CN107548078B - A method for controlling measurement gap resources and a multimode terminal - Google Patents

Abstract

The invention relates to the technical field of communications, and discloses a control method for measuring gap resources and a multi-mode terminal. In the present invention, a method for controlling measurement gap resources includes: acquiring measurement gaps required by measurement control modules of various modes in a multi-mode terminal; and allocating measurement gaps according to the requirements of measurement control modules in each mode for measurement gaps ; Among them, the whole measurement gap is preferentially allocated to the measurement control module that needs the whole measurement gap, and the measurement control module that receives the whole measurement gap cuts the whole measurement gap as needed, and then redistributes the fragment measurement gap obtained after cutting. For at least one measurement control module that does not require an integral measurement gap. The invention also discloses a multi-mode terminal. The embodiment of the present invention realizes full utilization of measurement gap resources, promotes the timeliness of terminal measurement update, and optimizes the mobile performance of the terminal.

Description

A method for controlling measurement gap resources and a multimode terminal

technical field

The present invention relates to the field of communication technologies, and in particular, to a method for controlling measurement gap resources and a multi-mode terminal.

Background technique

The development of mobile communication so far has formed a pattern that requires the coexistence of multiple network standards, such as the second generation mobile communication system (2-Generation wireless telephone technology, referred to as "2G"): Global System for Mobile Communication (Global System for Mobile Communication, referred to as "" GSM"), General Packet Radio Service (General Packet Radio Service, referred to as "GPRS"), Enhanced Data Rate (Enhanced Data Rate for GSMEvolution, referred to as "EDGE"); the third generation mobile communication system (3-Generation wireless telephone technology, referred to as "" 3G”): Wideband Code Division Multiple Access (WCDMA for short), Time Division-Synchronous Code Division Multiple Access (TD-SCDMA for short); next-generation mobile communications System: Long Term Evolution (Long Term Evolution, "LTE" for short), Worldwide Interoperability for Microwave Access (Worldwide Interoperability for Microwave Access, "WIMAX" for short). Due to the different network construction times of communication networks in different places, the coverage of each mobile network is different. Therefore, the terminal that supports automatic full mode has an absolute advantage in product competition.

However, business data, measurement and scheduling processing in different modes are all an independent system. In order to reduce the coupling between the processes, the related inter-system measurement requirements are generally implemented in modules according to the mode (for example: GSM, WCDMA, TD-SCDMA, LTE). Message interaction is performed between the processing module and a multi-mode controller (Multi-Module Control, "MMC" for short).

At present, multi-card multi-standby product forms are widely available in the market, and each mode of multi-card multi-standby still shares a set of radio frequency transceivers. Therefore, when one of the standbys is in a connected state, it is also necessary to allocate measurement gap resources to the other idle standby mode, so as to implement measurement update and maintain the mobility of the idle standby.

Based on the multi-mode software architecture shown in Figure 1, the currently commonly used measurement gap resource allocation scheme is: the main mode counts the measurement requirements, and allocates the measurement gap (GAP) in a time-sharing manner, that is, the entire segment in a scheduling period is continuously allocated. GAP is measured and allocated to a certain mode. Figure 2 lists a GAP allocation mode residing under LTE.

Among them, the measurement GAP of the modules numbered 0, 4, and 8 is the measurement GAP reserved for this mode in the LTE main mode; the measurement GAP of the modules numbered 1, 5, and 9 is the measurement allocated by the LTE main mode to TD-SCDMA. GAP resources; the measurement GAPs of modules numbered 2, 6, and 10 are the measurement GAPs allocated to WCDMA in the LTE main mode; the measurement GAPs of modules numbered 3, 7, and 11 are the measurement GAPs allocated to GSM in the LTE main mode.

Therefore, the inventor of the present application found that, according to the fixed-period GAP allocation scheme shown in FIG. 2, the following technical defects exist:

(1) If the relevant mode is in the suspended measurement state, the entire block of GAP resources allocated to this mode will be wasted.

(2) When synchronization has been acquired, only a small amount of data needs to be received, and the measurement is periodically updated, the entire GAP is only allocated to a certain mode of use, which will result in a large waste of resources and fail to fully utilize the measurement GAP resources. .

Since a multi-mode single-standby or multi-mode multi-standby mobile terminal is generally only configured with one set of radio frequency transceivers in order to reduce product costs. In order to maintain normal service performance, generally only the measurement GAP is configured for intra-system, inter-system or inter-waiting neighbor cell measurements. However, due to the wide variety of measurements, GAP resources will be in short supply, and there are generally problems such as untimely measurement updates and poor terminal mobility.

SUMMARY OF THE INVENTION

The purpose of the embodiments of the present invention is to provide a measurement gap resource control method and a multi-mode terminal, so that the utilization rate of measurement GAP resources is greatly improved, the timeliness of measurement update of the terminal is improved, and the mobile performance of the terminal is optimized.

To solve the above technical problems, embodiments of the present invention provide a method for controlling measurement gap resources, including the following steps:

Obtain the measurement gap required by the measurement control module of each mode in the multimode terminal;

According to the requirements of the measurement control module of each mode for the measurement gap, the measurement gap is allocated;

Among them, the whole measurement gap is preferentially allocated to the measurement control module that needs the whole measurement gap, and the measurement control module that receives the whole measurement gap cuts the whole measurement gap as needed, and then allocates the clipped measurement gap to the fragment measurement gap. At least one measurement control module that does not require an integral measurement gap.

Embodiments of the present invention also provide a multi-mode terminal, including measurement control modules in each mode, and further including:

A requirement collection unit, used to collect measurement gaps required by the measurement control modules of each mode in the multimode terminal;

a resource allocation unit, configured to allocate measurement gaps according to the requirements of the measurement control modules of each mode for measurement gaps;

The resource allocation unit preferentially allocates the entire measurement gap to the measurement control module that needs the entire measurement gap, and the measurement control module that receives the entire measurement gap trims the entire measurement gap as needed, and then trims the fragmented measurement gap obtained after trimming. Redistributed to at least one measurement control module that does not require an entire measurement gap.

Compared with the prior art, the embodiment of the present invention allocates the measurement GAP according to the measurement GAP required by the measurement control modules of each mode, and only allocates the measurement GAP to each measurement control module that needs to measure the GAP, and there is no measurement GAP. The problem of waste, and the measurement control module that receives the whole piece of measurement GAP cuts the whole piece of measurement GAP as needed, and redistributes the fragment measurement GAP obtained after the clipping, so that the fragments of the measurement GAP are fully utilized and the scarce GAP is realized. Maximize use of resources. The waste of measurement GAP resources caused by discarding measurement GAP fragments is further reduced, and the utilization rate of measurement GAP resources is improved.

In addition, in acquiring the measurement gaps required by the control modules of each mode in the multi-mode terminal, it specifically includes: the measurement control modules of each mode autonomously report the requirements for the measurement gaps; wherein, the reported requirements include: receiving a whole block of measurement gaps, Either receive the fragment measurement gap, or do not receive the entire block measurement gap and do not receive the fragment measurement gap; if the reported requirement includes receiving the fragment measurement gap, the reported requirement also includes: allowing the measurement of the fragment measurement gap to be sent to the measurement control module control module. Through the active reporting of each mode, the requirements of each mode for measuring GAP can be accurately obtained, thereby ensuring that the accuracy of measuring GAP allocation is improved, and the maximum utilization of GAP resources can be achieved.

In addition, the measurement control module does not meet the measurement start condition, or the reporting requirement during the suspension measurement period is not to receive the whole block measurement gap and not to receive the fragment measurement gap; the measurement control module determines the received length according to the expected event during the measurement period The reporting requirement is to receive the whole block measurement gap or receive the fragment measurement gap. Different expected event reception lengths determine different reporting requirements, so as to realize the timeliness of each mode measurement update and the mobile performance of the terminal.

In addition, the measurement control module that receives the entire measurement gap completes the trimming before the pre-agreed measurement gap advance, and redistributes the fragment measurement gap obtained after trimming, and trims it in advance to ensure that the allocation of fragment GAP still has sufficient time advance.

In addition, before reassigning the clipped fragment measurement gap to at least one measurement control module that does not require the entire measurement gap, determine whether the fragment measurement gap after deducting the event guard interval satisfies the to-be-allocated non-integrated measurement gap The minimum size requirement of event reception of the measurement control module of the For measurement control modules that do not require an integral measurement gap. Corresponding operations are performed according to the minimum size of event reception, and the fragment measurement GAP that meets the conditions is re-allocated, thereby realizing the effectiveness of fragment measurement GAP allocation.

In addition, after reassigning the fragment measurement gap obtained after trimming to at least one measurement control module that does not require an entire measurement gap, the method further includes: when the measurement control module that receives the fragment measurement gap cannot use the received measurement gap for a preset period of time When the fragment measurement gap arrives for measurement, the notification information of the fragment measurement gap obtained after trimming by the previous measurement control module is no longer fed back; wherein, the previous measurement control module is the measurement control module that sends the fragment measurement gap, and the preset duration is greater than preset threshold. Thus, invalid message wake-up and measurement gap resource resolution are avoided.

Description of drawings

Fig. 1 is according to the flow control diagram that realizes measurement scheduling according to the mode in the prior art;

FIG. 2 is a schematic diagram of a measurement GAP resource allocation manner of a multimode terminal according to the prior art;

3 is a flowchart of a control method for measuring GAP resources according to the first embodiment of the present invention;

4 is a schematic diagram of a GAP requirement data structure according to the first embodiment of the present invention;

FIG. 5 is a schematic diagram of interaction between multiple measurement control modules according to the first embodiment of the present invention;

6 is a schematic diagram of resource usage measured by TD-SCDMA according to the first embodiment of the present invention;

7 is a schematic diagram of resource usage according to LET measurement in the first embodiment of the present invention;

FIG. 8 is a schematic structural diagram of a multi-mode terminal according to a third embodiment of the present invention.

Detailed ways

In order to make the objectives, technical solutions and advantages of the present invention clearer, each embodiment of the present invention will be described in detail below with reference to the accompanying drawings. However, those of ordinary skill in the art can appreciate that, in the various embodiments of the present invention, many technical details are set forth in order for the reader to better understand the present application. However, even without these technical details and various changes and modifications based on the following embodiments, the technical solutions claimed in the present application can be realized.

The first embodiment of the present invention relates to a method for controlling measurement gap resources. The specific process is shown in Figure 3.

Step 101: Obtain the measurement GAP required by each measurement control module.

Specifically, the measurement control module of each mode autonomously reports the requirements for measuring GAP, wherein the reporting requirements may include: receiving the whole block measurement GAP, or receiving the fragment measurement GAP, or not receiving the whole block measurement GAP and not receiving the fragment measurement Gap. When the measurement control module does not meet the measurement start condition, or during the measurement suspension period, the reporting requirement is not to receive the whole block measurement GAP and not to receive the fragment measurement GAP.

The measurement control module determines, according to the expected event reception length in the measurement period, that the reporting requirement is to receive the whole block measurement GAP or receive the fragment measurement GAP. When the measurement control module does not meet the measurement start condition, or during the measurement suspension period (it may be that the measurement control module has completed one round of measurement, but the next round of measurement has not been started), at this time, the reporting requirement is not to receive the entire measurement gap and No fragments are received to measure GAP.

It is worth mentioning that, if the reporting requirement includes receiving the fragment measurement GAP, the reporting requirement further includes: a measurement control module that is allowed to send the fragment measurement GAP to the measurement control module. Only after obtaining which measurement control modules can receive the fragment measurement GAP, an effective fragment GAP allocation scheme can be implemented.

That is to say, in this step, the measurement control module (or other control module) of the main mode receives and organizes the GAP requirements of each mode (including the main mode itself): whether there is currently a willingness to receive a whole piece of GAP, and which GAP is willing to receive. Fragment GAP for some modes. Specifically, the measurement control module reports when the measurement start condition is not met, or during the measurement suspension period (a round of measurement has been completed, but the next round of measurement has not been started): it does not receive the entire GAP, and does not receive any fragmented GAP of the RAT. . Output after starting a new round of measurement: Receive the entire GAP. And according to whether the detection process or the measurement process is currently being executed, that is, according to the expected event reception length, it is determined whether to receive the fragment GAP. If the expected receive event is short, there is a willingness to receive fragmented GAPs.

Since in different modes, the size of GAP resources required by each measurement demand module is different, therefore, GAP resources can be reported according to the GAP resource requirements of the measurement control module in different scenarios, wherein the GAP resources of different modes in different scenarios Requirements, uses, etc., can be viewed in the following table.

Table 1

Table 1 lists the GAP resource requirements for different modes of neighbor detection measurements. For example, in the measurement scenario of TD-SCDMA mode, the received data length value is relatively large. If the measurement control module of this mode reports that a whole block of GAP resources is required, the whole block of measurement GAP resources can be allocated to this mode.

For example, the data structure of the GAP requirement shown in FIG. 4 is taken as an example for description. The measurement control module that needs to receive the whole piece of measurement GAP is the first priority measurement control module, and the measurement control module that is willing to receive the fragmented GAP is the second priority measurement control module.

When the first priority measurement control module is an LTE measurement control module, the second priority measurement control module is a TD-SCDMA, WCDMA and GSM measurement control module. That is, if the TD-SCDMA, WCDMA or GSM measurement control module is willing to receive the fragmented GAP, it can receive the measurement GAP used by the LTE measurement control module. Similarly, when the first priority measurement control module is the TD-SCDMA measurement control module, the second priority measurement control module is the LTE, WCDMA and GSM measurement control modules. That is, if the LTE, WCDMA or GSM measurement control module is willing to receive the fragmented GAP, it can receive the measurement GAP used by the TD-SCDMA measurement control module.

Step 102: Allocate the whole block to measure GAP.

Specifically, the measurement GAP is allocated according to the requirements of the measurement control modules in each mode for the measurement GAP. For the requirements reported by different measurement control modules, the main module (such as the measurement control module in the main mode or other control modules) plans a reasonable allocation strategy, so that the measurement GAP resources are reasonably allocated and the waste of the GAP resources is reduced.

Among them, preferably, the whole block of GAP measurement is allocated to the measurement control module that needs to measure the whole block of GAP, and further operation processing is performed after the measurement control module that needs the whole block of measurement GAP uses the whole block of measurement GAP.

For example, the measurement control module in the main mode sorts out the GAP requirements reported by each mode: a set of measurement control modules that receive the entire GAP, and the measurement control module in the main mode collects the entire GAP in different time periods according to certain rules (The reference factor may be: the number of modes with measurement requirements, mode priority, number of frequency points, expected GAP requirements of each mode, etc.) Allocate to the measurement control module set that receives the entire GAP. And when outputting the whole block of GAP, select one (or more) measurement control modules that are willing to receive the fragment GAP of this mode.

Step 103: The measurement control module that receives the whole-block measurement GAP tailors the whole-block measurement GAP as needed.

Specifically, when the measurement control module that receives the whole block of measurement GAP tailors the whole measurement GAP as needed, it not only needs to determine the range of GAP resources used by the measurement control module; The event guard interval is determined, and the fragment GAP after deducting the event guard interval is passed to the second priority measurement control module. If the size of the fragmented GAPs does not meet the minimum size requirement for receiving events of the second priority measurement control module, these GAP fragments may be directly discarded.

That is to say, the fragment measurement GAP after deducting the event guard interval can be accepted only if it meets the minimum size requirement for event reception of the measurement control module to be allocated that does not require the whole block measurement GAP.

Step 104: Allocate fragments to measure GAP.

Specifically, the fragment measurement GAP obtained after trimming is reassigned to at least one measurement control module that does not require the entire block measurement GAP. That is, after tailoring the entire measurement GAP as needed, the first priority measurement control module can redistribute its remaining fragment measurement GAP to the second priority measurement control module that is willing to receive the fragment GAP.

Furthermore, in this embodiment, before reassigning the clipped fragment measurement gap to at least one measurement control module that does not require the entire measurement gap, it is determined whether the fragment measurement gap after deducting the event guard interval satisfies the to-be-allocated fragment measurement gap. The minimum size requirement for event reception of the measurement control module that does not require the entire measurement gap; if the minimum size requirement for event reception is not met, the fragment measurement gap after deducting the event guard interval is discarded; if the minimum size requirement for event reception is met, it will be trimmed The obtained fragment measurement gap is then allocated to the measurement control module that does not require the entire block measurement gap.

It is worth mentioning that after reassigning the clipped fragment measurement GAP to at least one measurement control module that does not require the whole block measurement GAP, the measurement control module that receives the fragment measurement GAP cannot be used for a preset period of time. When the received fragment measurement GAP is measured, the notification information that the fragment measurement GAP obtained after trimming by the previous measurement control module is no longer received is fed back.

Wherein, the former measurement control module is a measurement control module for sending the fragment measurement GAP, and the preset duration is greater than the preset threshold. Preset thresholds can be set by the system.

That is to say, after the second-priority measurement control module receives the fragmented GAP, it will parse the GAP to determine whether the GAP is useful. If the fragmented GAP output by the previous mode is unavailable for a long time, the main mode is fed back: the fragmented GAP of the previous RAT is no longer received, thereby avoiding invalid message wake-up and GAP parsing.

It can be seen that, in this embodiment, the main mode measurement control module obtains, according to the GAP requirements reported by each mode, at the same time: a set of measurement control modules that are willing to receive the residual GAP of a specific mode, and redistributes the fragmented GAP, that is, the GAP resources are divided into: whole block GAP that has not been used, and fragment GAP that has been partially used. The same GAP resource is divided and used according to the priority order of the measurement control module indicated by the measurement control module in the main mode in the GAP allocation command. The unit performs allocation of GAP resources. First allocate the whole block measurement control module for the first priority measurement control module to tailor the GAP as needed, and then allocate the fragmented GAP resources. As shown in Figure 5, the main mode optimizes the GAP allocation strategy according to the GAP willingness fed back by each mode. .

The effects of the present embodiment will be specifically described below by using specific examples.

Case number one:

A user equipment (User Equipment, "UE" for short) performs a packet service (PacketService, "PS" for short) service in the LTE mode, and is required to update the TD-SCDMA neighbor cell measurement. Specifically, as shown in Figure 6, the measurement process will receive 192 chips of data near the training sequence and 128 chips of data on the downlink pilot time slot on the TS0 time slot under the TD-SCDMA frame timing.

Among them, in the continuous 5.6ms measurement gap resource output by the LTE main mode (the event guard interval at both ends has been deducted), the TD-SCDMA measurement only occupies 0.5125ms. Considering the event guard interval, the cumulative occupation is about 0.9ms. If a whole block of measurement GAP is allocated for TD-SCDMA according to the prior art, the utilization rate of measurement gap resources is only 16%. In this embodiment, the TD-SCDMA measurement control module can report requirements to the LTE measurement control module : Willing to receive fragmented GAP, and use the received fragmented GAP to measure, so as to maximize the utilization of scarce GAP resources.

Case 2:

The UE performs the PS service in the LTE mode and requires to update the LTE neighbor cell measurement, as shown in Figure 7. The measurement process may receive data of "1ms+2 Orthogonal Frequency Division Multiplexing (OFDM") symbols on subframe 0 or subframe 5 based on the target LTE frame timing.

Among them, in the continuous 5.6ms measurement gap resource output by the LTE main mode, the LTE measurement only occupies 1.14ms; considering the event guard interval, the cumulative occupation is about 1.5ms. If a whole block of measurement GAP is allocated for LTE according to the prior art, the utilization rate of measurement gap resources is only 27%. In this embodiment, fragmented GAP can be allocated to the LTE measurement control module, and the LTE measurement control module uses Fragment GAP is measured to maximize utilization of scarce GAP resources.

Therefore, in this embodiment, the measurement gaps are allocated according to the measurement gaps required by the measurement control modules of each mode, and only the measurement gaps are allocated to each measurement control module that needs the measurement gaps, there is no measurement gap waste problem, and , after the measurement control module that receives the entire measurement gap trims the entire measurement gap as needed, redistributes the fragmented measurement gap obtained after the trimming, so that the fragments in the measurement gap are fully utilized, and further reduces the measurement gap caused by discarding the measurement gap. The waste of measurement gap resources caused by fragmentation improves the utilization rate of measurement gap resources.

The second embodiment of the present invention relates to a method for controlling measurement gap resources. The second embodiment is an optimization of the first embodiment, and the main optimization lies in that: in the second embodiment of the present invention, the measurement control module that receives the entire block of measurement gaps, before the pre-agreed measurement gap advance, completes all the clipping.

For example, the first-priority measurement control module should complete GAP trimming before a predetermined GAP advance amount (for example, 10ms).

In this implementation manner, by predetermining the advance amount, it can be effectively ensured that the allocation of the fragment GAP still has a sufficient time advance amount (for example, 10 ms).

The step division of the above various methods is only for the purpose of describing clearly. During implementation, it can be combined into one step or some steps can be split and decomposed into multiple steps, as long as they contain the same logical relationship, they are all within the protection scope of this patent. ;Adding insignificant modifications to the algorithm or process or introducing insignificant designs will not affect the core design of the algorithm and process, as long as the core design of the algorithm and process is included within the scope of protection of this patent.

The third embodiment of the present invention relates to a multi-mode terminal, which includes measurement control modules in each mode, and further includes: a demand collection unit 22 and a resource allocation unit 23, as shown in FIG. 8 .

The requirement collection unit 22 is configured to collect the measurement GAP required by the measurement control module of each mode in the multimode terminal.

The resource allocation unit 23 is configured to allocate the measurement GAP according to the requirements of the measurement control module of each mode for the measurement GAP.

Among them, the resource allocation unit 23 preferentially allocates the whole piece of measurement GAP to the measurement control module that needs to measure the whole piece of GAP, and the measurement control module that receives the whole piece of measurement GAP cuts the whole piece of measurement GAP as needed, and then measures the fragments obtained after cutting. The GAP is redistributed to at least one measurement control module that does not need to measure the GAP in its entirety.

Specifically, the requirement collection unit 22 collects the measurement GAP required by each measurement control module by receiving the requirement reported by the measurement control module of each mode;

Among them, the reporting requirements include: receiving the whole block measurement GAP, or receiving the fragment measurement GAP, or not receiving the whole block measurement GAP and not receiving the fragment measurement GAP;

When the requirement reported by the measurement control module includes receiving the fragment measurement GAP, the requirement for reporting also includes:

A measurement control module that allows sending fragment measurement GAPs to this measurement control module.

When the measurement control module does not meet the measurement start condition, or during the measurement suspension period, the reporting requirement is not to receive the whole block measurement GAP and not to receive the fragment measurement GAP.

The measurement control module determines, according to the expected event reception length in the measurement period, that the reporting requirement is to receive the whole block measurement GAP or receive the fragment measurement GAP.

In this embodiment, the demand collection unit may be an independent control module, or may be implemented by a measurement control module in the main mode; the resource allocation unit may be an independent control module, or a combination of measurement control modules to realize the resource Allocate the function of the unit. For example, the measurement control module includes:

The tailoring sub-module is used to determine the resource range of the measurement GAP to be used by the measurement control module when the entire measurement GAP is received;

The fragment measurement GAP acquisition sub-module is used to deduct the event guard interval with the to-be-allocated measurement control module that does not require the entire measurement GAP after removing the resource range of the measurement GAP to be used from the whole measurement GAP;

The redistribution sub-module is used to send the fragment measurement GAP after deducting the event guard interval to the measurement control module to be allocated that does not require the whole block measurement GAP.

After the measurement control module in the main mode completes the collection of GAP requirements, it allocates the entire GAP block to the first priority measurement control module (ie, the measurement control module that requires the entire GAP block). The first priority measurement control module realizes the redistribution of GAP resources through a tailoring submodule, a fragmentation measurement GAP acquisition submodule, and a redistribution submodule.

It should be noted that the measurement control module may also include:

The feedback sub-module is used for feeding back the notification information of not receiving the fragment measurement GAP trimmed by the previous measurement control module when the received fragment measurement gap cannot be used for measurement within a preset time period. Wherein, the former measurement control module is a measurement control module for sending the fragment measurement GAP, and the preset duration is greater than the preset threshold.

When the measurement control module is the second-level measurement control module (that is, willing to receive the fragment GAP), the feedback sub-module can implement information feedback on whether the fragment GAP is available or not.

It is not difficult to find that this embodiment is a system example corresponding to the first embodiment, and this embodiment can be implemented in cooperation with the first embodiment. The relevant technical details mentioned in the first embodiment are still valid in this embodiment, and are not repeated here in order to reduce repetition. Correspondingly, the related technical details mentioned in this embodiment can also be applied to the first embodiment.

It is worth mentioning that each module involved in this embodiment is a logical module. In practical applications, a logical unit may be a physical unit, a part of a physical unit, or multiple physical units. A composite implementation of the unit. In addition, in order to highlight the innovative part of the present invention, this embodiment does not introduce units that are not closely related to solving the technical problem proposed by the present invention, but this does not mean that there are no other units in this embodiment.

Those skilled in the art can understand that all or part of the steps in the method of the above embodiments can be completed by instructing the relevant hardware through a program. The program is stored in a storage medium and includes several instructions to make a device (which may be a single-chip microcomputer) , chip, etc.) or a processor (processor) to execute all or part of the steps of the methods described in the various embodiments of the present application. The aforementioned storage medium includes: U disk, removable hard disk, Read-Only Memory (ROM, Read-Only Memory), Random Access Memory (RAM, Random Access Memory), magnetic disk or optical disk and other media that can store program codes.

Those skilled in the art can understand that the above-mentioned embodiments are specific examples for realizing the present invention, and in practical applications, various changes in form and details can be made without departing from the spirit and the spirit of the present invention. scope.

Claims (11)

1. A method for controlling measurement gap resources, comprising: Obtain the measurement gap required by the measurement control module of each mode in the multimode terminal; Allocate the measurement gaps according to the requirements of the measurement control modules of the various modes for the measurement gaps; Among them, the entire measurement gap is preferentially allocated to the measurement control module that needs the entire measurement gap, and the trimming is completed before the pre-agreed measurement gap advance, and the measurement control module that receives the entire measurement gap trims the entire measurement gap as needed. Then, the fragment measurement gap obtained after trimming is redistributed to at least one measurement control module that does not require the entire measurement gap. 2 . The method for controlling measurement gap resources according to claim 1 , wherein the acquiring the measurement gap required by the control module of each mode in the multi-mode terminal specifically comprises: 2 . The measurement control module of each mode autonomously reports the requirements for the measurement gap; Wherein, the reporting requirements include: receiving the whole block measurement gap, or receiving the fragment measurement gap, or not receiving the whole block measurement gap and not receiving the fragment measurement gap; If the reported requirement includes receiving fragment measurement gaps, the reported requirement further includes: A measurement control module that allows sending fragment measurement gaps to this measurement control module. 3. The method for controlling measurement gap resources according to claim 2, wherein: When the measurement control module does not meet the measurement start condition, or the reporting requirement during the suspension measurement period is not to receive the whole block measurement gap and not to receive the fragment measurement gap; The measurement control module determines, according to the expected event reception length within the measurement period, that the reporting requirement is to receive the whole block measurement gap or the fragment measurement gap. 4. The method for controlling measurement gap resources according to claim 1, wherein the measurement control module that receives the entire block of measurement gaps tailors the entire block of measurement gaps as needed, specifically comprising: The measurement control module determines the resource range of the measurement gap to be used by the measurement control module; After the entire block of measurement gaps are removed from the resource range of the to-be-used measurement gaps, the event guard interval with the to-be-allocated measurement control modules that do not require the entire block of measurement gaps is deducted; The described redistribution of the fragment measurement gap obtained after trimming to at least one measurement control module that does not require the entire measurement gap, specifically includes: The fragment measurement gap after deducting the event guard interval is sent to the to-be-allocated measurement control module that does not require an entire block of measurement gaps. 5. The method for controlling measurement gap resources according to claim 4, further comprising: Before reassigning the clipped fragment measurement gap to at least one measurement control module that does not require an entire measurement gap, determine whether the fragment measurement gap after deducting the event guard interval satisfies the to-be-allocated non-integrated measurement gap The event receiving minimum size requirements for the measurement control module of the measurement gap; If the minimum size requirement for event reception is not met, the fragment measurement gap after deducting the event guard interval is discarded; if the minimum size requirement for event reception is met, the fragment measurement gap obtained after trimming is reassigned to The measurement control module does not require an entire measurement gap. 6. The method for controlling measurement gap resources according to any one of claims 1 to 5, wherein the fragmented measurement gaps obtained after trimming are reassigned to at least one measurement control module that does not require a whole block of measurement gaps After that, it also includes: When the measurement control module that receives the fragment measurement gap cannot use the received fragment measurement gap for measurement within the preset time period, it feeds back the notification information that it no longer receives the fragment measurement gap trimmed by the previous measurement control module; The previous measurement control module is a measurement control module that sends the fragment measurement gap, and the preset duration is greater than a preset threshold. 7. A multimode terminal, comprising the measurement control module of each mode, is characterized in that, also comprises: The demand collection unit is used to collect the measurement gap required by the measurement control module of each mode in the die terminal; a resource allocation unit, configured to allocate measurement gaps according to the requirements of the measurement control modules of the various modes for measurement gaps; The resource allocation unit preferentially allocates the entire measurement gap to the measurement control module that needs the entire measurement gap, completes the trimming before the pre-agreed measurement gap advance, and receives the measurement control of the entire measurement gap After the module trims the entire measurement gap as required, it redistributes the fragmented measurement gap obtained after trimming to at least one measurement control module that does not require the entire measurement gap. 8. The multimode terminal according to claim 7, wherein, The requirement collection unit collects the measurement gap required by each measurement control module by receiving the requirement reported by the measurement control module of each mode; Wherein, the reporting requirements include: receiving the whole block measurement gap, or receiving the fragment measurement gap, or not receiving the whole block measurement gap and not receiving the fragment measurement gap; When the requirement reported by the measurement control module includes receiving fragment measurement gaps, the requirement reported further includes: A measurement control module that allows sending fragment measurement gaps to this measurement control module. 9 . The multi-mode terminal according to claim 8 , wherein the measurement control module does not receive the entire measurement gap and does not receive the measurement gap when the measurement start condition is not met, or the reporting requirement during the measurement suspension period is 9 . debris measurement gap; The measurement control module determines, according to the expected event reception length within the measurement period, that the reporting requirement is to receive the whole block measurement gap or the fragment measurement gap. 10. The multimode terminal according to claim 7, wherein the measurement control module comprises: The tailoring sub-module is used to determine the resource range of the measurement gap to be used by the measurement control module when the entire measurement gap is received; The fragment measurement gap acquisition sub-module is used to deduct the event guard interval from the measurement control module to be allocated that does not require the entire measurement gap after removing the resource range of the measurement gap to be used from the whole measurement gap ; The redistribution sub-module is configured to send the fragment measurement gap after deducting the event guard interval to the to-be-allocated measurement control module that does not require a whole block of measurement gaps. 11. The multimode terminal according to any one of claims 7 to 10, wherein the measurement control module further comprises: The feedback sub-module is used to feed back the notification information that the fragment measurement gap obtained after trimming by the previous measurement control module is no longer received when the received fragment measurement gap cannot be used for measurement within the preset time period; The previous measurement control module is a measurement control module that sends the fragment measurement gap, and the preset duration is greater than a preset threshold.

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