different MGs, or SMTCs with different offsets in at least one SMTC configured on each frequency layer are associated with different MGs, or different MOs in at least one SMTC configured on each frequency layer correspond to The SMTCs are associated with different MGs.

In some embodiments, when the first information is at least used to indicate that each MO in the at least one MO is associated with a plurality of different MGs, the at least one SMTC configured on each MO has an SMTC with a different period Different MGs are associated, or SMTCs with different offsets among at least one SMTC configured on each MO are associated with different MGs.

In some embodiments, when the first information is at least used to indicate that each cell group in the at least one cell group is associated with multiple different MGs, the at least one SMTC corresponding to each cell group has different periods The SMTCs of the cell groups are associated with different MGs, or the SMTCs with different offsets among at least one SMTC corresponding to each cell group are associated with different MGs.

In some embodiments, when the first information is at least used to indicate that each SSB identity group in the at least one SSB identity group is associated with multiple different MGs, the at least one SMTC corresponding to each SSB identity group SMTCs with different periods are associated with different MGs, or SMTCs with different offsets among at least one SMTC corresponding to each SSB identification group are associated with different MGs.

In some embodiments, when the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with a plurality of different MGs, the granularity at which the terminal device performs measurement is frequency point granularity or MO granularity , and the measurement time for the terminal device to perform the measurement is determined according to the ability to simultaneously process X ₁ SMTCs on the i-th frequency layer;

Wherein, X ₁ and i are both positive integers, 1≤i≤the number of frequency layers in the at least one frequency layer, and X ₁ is the number of SMTCs that the terminal device supports to process simultaneously or in parallel on each frequency layer.

In some embodiments, the measurement time of the i-th frequency layer is determined based on the SMTC with the largest period among the SMTCs corresponding to all MOs in the i-th frequency layer.

In some embodiments, for the measurement of the idle state or the deactivated state, the measurement time T _i of the i-th frequency layer is determined based on the following formula: T _i =a*SSB sample*max(SMTC 1,...SMTC X )*M1;

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and M1 is based on the correspondence of all MOs in the i-th frequency layer It is determined by the SMTC with the largest period in the SMTC, and max() means to take the maximum value.

In some embodiments, when the period of the SMTC with the largest period is greater than 20ms, and the period of the discontinuous reception DRX is less than or equal to 0.64s, M1=2; otherwise, M1=1.

In some embodiments, for the measurement of the connected state at the same frequency without intervals, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample* max(SMTC 1, ...SMTC X); or,

For the measurement of inter-frequency and gaps in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1,... SMTC X,MG _i );

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, MG _i represents the MG corresponding to the i-th frequency layer, max () means to take the maximum value.

In some embodiments, for the measurement of the connected state at the same frequency without intervals, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample* max(SMTC 1, ...SMTC X)*CSSF; or,

For the measurement of inter-frequency and gaps in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1,... SMTC X,MG _i )*CSSF;

Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, MG _i represents the MG corresponding to the i-th frequency layer, CSSF Represents the carrier scaling factor, and max() represents the maximum value.

In some embodiments, the measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the measurement time of each MO It is determined by the SMTC with the largest period among the corresponding SMTCs.

In some embodiments, the i-th frequency layer includes w MOs, where w is a positive integer;

For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,... SMTC x )+...+a _w *SSB samples*max(SMTC x+n,...SMTC x);

or,

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x , MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i );

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, and a _w represents the number of SSB samples among the w MOs The number of SSB samples corresponding to the w-th MO, SMTC x+n to SMTC X represents the SMTC corresponding to the w-th MO among the w-th MOs, MG _i represents the MG corresponding to the i-th frequency layer, and the i-th frequency The SMTCs corresponding to the layers are SMTC 1 to SMTC X, and max() means to take the maximum value.

In some embodiments, the i-th frequency layer includes w MOs, where w is a positive integer;

For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,... SMTC x )+...+a _w *SSB samples*max(SMTC x+n,...SMTC x)*CSSF;

or,

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x , MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i )*CSSF;

Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTC corresponding to the first MO among the w MOs, and a _w represents the number of SSB samples among the w MOs The number of SSB samples corresponding to the w-th MO, SMTC x+n to SMTC X represents the SMTC corresponding to the w-th MO among the w-th MOs, MG _i represents the MG corresponding to the i-th frequency layer, and CSSF represents the carrier scaling factor , the SMTCs corresponding to the i-th frequency layer are SMTC 1 to SMTC X, and max() means to take the maximum value.

In some embodiments, the measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the measurement time of each MO It is determined by the SMTC corresponding to the corresponding cell group or SSB identity group.

In some embodiments, the i-th frequency layer includes MO1 and MO2;

For the same frequency and no interval measurement, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1)+a ₂ * SSB samples * max(SMTC 2) + b ₁ * SSB samples * max(SMTC 3) + b ₂ * SSB samples * max(SMTC 4); or,

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB samples*max(SMTC 1, MG _i ) +a ₂ *SSB samples*max(SMTC 2, MG _i )+b ₁ *SSB samples*max(SMTC3, MG _i )+b ₂ *SSB samples*max(SMTC 4, MG _i );

Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG _i represents the MG corresponding to the i-th frequency layer, and max() represents the maximum value; or,

a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, and SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in MO2, b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG _i indicates the MG corresponding to the i-th frequency layer, and max() indicates the maximum value.

In some embodiments, the i-th frequency layer includes MO1 and MO2;

For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula:

T _{i_different frequency} = a ₁ * SSB sample * max (SMTC 1, MG ₁ ) + a ₂ * SSB sample * max (SMTC 2, MG ₂ ) + b ₁ * SSB sample * max (SMTC 3, MG ₁ ) +b ₂ *SSB samples*max(SMTC 4, MG ₂ );

Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG ₁ represents the MG associated with cell group 1, MG ₂ represents the MG associated with cell group 2, and max() represents the maximum value; or,

a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, and SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in MO2, b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG ₁ indicates the MG associated with cell group 1, MG ₂ indicates the MG associated with cell group 2, and max() indicates the maximum value.

In some embodiments, the measurement granularity of the terminal device is a cell group or SSB identification group corresponding to a group of SMTCs in the MO;

The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identification group on a frequency point in the at least one frequency layer; or,

The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identity group on the MO in the at least one MO.

In some embodiments, for co-frequency and no interval measurement, the measurement time T _{j_same frequency} of the jth cell group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j );or,

For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth cell group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j );

Wherein, a represents the number of SSB samples corresponding to the j-th cell group, SMTC j represents the SMTC corresponding to the j-th cell group, MG _j represents the MG corresponding to the j-th cell group, and max() represents the maximum value, 1≤j≤the number of cell groups corresponding to each frequency point or MO.

In some embodiments, for the measurement of the same frequency and no interval, the measurement time T _{j_same frequency} of the jth SSB identification group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j); or,

For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth SSB identification group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j );

Among them, a represents the number of SSB samples corresponding to the j th SSB identification group, SMTC j represents the SMTC corresponding to the j th SSB identification group, MG _j represents the MG corresponding to the j th SSB identification group, and max() represents the The maximum value, 1≤j≤the number of SSB identification groups corresponding to each frequency point or MO.

In some embodiments, the terminal device supports simultaneous or parallel processing of multiple SMTCs, including at least one of the following:

The terminal equipment supports simultaneous or parallel processing of up to X ₁ SMTCs on each of the N frequency layers;

The terminal equipment supports simultaneous or parallel processing of up to X ₂ SMTCs on each of the Q MOs;

The terminal equipment supports simultaneous or parallel processing of up to X ₃ SMTCs on N frequency layers;

Wherein, N, Q, X ₁ , X ₂ , and X ₃ are all positive integers.

In some embodiments, some or all of the periods, offsets, and durations corresponding to different SMTCs in the X ₁ SMTCs are different; and/or, the periods, offsets, and durations corresponding to different SMTCs in the X ₂ SMTCs Some or all of the durations are different; and/or, some or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₃ SMTCs are different.

In some embodiments, X ₁ <4, and/or, X ₂ <4, and/or, X ₃ <4.

In some embodiments, the N frequency layers are all non-terrestrial communication network NTN frequency layers supported by the terminal device; or,

The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all NTN frequency layers supported by the terminal device; or,

The N frequency layers are all frequency layers supported by the terminal device; or,

The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all frequency layers supported by the terminal device.

In some embodiments, the first information is carried by one of the following: RRC signaling, DCI, and MAC CE.

In some embodiments, the above-mentioned communication unit may be a communication interface or a transceiver, or an input-output interface of a communication chip or a system-on-chip. The aforementioned processing unit may be one or more processors.

It should be understood that the network device 400 according to the embodiment of the present application may correspond to the network device in the method embodiment of the present application, and the above-mentioned and other operations and/or functions of each unit in the network device 400 are to realize the method shown in FIG. 3 For the sake of brevity, the corresponding processes of the network devices in 200 will not be repeated here.

FIG. 6 is a schematic structural diagram of a communication device 500 provided in an embodiment of the present application. The communication device 500 shown in FIG. 6 includes a processor 510, and the processor 510 can call and run a computer program from a memory, so as to implement the method in the embodiment of the present application.

In some embodiments, as shown in FIG. 6 , the communication device 500 may further include a memory 520 . Wherein, the processor 510 can invoke and run a computer program from the memory 520, so as to implement the method in the embodiment of the present application.

Wherein, the memory 520 may be an independent device independent of the processor 510 , or may be integrated in the processor 510 .

In some embodiments, as shown in FIG. 6, the communication device 500 may further include a transceiver 530, and the processor 510 may control the transceiver 530 to communicate with other devices, specifically, to send information or data to other devices, or Receive messages or data from other devices.

Wherein, the transceiver 530 may include a transmitter and a receiver. The transceiver 530 may further include antennas, and the number of antennas may be one or more.

In some embodiments, the communication device 500 may specifically be the network device of the embodiment of the present application, and the communication device 500 may implement the corresponding processes implemented by the network device in each method of the embodiment of the present application. For the sake of brevity, the Let me repeat.

In some embodiments, the communication device 500 may specifically be the terminal device in the embodiment of the present application, and the communication device 500 may implement the corresponding processes implemented by the terminal device in each method of the embodiment of the present application. For the sake of brevity, the Let me repeat.

Fig. 7 is a schematic structural diagram of a device according to an embodiment of the present application. The apparatus 600 shown in FIG. 7 includes a processor 610, and the processor 610 can call and run a computer program from a memory, so as to implement the method in the embodiment of the present application.

In some embodiments, as shown in FIG. 7 , the device 600 may further include a memory 620 . 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.

Wherein, the memory 620 may be an independent device independent of the processor 610 , or may be integrated in the processor 610 .

In some embodiments, the device 600 may further include an input interface 630 . Wherein, the processor 610 can control the input interface 630 to communicate with other devices or chips, specifically, can obtain information or data sent by other devices or chips.

In some embodiments, the device 600 may further include an output interface 640 . Wherein, the processor 610 can control the output interface 640 to communicate with other devices or chips, specifically, can output information or data to other devices or chips.

In some embodiments, the device can be applied to the network device in the embodiments of the present application, and the device can implement the corresponding processes implemented by the network device in the methods of the embodiments of the present application. For the sake of brevity, details are not repeated here.

In some embodiments, the device can be applied to the terminal device in the embodiment of the present application, and the device can implement the corresponding process implemented by the terminal device in each method of the embodiment of the present application. For the sake of brevity, details are not repeated here.

In some embodiments, the device mentioned in the embodiment of the present application may also be a chip. For example, it may be a system-on-a-chip, a system-on-a-chip, a system-on-a-chip, or a system-on-a-chip.

FIG. 8 is a schematic block diagram of a communication system 700 provided by an embodiment of the present application. As shown in FIG. 8 , the communication system 700 includes a terminal device 710 and a network device 720 .

Wherein, the terminal device 710 can be used to realize the corresponding functions realized by the terminal device in the above method, and the network device 720 can be used to realize the corresponding functions realized by the network device in the above method, for the sake of brevity, no longer repeat.

It should be understood that the processor in the embodiment of the present application may be an integrated circuit chip, which has a signal processing capability. In the implementation process, each step of the above-mentioned method embodiments may be completed by an integrated logic circuit of hardware in a processor or instructions in the form of software. The above-mentioned processor can be a general-purpose processor, a digital signal processor (Digital Signal Processor, DSP), an application-specific integrated circuit (Application Specific Integrated Circuit, ASIC), an off-the-shelf programmable gate array (Field Programmable Gate Array, FPGA) or other available Program logic devices, discrete gate or transistor logic devices, discrete hardware components. Various methods, steps, and logic block diagrams disclosed in the embodiments of the present application may be implemented or executed. A general-purpose processor may be a microprocessor, or the processor may be any conventional processor, or the like. 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 can 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 electrically 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.

It can be understood that the memory in the embodiments of the present application may be a volatile memory or a nonvolatile memory, or may include both volatile and nonvolatile memories. 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 (Synchlink DRAM, SLDRAM ) and Direct Memory Bus Random Access Memory (Direct Rambus RAM, DR RAM). It should be noted that the memory of the systems and methods described herein is intended to include, but not be limited to, these and any other suitable types of memory.

It should be understood that the above-mentioned memory is illustrative but not restrictive. For example, the memory in the embodiment of the present application may also be a static random access memory (static RAM, SRAM), a 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), etc. That is, the memory in the embodiments of the present application is intended to include, but not be limited to, these and any other suitable types of memory.

The embodiment of the present application also provides a computer-readable storage medium for storing computer programs.

In some embodiments, the computer-readable storage medium 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 process implemented by the network device in each method of the embodiment of the present application. For the sake of brevity, I won't repeat them here.

In some embodiments, the computer-readable storage medium can be applied to the terminal device in the embodiments of the present application, and the computer program enables the computer to execute the corresponding processes implemented by the terminal device in the various methods of the embodiments of the present application. For the sake of brevity, I won't repeat them here.

The embodiment of the present application also provides a computer program product, including computer program instructions.

In some embodiments, the computer program product can be applied to the network device in the embodiments of the present application, and the computer program instructions enable the computer to execute the corresponding processes implemented by the network device in the various methods of the embodiments of the present application. For brevity, This will not be repeated here.

In some embodiments, the computer program product can be applied to the terminal device in the embodiments of the present application, and the computer program instructions cause the computer to execute the corresponding processes implemented by the terminal device in the methods of the embodiments of the present application. For brevity, the This will not be repeated here.

The embodiment of the present application also provides a computer program.

In some embodiments, the computer program can be applied to the network device in the embodiment of the present application, and 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, details are not repeated here.

In some embodiments, the computer program can be applied to the terminal 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 terminal device in each method of the embodiment of the present application, For the sake of brevity, details are not repeated here.

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. Skilled artisans 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 present application.

Those skilled in the art can clearly understand that for the convenience and brevity of the description, the specific working process of the above-described system, device and unit can refer to the corresponding process in the foregoing method embodiment, which will not be 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 device embodiments described above are only illustrative. For example, the division of the units is only a logical function division. In actual implementation, there may be other division methods. For example, multiple units or components can be combined or May be integrated into another system, or some features may be ignored, or not implemented. In another point, the mutual coupling or direct coupling or communication connection shown or discussed 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 units described as separate components may or may not be physically separated, and the components shown as units may or may not be physical units, that is, they may be located in one place, or may be distributed to multiple network units. Part or all of the units can be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present application may be integrated into one processing unit, each unit may exist separately physically, or two or more units may be integrated into one unit.

If the functions described above are realized in the form of software function units and sold or used as independent products, they can be stored in a computer-readable storage medium. For such an understanding, the technical solution 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 are used 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 methods described in the various embodiments of the present application. The aforementioned storage media include: U disk, mobile hard disk, read-only memory (Read-Only Memory, ROM), random access memory (Random Access Memory, RAM), magnetic disk or optical disc and other media that can store program codes. .

The above is only a specific implementation of the application, but the scope of protection of the application is not limited thereto. Anyone familiar with the technical field can easily think of changes or substitutions within the technical scope disclosed in the application. Should be covered within the protection scope of this application. Therefore, the protection scope of the present application should be based on the protection scope of the claims.

Claims (63)

A method for wireless communication, comprising: The terminal device receives first information, where the first information is determined based on capability information of the terminal device; Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple measurement interval MGs, and the terminal device supports simultaneous or parallel processing of multiple synchronization signal block measurement time configuration SMTC; Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, and each MO in at least one measurement object MO is associated with multiple different MGs, at least Each cell group in a cell group is associated with multiple different MGs, and each SSB identification group in at least one synchronization signal block SSB identification group is associated with multiple different MGs. The method of claim 1, wherein In the case where the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with multiple different MGs, SMTCs with different periods among the at least one SMTC configured on each frequency layer Associate different MGs, or, the SMTCs with different offsets among the at least one SMTC configured on each frequency layer are associated with different MGs, or, the at least one SMTC configured on each frequency layer corresponds to different MOs The SMTC is associated with different MGs. The method of claim 1, wherein In the case where the first information is at least used to indicate that each MO in the at least one MO is associated with multiple different MGs, SMTCs with different periods among the at least one SMTC configured on each MO are associated with different The MG, or, among the at least one SMTC configured on each MO, SMTCs with different offsets are associated with different MGs. The method of claim 1, wherein In the case where the first information is at least used to indicate that each cell group in the at least one cell group is associated with multiple different MGs, the at least one SMTC corresponding to each cell group has SMTC associations with different periods Different MGs, or, SMTCs with different offsets among at least one SMTC corresponding to each cell group are associated with different MGs. The method of claim 1, wherein In the case where the first information is at least used to indicate that each SSB identification group in the at least one SSB identification group is associated with multiple different MGs, the at least one SMTC corresponding to each SSB identification group has different periods Different MGs are associated with different SMTCs, or SMTCs with different offsets among at least one SMTC corresponding to each SSB identification group are associated with different MGs. The method according to any one of claims 1 to 5, further comprising: The terminal device performs measurement according to the first information. The method according to claim 6, wherein when the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with multiple different MGs, the terminal device executes The measured granularity is frequency point granularity or MO granularity; The method also includes: The terminal device determines the measurement time according to the capability of simultaneously processing X ₁ SMTCs on the i-th frequency layer; Wherein, X ₁ and i are both positive integers, 1≤i≤the number of frequency layers in the at least one frequency layer, and X ₁ is the number of SMTCs that the terminal device supports to process simultaneously or in parallel on each frequency layer. The method according to claim 7, wherein the measurement time of the i-th frequency layer is determined based on the SMTC with the largest period among the SMTCs corresponding to all MOs in the i-th frequency layer. The method of claim 8, wherein For the measurement of the idle state or the deactivated state, the measurement time T _i of the i-th frequency layer is determined based on the following formula: T _i =a*SSB sample*max(SMTC 1,...SMTC X)*M1; Wherein, a represents the number of SSB samples corresponding to all MOs in the ith frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and M1 is based on the i-th frequency layer It is determined by the SMTC with the largest period among the SMTCs corresponding to all MOs, and max() means to take the maximum value. The method according to claim 9, wherein when the period of the SMTC with the largest period is greater than 20ms and the period of the discontinuous reception DRX is less than or equal to 0.64s, M1=2; otherwise, M1=1. The method of claim 8, wherein For the measurement of the same frequency and no interval in the connected state, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample*max(SMTC 1, …SMTC X); or, For the measurement of different frequencies and intervals in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1, ...SMTC X,MG _i ); Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and MG _i represents the corresponding MG, max() means take the maximum value. The method of claim 8, wherein For the measurement of the same frequency and no interval in the connected state, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample*max(SMTC 1, ...SMTC X)*CSSF; or, For the measurement of different frequencies and intervals in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1, ...SMTC X,MG _i )*CSSF; Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and MG _i represents the corresponding MG, CSSF means the carrier scaling factor, and max() means take the maximum value. The method of claim 7, wherein The measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all the MOs in the i-th frequency layer, and the measurement time of each MO is based on the SMTC corresponding to each MO Determined by the SMTC with the largest mid-period. The method according to claim 13, wherein the i-th frequency layer comprises w MOs, and w is a positive integer; For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x) + ... + a _w * SSB samples * max(SMTC x+n, ...SMTC x); or, For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x, MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i ); Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTCs corresponding to the first MO among the w MOs, and a _w represents the w The number of SSB samples corresponding to the w-th MO among the MOs, SMTC x+n to SMTC X represent the SMTC corresponding to the w-th MO among the w-th MOs, and MG _i represents the MG corresponding to the i-th frequency layer, The SMTCs corresponding to the i-th frequency layer are SMTC 1 to SMTC X, and max() means to take the maximum value. The method according to claim 13, wherein the i-th frequency layer comprises w MOs, and w is a positive integer; For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x)+...+a _w *SSB samples*max(SMTC x+n,...SMTC x)*CSSF; or, For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x, MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i )*CSSF; Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTCs corresponding to the first MO among the w MOs, and a _w represents the w The number of SSB samples corresponding to the w-th MO among the MOs, SMTC x+n to SMTC X represent the SMTC corresponding to the w-th MO among the w-th MOs, and MG _i represents the MG corresponding to the i-th frequency layer, CSSF represents a carrier scaling factor, the SMTCs corresponding to the i-th frequency layer are SMTC 1 to SMTC X, and max() represents a maximum value. The method of claim 7, wherein The measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the cell corresponding to each MO It is determined by the SMTC corresponding to the group or SSB identification group. The method of claim 16, wherein, The i-th frequency layer includes MO1 and MO2; For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1)+a ₂ * SSB samples * max(SMTC 2) + b ₁ * SSB samples * max(SMTC 3) + b ₂ * SSB samples * max(SMTC 4); or, For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1, MG _i )+a ₂ *SSB samples*max(SMTC 2, MG _i )+b ₁ *SSB samples*max(SMTC3, MG _i )+b ₂ *SSB samples*max(SMTC 4, MG _i ); Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG _i represents the MG corresponding to the i-th frequency layer, and max() represents the maximum value; or, a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in , b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG _i indicates the MG corresponding to the i-th frequency layer, and max() indicates the maximum value. The method of claim 16, wherein, The i-th frequency layer includes MO1 and MO2; For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} = a ₁ * SSB sample * max (SMTC 1, MG ₁ ) + a ₂ * SSB sample * max (SMTC 2, MG ₂ ) + b ₁ * SSB sample * max (SMTC 3, MG ₁ ) +b ₂ *SSB samples*max(SMTC 4, MG ₂ ); Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG ₁ represents the MG associated with cell group 1, MG ₂ represents the MG associated with cell group 2, and max() represents the maximum value; or, a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, and SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in MO2, b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG ₁ indicates the MG associated with cell group 1, MG ₂ indicates the MG associated with cell group 2, and max() indicates the maximum value. The method of claim 6, wherein The granularity of the measurement performed by the terminal device is the cell group or SSB identification group corresponding to a group of SMTCs in the MO; The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identity group on a frequency point in the at least one frequency layer; or, The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identity group on the MO in the at least one MO. The method of claim 19, wherein, For the same frequency and no interval measurement, the measurement time T _{j_same frequency} of the jth cell group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j); or, For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth cell group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j ); Wherein, a represents the number of SSB samples corresponding to the j-th cell group, SMTC j represents the SMTC corresponding to the j-th cell group, MG _j represents the MG corresponding to the j-th cell group, and max() represents the The maximum value, 1≤j≤the number of cell groups corresponding to each frequency point or MO. The method of claim 19, wherein, For the measurement of the same frequency and no interval, the measurement time T _{j_same frequency} of the jth SSB identification group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j); or, For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth SSB identification group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j ); Wherein, a represents the number of SSB samples corresponding to the j th SSB identification group, SMTC j represents the SMTC corresponding to the j th SSB identification group, MG _j represents the MG corresponding to the j th SSB identification group, max( ) represents the maximum value, 1≤j≤the number of SSB identification groups corresponding to each frequency point or MO. The method according to any one of claims 1 to 21, wherein the terminal device supports simultaneous or parallel processing of multiple SMTCs, including at least one of the following: The terminal device supports simultaneous or parallel processing of up to X ₁ SMTCs on each of the N frequency layers; The terminal device supports simultaneous or parallel processing of up to X ₂ SMTCs on each of the Q MOs; The terminal device supports simultaneous or parallel processing of up to X ₃ SMTCs on N frequency layers; Wherein, N, Q, X ₁ , X ₂ , and X ₃ are all positive integers. The method of claim 22, wherein, Part or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₁ SMTCs are different; and/or, Part or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₂ SMTCs are different; and/or, Part or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₃ SMTCs are different. The method according to claim 22 or 23, characterized in that, X ₁ <4, and/or, X ₂ <4, and/or, X ₃ <4. A method according to any one of claims 22 to 24, wherein, The N frequency layers are all non-terrestrial communication network NTN frequency layers supported by the terminal device; or, The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all NTN frequency layers supported by the terminal device; or, The N frequency layers are all frequency layers supported by the terminal device; or, The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all frequency layers supported by the terminal device. A method according to any one of claims 1 to 25, wherein The first information is carried by one of the following: Radio resource control RRC signaling, downlink control information DCI, media access control control element MAC CE. A method for wireless communication, comprising: The network device sends first information to the terminal device, where the first information is determined based on capability information of the terminal device; Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple measurement interval MGs, and the terminal device supports simultaneous or parallel processing of multiple synchronization signal block measurement time configuration SMTC; Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, and each MO in at least one measurement object MO is associated with multiple different MGs, at least Each cell group in a cell group is associated with multiple different MGs, and each SSB identification group in at least one synchronization signal block SSB identification group is associated with multiple different MGs. The method of claim 27, wherein, In the case where the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with multiple different MGs, SMTCs with different periods among the at least one SMTC configured on each frequency layer Associate different MGs, or, the SMTCs with different offsets among the at least one SMTC configured on each frequency layer are associated with different MGs, or, the at least one SMTC configured on each frequency layer corresponds to different MOs The SMTC is associated with different MGs. The method of claim 27, wherein, In the case where the first information is at least used to indicate that each MO in the at least one MO is associated with multiple different MGs, SMTCs with different periods among the at least one SMTC configured on each MO are associated with different The MG, or, among the at least one SMTC configured on each MO, SMTCs with different offsets are associated with different MGs. The method of claim 27, wherein, In the case where the first information is at least used to indicate that each cell group in the at least one cell group is associated with multiple different MGs, the at least one SMTC corresponding to each cell group has SMTC associations with different periods Different MGs, or, SMTCs with different offsets among at least one SMTC corresponding to each cell group are associated with different MGs. The method of claim 27, wherein, In the case where the first information is at least used to indicate that each SSB identification group in the at least one SSB identification group is associated with multiple different MGs, the at least one SMTC corresponding to each SSB identification group has different periods Different MGs are associated with different SMTCs, or SMTCs with different offsets among at least one SMTC corresponding to each SSB identification group are associated with different MGs. A method as claimed in any one of claims 27 to 31 wherein, In the case where the first information is at least used to indicate that each frequency layer in the at least one frequency layer is associated with multiple different MGs, the granularity at which the terminal device performs measurement is frequency point granularity or MO granularity, and the The measurement time for the terminal equipment to perform the measurement is determined according to the ability to simultaneously process X ₁ SMTCs on the i-th frequency layer; Wherein, X ₁ and i are both positive integers, 1≤i≤the number of frequency layers in the at least one frequency layer, and X ₁ is the number of SMTCs that the terminal device supports to process simultaneously or in parallel on each frequency layer. The method according to claim 32, wherein the measurement time of the i-th frequency layer is determined based on the SMTC with the largest period among the SMTCs corresponding to all MOs in the i-th frequency layer. The method of claim 33, wherein, For the measurement of the idle state or the deactivated state, the measurement time T _i of the i-th frequency layer is determined based on the following formula: T _i =a*SSB sample*max(SMTC 1,...SMTC X)*M1; Wherein, a represents the number of SSB samples corresponding to all MOs in the ith frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and M1 is based on the i-th frequency layer It is determined by the SMTC with the largest period among the SMTCs corresponding to all MOs, and max() means to take the maximum value. The method according to claim 34, wherein when the period of the SMTC with the largest period is greater than 20ms and the period of the discontinuous reception DRX is less than or equal to 0.64s, M1=2; otherwise, M1=1. The method of claim 33, wherein, For the measurement of the same frequency and no interval in the connected state, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample*max(SMTC 1, …SMTC X); or, For the measurement of different frequencies and intervals in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1, ...SMTC X,MG _i ); Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and MG _i represents the corresponding MG, max() means take the maximum value. The method of claim 33, wherein, For the measurement of the same frequency and no interval in the connected state, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a*SSB sample*max(SMTC 1, ...SMTC X)*CSSF; or, For the measurement of different frequencies and intervals in the connected state, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a*SSB sample*max(SMTC 1, ...SMTC X,MG _i )*CSSF; Among them, a represents the number of SSB samples corresponding to all MOs in the i-th frequency layer, SMTC 1 to SMTC X represent the SMTCs corresponding to the i-th frequency layer, and MG _i represents the corresponding MG, CSSF means the carrier scaling factor, and max() means take the maximum value. The method of claim 32, wherein, The measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all the MOs in the i-th frequency layer, and the measurement time of each MO is based on the SMTC corresponding to each MO Determined by the SMTC with the largest mid-period. The method according to claim 38, wherein the i-th frequency layer comprises w MOs, and w is a positive integer; For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x) + ... + a _w * SSB samples * max(SMTC x+n, ...SMTC x); or, For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,... SMTC x, MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i ); Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTCs corresponding to the first MO among the w MOs, and a _w represents the w The number of SSB samples corresponding to the w-th MO among the MOs, SMTC x+n to SMTC X represent the SMTC corresponding to the w-th MO among the w-th MOs, and MG _i represents the MG corresponding to the i-th frequency layer, The SMTCs corresponding to the i-th frequency layer are SMTC 1 to SMTC X, and max() means to take the maximum value. The method according to claim 38, wherein the i-th frequency layer comprises w MOs, and w is a positive integer; For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x)+...+a _w *SSB samples*max(SMTC x+n,...SMTC x)*CSSF; or, For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1,...SMTC x, MG _i )+...+a _w *SSB samples*max(SMTC x+n,...SMTC X, MG _i )*CSSF; Among them, a ₁ represents the number of SSB samples corresponding to the first MO among the w MOs, SMTC 1 to SMTC x represent the SMTCs corresponding to the first MO among the w MOs, and a _w represents the w The number of SSB samples corresponding to the w-th MO among the MOs, SMTC x+n to SMTC X represent the SMTC corresponding to the w-th MO among the w-th MOs, and MG _i represents the MG corresponding to the i-th frequency layer, CSSF represents a carrier scaling factor, the SMTCs corresponding to the i-th frequency layer are SMTC 1 to SMTC X, and max() represents a maximum value. The method of claim 32, wherein, The measurement time of the i-th frequency layer is the sum of the measurement times of each MO in all MOs in the i-th frequency layer, and the measurement time of each MO is based on the cell corresponding to each MO It is determined by the SMTC corresponding to the group or SSB identification group. The method of claim 41, wherein, The i-th frequency layer includes MO1 and MO2; For the measurement of the same frequency and no interval, the measurement time T _{i_same frequency} of the i-th frequency layer is determined based on the following formula: T _{i_same frequency} =a ₁ *SSB sample*max(SMTC 1)+a ₂ * SSB samples * max(SMTC 2) + b ₁ * SSB samples * max(SMTC 3) + b ₂ * SSB samples * max(SMTC 4); or, For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} =a ₁ *SSB sample*max(SMTC 1, MG _i )+a ₂ *SSB samples*max(SMTC 2, MG _i )+b ₁ *SSB samples*max(SMTC3, MG _i )+b ₂ *SSB samples*max(SMTC 4, MG _i ); Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG _i represents the MG corresponding to the i-th frequency layer, and max() represents the maximum value; or, a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in , b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG _i indicates the MG corresponding to the i-th frequency layer, and max() indicates the maximum value. The method of claim 41, wherein, The i-th frequency layer includes MO1 and MO2; For measurements with different frequencies and intervals, the measurement time T _{i_different frequency} of the i-th frequency layer is determined based on the following formula: T _{i_different frequency} = a ₁ * SSB sample * max (SMTC 1, MG ₁ ) + a ₂ * SSB sample * max (SMTC 2, MG ₂ ) + b ₁ * SSB sample * max (SMTC 3, MG ₁ ) +b ₂ *SSB samples*max(SMTC 4, MG ₂ ); Among them, a ₁ represents the number of SSB samples corresponding to cell group 1 in MO1, SMTC 1 represents the SMTC corresponding to cell group 1 in MO1, a ₂ represents the number of SSB samples corresponding to cell group 2 in MO1, and SMTC 2 represents the number of SSB samples in MO1 SMTC corresponding to cell group 2 in MO2, b ₁ represents the number of SSB samples corresponding to cell group 1 in MO2, SMTC 3 represents the SMTC corresponding to cell group 1 in MO2, b ₂ represents the number of SSB samples corresponding to cell group 2 in MO2 , SMTC 4 represents the SMTC corresponding to cell group 2 in MO2, MG ₁ represents the MG associated with cell group 1, MG ₂ represents the MG associated with cell group 2, and max() represents the maximum value; or, a ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO1, SMTC 1 indicates the SMTC corresponding to SSB identification group 1 in MO1, a ₂ indicates the number of SSB samples corresponding to SSB identification group 2 in MO1, and SMTC 2 indicates MO1 SMTC corresponding to SSB identification group 2 in MO2, b ₁ indicates the number of SSB samples corresponding to SSB identification group 1 in MO2, SMTC 3 indicates the SMTC corresponding to SSB identification group 1 in MO2, b ₂ indicates SSB identification group 2 in MO2 The number of corresponding SSB samples, SMTC 4 indicates the SMTC corresponding to SSB identification group 2 in MO2, MG ₁ indicates the MG associated with cell group 1, MG ₂ indicates the MG associated with cell group 2, and max() indicates the maximum value. A method as claimed in any one of claims 27 to 31 wherein, The granularity of the measurement performed by the terminal device is the cell group or SSB identification group corresponding to a group of SMTCs in the MO; The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identity group on a frequency point in the at least one frequency layer; or, The measurement time for the terminal device to perform the measurement is determined based on the SMTC configuration corresponding to each cell group or SSB identity group on the MO in the at least one MO. The method of claim 44, wherein, For the same frequency and no interval measurement, the measurement time T _{j_same frequency} of the jth cell group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j); or, For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth cell group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j ); Wherein, a represents the number of SSB samples corresponding to the j-th cell group, SMTC j represents the SMTC corresponding to the j-th cell group, MG _j represents the MG corresponding to the j-th cell group, and max() represents the The maximum value, 1≤j≤the number of cell groups corresponding to each frequency point or MO. The method of claim 44, wherein, For the measurement of the same frequency and no interval, the measurement time T _{j_same frequency} of the jth SSB identification group is determined based on the following formula: T _{j_same frequency} =a*SSB sample*max(SMTC j); or, For measurements with different frequencies and intervals, the measurement time T _{j_different frequency} of the jth SSB identification group is determined based on the following formula: T _{j_different frequency} =a*SSB sample*max(SMTC j,MG _j ); Wherein, a represents the number of SSB samples corresponding to the j th SSB identification group, SMTC j represents the SMTC corresponding to the j th SSB identification group, MG _j represents the MG corresponding to the j th SSB identification group, max( ) represents the maximum value, 1≤j≤the number of SSB identification groups corresponding to each frequency point or MO. The method according to any one of claims 27 to 46, wherein the terminal device supports simultaneous or parallel processing of multiple SMTCs, including at least one of the following: The terminal device supports simultaneous or parallel processing of up to X ₁ SMTCs on each of the N frequency layers; The terminal device supports simultaneous or parallel processing of up to X ₂ SMTCs on each of the Q MOs; The terminal device supports simultaneous or parallel processing of up to X ₃ SMTCs on N frequency layers; Wherein, N, Q, X ₁ , X ₂ , and X ₃ are all positive integers. The method of claim 47, wherein, Part or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₁ SMTCs are different; and/or, Part or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₂ SMTCs are different; and/or, Part or all of the periods, offsets, and durations corresponding to different SMTCs among the X ₃ SMTCs are different. A method as claimed in claim 47 or 48, characterized in that, X ₁ <4, and/or, X ₂ <4, and/or, X ₃ <4. A method as claimed in any one of claims 47 to 49 wherein, The N frequency layers are all non-terrestrial communication network NTN frequency layers supported by the terminal device; or, The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all NTN frequency layers supported by the terminal device; or, The N frequency layers are all frequency layers supported by the terminal device; or, The N frequency layers are frequency layers that allow configuration of multiple SMTCs among all frequency layers supported by the terminal device. A method according to any one of claims 27 to 50, wherein, The first information is carried by one of the following: Radio resource control RRC signaling, downlink control information DCI, media access control control element MAC CE. A terminal device, characterized in that it includes: a communication unit, configured to receive first information, where the first information is determined based on capability information of the terminal device; Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple measurement interval MGs, and the terminal device supports simultaneous or parallel processing of multiple synchronization signal block measurement time configuration SMTC; Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, and each MO in at least one measurement object MO is associated with multiple different MGs, at least Each cell group in a cell group is associated with multiple different MGs, and each SSB identification group in at least one synchronization signal block SSB identification group is associated with multiple different MGs. A network device, characterized in that it includes: a communication unit, configured to send first information to a terminal device, where the first information is determined based on capability information of the terminal device; Wherein, the capability information of the terminal device includes at least one of the following: the terminal device supports simultaneous or parallel processing of multiple measurement interval MGs, and the terminal device supports simultaneous or parallel processing of multiple synchronization signal block measurement time configuration SMTC; Wherein, the first information is used to indicate at least one of the following: each frequency layer in at least one frequency layer is associated with multiple different MGs, and each MO in at least one measurement object MO is associated with multiple different MGs, at least Each cell group in a cell group is associated with multiple different MGs, and each SSB identification group in at least one synchronization signal block SSB identification group is associated with multiple different MGs. A terminal device, characterized in that it includes: a processor and a memory, the memory is used to store a computer program, the processor is used to call and run the computer program stored in the memory, and execute the computer program described in claims 1 to 26 any one of the methods described. A network device, characterized by comprising: a processor and a memory, the memory is used to store computer programs, the processor is used to invoke and run the computer programs stored in the memory, and perform the tasks described in claims 27 to 51 any one of the methods described. A chip, characterized by comprising: a processor, configured to invoke and run a computer program from a memory, so that a device installed with the chip executes the method according to any one of claims 1 to 26. A chip, characterized by comprising: a processor, configured to call and run a computer program from a memory, so that a device installed with the chip executes the method according to any one of claims 27 to 51. A computer-readable storage medium, characterized by being used for storing a computer program, the computer program causing a computer to execute the method according to any one of claims 1 to 26. A computer-readable storage medium, characterized by being used for storing a computer program, the computer program causes a computer to execute the method according to any one of claims 27 to 51. A computer program product, characterized by comprising computer program instructions, the computer program instructions cause a computer to execute the method as claimed in any one of claims 1 to 26. A computer program product, characterized by comprising computer program instructions, the computer program instructions cause a computer to execute the method according to any one of claims 27 to 51. A computer program, characterized in that the computer program causes a computer to execute the method according to any one of claims 1-26. A computer program, characterized in that the computer program causes a computer to execute the method according to any one of claims 27 to 51.

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