CN117336752A - Control method and device - Google Patents

Abstract

The application discloses a control method and a control device, wherein the method comprises the following steps: monitoring the data flow demand of the electronic equipment, wherein the data flow at least enables the electronic equipment to access or load target data content of a network side; controlling a target communication module of the electronic equipment to adjust working parameters based on the change information of the data flow demand; the target communication module has different power consumption and/or communication parameters before and after the working parameters are adjusted, and the communication parameters can influence the data flow generated by the electronic equipment.

Description

Control method and device

Technical Field

The present disclosure relates to the field of communications technologies, and in particular, to a control method and apparatus.

Background

Currently, a WiFi terminal is capable of supporting multiple wireless access point AP connections. For example, a handset may connect to multiple routers that provide WiFi connectivity of different bandwidths.

However, the user is required to manually select a WiFi connection with a desired bandwidth on the WiFi terminal, which results in high operation complexity.

Disclosure of Invention

In view of this, the present application provides a control method and apparatus, as follows:

a control method, comprising:

Monitoring the data flow demand of the electronic equipment, wherein the data flow at least enables the electronic equipment to access or load target data content of a network side;

controlling a target communication module of the electronic equipment to adjust working parameters based on the change information of the data flow demand;

the target communication module has different power consumption and/or communication parameters before and after the working parameters are adjusted, and the communication parameters can influence the data flow generated by the electronic equipment.

The method, preferably, of monitoring the data traffic demand of the electronic device, includes at least one of the following:

acquiring operation information of a target application of the electronic equipment, and monitoring the data flow demand based on the operation information, wherein the target application is an application which needs to access a network side in the electronic equipment to acquire target data content;

obtaining usage pattern information of the electronic device, and monitoring the data traffic demand based on the usage pattern information;

acquiring using environment information of the electronic equipment, and monitoring the data flow requirement based on the using environment information;

obtaining the type and/or the acquisition mode of the target data content, and monitoring the data flow requirement based on the type and/or the acquisition mode;

And monitoring a request instruction obtained by the electronic equipment, and monitoring the data flow demand based on the request instruction, wherein the request instruction is used for adjusting the data flow.

In the above method, preferably, the controlling the target communication module of the electronic device to adjust the working parameter based on the change information of the data traffic demand includes at least one of the following:

if the change information characterizes that the data flow requirement of the electronic equipment is increased, the working frequency band of the target communication module is controlled to be increased and/or increased;

and if the change information characterizes that the data flow requirement of the electronic equipment is reduced, controlling the working frequency band of the target communication module to be reduced and/or reduced.

In the above method, preferably, the controlling the target communication module of the electronic device to adjust the working parameter based on the change information of the data traffic demand includes at least one of the following:

if the target index parameter of the electronic equipment exceeds a first threshold value and lasts for a first duration, controlling the target communication module to adjust from working in a first frequency band to simultaneously working in a first frequency band and a second frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, and the second frequency band is larger than the first frequency band;

If the target index parameter of the electronic equipment exceeds a second threshold value and lasts for a second duration, controlling the target communication module to adjust from simultaneously working in a first frequency band and a second frequency band to simultaneously working in the first frequency band, the second frequency band and a third frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, the third frequency band is larger than the second frequency band, and the second frequency band is larger than the first frequency band;

if the target index parameter of the electronic equipment is smaller than a third threshold value and lasts for a third duration, the target communication module is controlled to be adjusted from simultaneously working in a first frequency band, a second frequency band and a third frequency band to simultaneously working in the first frequency band and the second frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, the third frequency band is larger than the second frequency band, and the second frequency band is larger than the first frequency band;

and if the target index parameter of the electronic equipment is smaller than a fourth threshold value and lasts for a fourth duration, controlling the target communication module to adjust from simultaneously working in a first frequency band and a second frequency band to working in the first frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, and the second frequency band is larger than the first frequency band.

The above method, preferably, further comprises:

and monitoring the signal quality of a data flow signal in a space where the electronic equipment is located, and controlling the target communication module to adjust the working parameters of the target communication module based on the signal quality and the change information of the data flow demand.

In the above method, preferably, the controlling the target communication module to adjust the working parameter based on the signal quality and the change information of the data traffic demand includes at least one of the following:

under the condition that the data traffic demand is unchanged, if the target communication module works in a second frequency band and the signal quality of a data traffic signal of the second frequency band is lower than a fifth threshold, controlling the target communication module to adjust from working in the second frequency band to simultaneously working in the second frequency band and a first frequency band, wherein the second frequency band is larger than the first frequency band;

under the condition that the data flow demand is unchanged, if the target communication module works in a first frequency band and a second frequency band at the same time and the signal quality of a data flow signal of the second frequency band is higher than a fifth threshold value, controlling the target communication module to adjust from the first frequency band and the second frequency band to the second frequency band, wherein the second frequency band is larger than the first frequency band;

If the data traffic demand increases, controlling the target communication module to adjust from operating in the second frequency band to simultaneously operating in the first frequency band and the second frequency band, or simultaneously operating in the second frequency band and the third frequency band, or simultaneously operating in the first frequency band, the second frequency band and the third frequency band based on the signal quality of the data traffic signal in the first frequency band and the third frequency band under the condition that the target communication module operates in the second frequency band;

and under the condition that the target communication module works in a third frequency band, if the data flow demand is reduced, controlling the target communication module to adjust from working in the third frequency band to working in the second frequency band or the first frequency band based on the signal quality of the data flow signal in the first frequency band and the second frequency band.

In the above method, preferably, the target communication module is controlled to adjust its working parameter based on the signal quality and the change information of the data traffic demand, and at least one of the following is further included:

controlling a second communication module of the electronic equipment to adjust the working frequency band and/or networking mode of the second communication module under the condition that the signal quality of a first type of data flow signal in the space where the electronic equipment is located does not meet a corresponding signal quality threshold value and/or the first communication module of the electronic equipment cannot meet the data flow requirement;

Controlling a second communication module of the electronic equipment to adjust the working frequency band and/or networking mode of the second communication module under the condition that the signal quality of a first type of data flow signal in the space where the electronic equipment is located does not meet a corresponding signal quality threshold value and/or a first communication module of the electronic equipment cannot meet the data flow requirement so as to provide the required data flow for the electronic equipment in cooperation with the first communication module;

wherein the first communication module is of a different type than the second communication module.

In the above method, preferably, under the condition that the space where the electronic device is located has the first data traffic signal provided by the first network side and the second data traffic signal provided by the second network side, the target communication module is controlled to establish corresponding communication connection with the first network side and/or the second network side under different communication parameters based on the change information of the data traffic demand and the signal quality of the data traffic signal.

The above method, preferably, further comprising at least one of:

acquiring the service condition of data flow signals of each frequency band provided by the network terminal, and controlling the target communication module to adjust the working parameters based on the service condition and the change information of the data flow demand;

Acquiring the service condition of data flow signals of each frequency band provided by the network side, and controlling the target communication module to adjust the working parameters based on the service condition, the signal quality and the change information of the data flow requirements;

and monitoring motion data of the electronic equipment, and adjusting working parameters of the target communication module in real time based on the motion data.

A control apparatus comprising:

the demand monitoring unit is used for monitoring the data flow demand of the electronic equipment, and the data flow at least enables the electronic equipment to access or load the target data content of the network side;

the parameter control unit is used for controlling the target communication module of the electronic equipment to adjust the working parameters of the target communication module based on the change information of the data flow demand;

the target communication module has different power consumption and/or communication parameters before and after the working parameters are adjusted, and the communication parameters can influence the data flow generated by the electronic equipment.

According to the technical scheme, in the control method and the control device disclosed by the application, the data flow demand of the target data content of the network side accessed or loaded by the electronic equipment is monitored, the target communication module of the electronic equipment is controlled to adjust the working parameters based on the change information of the data flow demand, and the power consumption of the target communication module before and after the working parameters are adjusted and/or the communication parameters affecting the data flow generated by the electronic equipment are different. Therefore, in the application, the target communication module is controlled to be under the working parameters of different power consumption and/or different communication parameters according to the change information of the data flow requirement of the network side data content accessed or loaded by the electronic equipment, and the working parameter adjustment is not required to be manually carried out on the communication module, so that the operation complexity is reduced, and the use experience of a user on the electronic equipment is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a flowchart of a control method according to a first embodiment of the present application;

FIG. 2 is another flow chart of a control method according to the first embodiment of the present application;

fig. 3 is a schematic structural diagram of a control device according to a second embodiment of the present disclosure;

fig. 4 is a schematic structural diagram of an electronic device according to a third embodiment of the present application;

fig. 5 is an exemplary diagram of a WiFi band control procedure in a scenario of the present application applicable to a mobile phone;

fig. 6 is another exemplary diagram of a WiFi band control procedure in a scenario of the present application applicable to a mobile phone.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

Referring to fig. 1, a flowchart of a control method according to an embodiment of the present application is provided, and the method may be applied to an electronic device, such as a mobile phone, a tablet computer, a notebook, etc., having a communication module and capable of performing data communication. The technical scheme in the embodiment is mainly used for reducing the operation complexity of the control communication module so as to improve the use experience of a user on the electronic equipment.

Specifically, the method in this embodiment may include the following steps:

step 101: the data traffic demand of the electronic device is monitored.

The data flow at least enables the electronic equipment to access or load target data content of the network side.

Specifically, the data traffic demand of the electronic device may include the demands of an uplink network rate, a downlink network rate, a throughput rate, etc. for performing data access or loading between the electronic device and the network side.

Wherein the data traffic demand of the electronic device is related to at least one of:

running information of a target application of the electronic device, using mode information of the electronic device, using environment information of the electronic device, type and/or obtaining mode of target data content, request instructions obtained by the electronic device and the like.

The target application is an application in the electronic device, which needs to access or load the network side to obtain the target data content, and the running information of the target application may include: the number of the starting operation of the target application, the operation stage of the target application such as the stage of accessing the network or the stage of local starting, the loading degree of the target application to the target data content and the like.

The target data content may be video pictures, web pages, music files, documents, etc. types of content. The acquisition mode of the target data content can be an access mode and a loading mode, such as downloading the target data content to a local place, caching the target data content, pushing the target data content and the like.

The usage pattern information of the electronic device characterizes whether the electronic device is used as a hot spot device, whether the electronic device is used as a relay device to share data traffic with other devices, whether the electronic device is connected with a plurality of network ends, and the like.

The using environment information of the electronic equipment represents information such as using places, using scenes and the like of the electronic equipment, wherein the using place information represents whether hot spots, hot spot intensity, hot spot quantity and the like exist, and the using scene information represents that the electronic equipment is in scenes such as exclusive hot spots, shared hot spots, public hot spots or private hot spots and the like.

And the request instruction is used to request other devices to which the electronic device is connected to adjust the data traffic, such as to adjust the data traffic up or down.

Based on this, the data traffic demand of the electronic device is monitored in step 101 according to at least one of the above.

Step 102: and controlling the target communication module of the electronic equipment to adjust the working parameters based on the change information of the data flow demand.

The power consumption and/or communication parameters of the target communication module before and after the working parameter adjustment are different.

Specifically, the target communication module may be a bluetooth module, a WiFi module, a WAN module, and the like. For example, taking an electronic device as a mobile phone, a WiFi module in the mobile phone is adjusted to work parameters according to the change information of the data flow requirement of the video on the mobile phone download network, so that the power consumption of the WiFi module becomes high or low, and/or the communication parameters of the WiFi module are different.

The communication parameters of the target communication module may include parameters such as a working frequency band and/or a working power of the target communication module.

For example, taking a communication parameter as an operating frequency band, a WiFi module in the mobile phone is used to adjust the operating parameter according to the change information of the data flow requirement of the video on the mobile phone download network, so that the operating frequency band operated by the WiFi module is changed correspondingly.

It can be seen from the above technical solution that, in the control method provided in the first embodiment of the present application, the data traffic demand of the electronic device for accessing or loading the target data content of the network side is monitored, and then the target communication module of the electronic device is controlled to adjust the working parameters thereof based on the change information of the data traffic demand, and the power consumption of the target communication module before and after the adjustment of the working parameters thereof and/or the communication parameters affecting the data traffic generated by the electronic device are different. Therefore, in this embodiment, the target communication module is controlled to be under the working parameters of different power consumption and/or different communication parameters according to the change information of the data flow requirement of the network side data content accessed or loaded by the electronic device, and the working parameter adjustment is not required to be manually performed on the communication module, so that the operation complexity is reduced, and the use experience of the user on the electronic device is improved.

It should be noted that, in step 101, the data traffic demand of the electronic device may be monitored by at least one of the following implementations to obtain the change information of the data traffic demand, such as increasing or decreasing the demand:

in one implementation, in step 101, the operation information of the target application of the electronic device may be obtained first, and then the data traffic demand may be monitored based on the operation information.

The target application of the electronic equipment is an application which needs to access the network end in the electronic equipment to obtain target data content.

For example, the target application of the mobile phone may be an online game application, the network end is a game background server, and the online game application on the mobile phone needs to access the game background server to obtain the game role skin.

For another example, the target application of the mobile phone may be an online video playing application, the network end is a video background server, and the online video playing application on the mobile phone needs to download video frames from the video background server.

Specifically, the running information of the target application may include at least one of the following: the number of starting operations of the target application, the operation stage of the target application, the content loading degree of the target application and the like. The starting operation quantity of the target application is increased, the data flow requirement of the electronic equipment is increased, the starting operation quantity of the target application is reduced, and the data flow requirement of the electronic equipment is reduced; the data flow demand of the electronic equipment when the target application accesses the network stage is greater than the data flow demand of the electronic equipment when the target application is in the local starting stage; the content loading rate of the target application increases, the data traffic demand of the electronic device increases, the content loading rate of the target application decreases, the data traffic demand of the electronic device decreases, and so on.

In this way, in step 101, the change information of the data traffic demand of the electronic device may be monitored through the change situations of the starting operation number, the operation stage, the content loading degree and the like of the target application in the electronic device.

In one implementation, usage pattern information for the electronic device may be obtained first in step 101, and then data traffic demand may be monitored based on the usage pattern information.

Wherein the pattern information is used to characterize pattern information of the electronic device usage data traffic. The usage pattern information can characterize the size of the data traffic that the electronic device needs to use.

For example, the usage pattern information may characterize whether the electronic device shares data traffic as a hotspot device to the user device, and if the electronic device shares data traffic as a hotspot device to the user device, the data traffic requirement of the electronic device becomes greater. If the electronic device is no longer sharing data traffic as a hotspot device to the user device, the data traffic demand of the electronic device becomes smaller.

For another example, the usage pattern information may indicate whether the electronic device is used as a relay device to share data traffic with the user device, if the electronic device is used as a relay device to share data traffic with the user device, the data traffic requirement of the electronic device becomes larger, and if the electronic device is not used as a relay device to share data traffic with the user device, the data traffic requirement of the electronic device becomes smaller.

Thus, in step 101, the change information of the data traffic demand of the electronic device may be monitored by the usage pattern information of the electronic device.

In one implementation, usage environment information for the electronic device may be obtained in step 101, and then the data traffic demand of the electronic device is monitored based on the usage environment information.

The usage environment information of the electronic device represents information such as usage places, usage scenes and the like of the electronic device, the usage place information represents whether hot spots, hot spot intensity, hot spot number and the like exist, and the usage scene information represents scenes such as exclusive hot spots, shared hot spots, public hot spots or private hot spots and the like of the electronic device.

For example, if the space where the electronic device is located has a hot spot and the intensity of the hot spot becomes large, the data flow requirement of the electronic device becomes large, whereas if the space where the electronic device is located has a hot spot and the intensity of the hot spot becomes small, the data flow requirement of the electronic device becomes small.

For another example, if the space where the electronic device is located has a hotspot and the hotspot is switched from sharing with other devices to a single-sharing hotspot, the data traffic requirement of the electronic device becomes larger; if the space where the electronic device is located has a hot spot and switches from a single shared hot spot to a shared hot spot with other devices, the data traffic requirements of the electronic device become smaller.

For another example, if the electronic device switches from a public hotspot of a plurality of devices to a private hotspot of one device, the data traffic requirement of the electronic device becomes larger, whereas if the electronic device switches from a private hotspot of one device to a public hotspot of a plurality of devices, the data traffic requirement of the electronic device becomes smaller.

Thus, in step 101, the change information of the data traffic demand of the electronic device can be monitored by the usage environment information of the electronic device.

In one implementation, the type and/or manner of acquisition of the target data content may be obtained in step 101, and then the data traffic demand of the electronic device is monitored based on the type and/or manner of acquisition.

The type of the target data content may be a video type, an image type, a text type, an audio type, etc., and the acquisition mode of the target data content may be an access mode and a loading mode, for example, downloading the target data content to a local area, caching the target data content, pushing the target data content, etc.

For example, if the target data content changes from video type to text type, the data traffic demand of the electronic device becomes smaller, and if the target data content changes from image type to video type, the data traffic demand of the electronic device becomes larger.

For another example, if the target data content is switched from the mode of caching the target data content to the mode of downloading the target data content, the data flow requirement of the electronic device becomes smaller; if the target data content is switched from the manner of downloading the target data content to the manner of caching the target data content, the data traffic requirement of the electronic device becomes large.

Thus, in step 101, the change information of the data traffic demand of the electronic device may be monitored by the type and/or the acquisition mode of the target data content.

In one implementation, in step 101, a request instruction obtained by the electronic device may be monitored, and the data traffic demand is obtained based on the request instruction, where the request instruction is used to adjust the data traffic.

For example, in the case where the request instruction requests the electronic device to increase the data flow rate, the data flow rate requirement of the electronic device becomes large; in the case where the request instruction requests the electronic device to turn down the data traffic, the data traffic demand of the electronic device becomes smaller. Thus, in step 101, the change information of the data traffic demand of the electronic device may be monitored by the request instruction obtained by the electronic device.

In a specific implementation, in step 102, when the target communication module of the electronic device is controlled to adjust the working parameters based on the change information of the data traffic demand, at least one implementation manner may be included:

In one implementation, if the change information characterizes an increase in data traffic demand of the electronic device, the operating frequency band of the control target communication module is increased and/or increased.

For example, if the number of start-up operations of the target application in the electronic device increases, the data traffic requirement of the electronic device becomes larger, and at this time, the target communication module may be controlled to operate in a plurality of operating frequency bands and/or in a wider operating frequency band, for example, the WiFi module is switched from operating in only the 2.4G frequency band to simultaneously operating in both the 2.4G and 5G frequency bands, and/or is switched from operating in the 2.4G frequency band to operating in the 6G frequency band, so as to meet the increased data traffic requirement.

For another example, if the target application enters the access network phase from the local start phase, the data traffic requirement of the electronic device becomes larger, and at this time, the target communication module may be controlled to operate in multiple operating frequency bands and/or in a wider operating frequency band, such as the WiFi module is switched from operating in only the 5G frequency band to simultaneously operating in both the 5G and 6G operating frequency bands, and/or is switched from operating in the 5G frequency band to operating in the 6G frequency band, so as to meet the increased data traffic requirement.

For another example, if the target data content changes from an image type to a video type, the data traffic requirement of the electronic device becomes larger, at this time, the target communication module may be controlled to operate in a plurality of operating frequency bands and/or in a wider operating frequency band, such as the WiFi module is switched from operating in only the 2.4G frequency band to simultaneously operating in both the 2.4G and 5G operating frequency bands, and/or is switched from operating in the 2.4G frequency band to operating in the 5G frequency band, so as to meet the increased data traffic requirement.

In another implementation, if the change information characterizes a decrease in data traffic demand of the electronic device, the operating frequency band of the control target communication module is decreased and/or reduced.

For example, if the number of starting operations of the target application in the electronic device is reduced, the data traffic demand of the electronic device becomes smaller, and at this time, the target communication module may be controlled to reduce the number of operating frequency bands and/or operate in a narrower operating frequency band, such as the WiFi module switches from operating in the 5G frequency band to operating in the 2.4G frequency band, and/or switches from operating in both the 2.4G and 5G frequency bands to operating in the 2.4G frequency band, so as to meet the increased data traffic demand.

For another example, if the target application enters the local start-up phase from the access network phase, the data traffic demand of the electronic device becomes smaller, at this time, the target communication module may be controlled to reduce the number of operating frequency bands and/or operate in a narrower operating frequency band, such as the WiFi module switches from operating in the 6G frequency band to operating in the 5G frequency band, and/or switches from operating in both the 2.4G and 5G frequency bands to operating in the 2.4G frequency band, so as to meet the increased data traffic demand.

For another example, if the target data content changes from video type to text type, the data traffic demand of the electronic device becomes smaller, at this time, the target communication module may be controlled to reduce the number of operating frequency bands and/or operate in a narrower operating frequency band, such as switching the WiFi module from operating in the 6G frequency band to operating in the 5G operating frequency band, and/or switching from operating in both the 5G and 6G frequency bands to operating in the 5G frequency band, so as to meet the increased data traffic demand.

In a specific implementation, in step 102, when the target communication module of the electronic device is controlled to adjust the working parameters based on the change information of the data traffic demand, at least one implementation manner may be included:

in one implementation, if the target indicator parameter of the electronic device exceeds the first threshold and lasts for a first duration, the target communication module is controlled to be adjusted from operating in the first frequency band to operating in the first frequency band and the second frequency band at the same time.

The target index parameter can indicate a data traffic demand of the electronic device, such as an uplink network rate, a downlink network rate, or a throughput rate between the electronic device and the network end. And the second frequency band is larger than the first frequency band.

Specifically, in this embodiment, the change condition of the target index parameter of the electronic device is continuously monitored, if the target index parameter is raised and remains longer than the first time after the target index parameter is raised to exceed the first threshold, it indicates that the first frequency band currently operated by the target communication module cannot meet the data traffic demand of the electronic device, and at this time, the operating frequency band can be increased for the target communication module, for example, the target communication module is controlled to adjust from operating in the first frequency band to operating in the first frequency band and in the wider second frequency band at the same time.

For example, in this embodiment, the throughput rate of surfing the internet of the mobile phone is monitored, if the throughput rate is continuously increased to exceed the first threshold value and then is maintained to exceed the first time, at this time, the WiFi module of the mobile phone is controlled to be turned on under the condition that the 2.4G frequency band is kept on, so that the WiFi module is adjusted from only working in the 2.4G frequency band to simultaneously working in the 2.4G frequency band and the 5G frequency band, and therefore, the data flow requirement of surfing the internet of the mobile phone is met by increasing the number of wider working frequency bands of the WiFi module.

In one implementation, if the target indicator parameter of the electronic device exceeds the second threshold and lasts for a second duration, the target communication module is controlled to be adjusted from operating in the first frequency band and the second frequency band to operating in the first frequency band, the second frequency band and the third frequency band at the same time. Wherein the third frequency band is greater than the second frequency band.

Specifically, in this embodiment, the change condition of the target index parameter of the electronic device is continuously monitored, if the target index parameter is raised and remains exceeding the second time period after the target index parameter is raised to exceed the second threshold, this indicates that the first frequency band and the second frequency band currently operated by the target communication module cannot meet the data traffic demand of the electronic device, and at this time, the operating frequency band can be increased for the target communication module, for example, the target communication module is controlled to adjust from simultaneously operating in the first frequency band and the second frequency band to simultaneously operating in the first frequency band, the second frequency band and a wider third frequency band.

For example, in this embodiment, the throughput rate of surfing the internet of the mobile phone is monitored, if the throughput rate continuously rises to exceed the second threshold value and then is maintained to exceed the second duration, at this time, the WiFi module of the mobile phone is controlled to turn on the 6G frequency band under the condition that both the 2.4G frequency band and the 5G frequency band are kept on, so that the WiFi module is adjusted from simultaneously operating in the 2.4G frequency band and the 5G frequency band to simultaneously operating in the 2.4G frequency band, the 5G frequency band and the 6G frequency band, and therefore, the data flow requirement of surfing the internet of the mobile phone is met by increasing the number of wider operating frequency bands of the WiFi module.

In one implementation, if the target indicator parameter of the electronic device is less than the third threshold and lasts for a third duration, the target communication module is controlled to be adjusted from simultaneously operating in the first frequency band, the second frequency band and the third frequency band to simultaneously operating in the first frequency band and the second frequency band.

Wherein the third threshold may be the same as or different from the second threshold. In case the third threshold is different from the second threshold, the third threshold is smaller than the second threshold to avoid ping-pong effect.

Specifically, in this embodiment, the change condition of the target index parameter of the electronic device is continuously monitored, if the target index parameter is reduced and remains exceeding the third duration after being reduced to be lower than the third threshold, this indicates that the first frequency band, the second frequency band and the third frequency band of the current working of the target communication module completely meet the flow requirement of the electronic device and that the possible frequency band resources are excessive, at this time, the number of working frequency bands can be reduced for the target communication module, for example, the target communication module is controlled to be adjusted from work of a colleague in the first frequency band, the second frequency band and the third frequency band to work at the first frequency band and the second frequency band at the same time, that is, the widest working frequency band is closed first, thereby not only meeting the data flow requirement of the electronic device, but also reducing the power consumption of the electronic device.

For example, in this embodiment, the throughput rate of surfing the internet of the mobile phone is monitored, if the throughput rate is continuously reduced to be lower than a third threshold value and then is maintained to be longer than a third duration, at this time, the WiFi module of the mobile phone is controlled to close the 6G frequency band under the condition that both the 2.4G frequency band and the 5G frequency band are kept open, so that the WiFi module is adjusted from simultaneously working in the 2.4G frequency band, the 5G frequency band and the 6G frequency band to simultaneously working in the 2.4G frequency band and the 5G frequency band, and therefore, under the condition that the data flow requirement of surfing the internet of the mobile phone is met by reducing the number of working frequency bands of the WiFi module, the power consumption of the WiFi module is reduced.

In one implementation, if the target indicator parameter of the electronic device is less than the fourth threshold and lasts for a fourth duration, the target communication module is controlled to be adjusted from operating in the first frequency band and the second frequency band simultaneously to operating in the first frequency band.

Wherein the fourth threshold may be the same as or different from the first threshold. In the case that the fourth threshold is different from the first threshold, the fourth threshold is smaller than the first threshold to avoid the ping-pong effect.

Specifically, in this embodiment, the change condition of the target index parameter of the electronic device is continuously monitored, if the target index parameter is reduced and remains longer than the fourth time after being reduced to be lower than the fourth threshold, it indicates that the first frequency band and the second frequency band currently operated by the target communication module completely meet the data traffic demand of the electronic device and there may be an excessive frequency band resource condition, and at this time, the operating frequency band may be reduced for the target communication module, for example, the target communication module is controlled to operate only in the first frequency band from the adjustment value of the first frequency band and the second frequency band simultaneously.

For example, in this embodiment, the throughput rate of surfing the internet of the mobile phone is monitored, if the throughput rate is continuously reduced to be lower than a third threshold value and then is maintained to be longer than a third duration, at this time, the WiFi module of the mobile phone is controlled to close the 5G frequency band under the condition that the 2.4G frequency band is kept open, so that the WiFi module is adjusted from simultaneously working in the 2.4G frequency band and the 5G frequency band to only working in the 2.4G frequency band, and therefore, the power consumption of the WiFi module is reduced under the condition that the data flow requirement of surfing the internet of the mobile phone is met by reducing the number of working frequency bands of the WiFi module.

Further, the present embodiment may further include the following steps, as shown in fig. 2:

step 103: the signal quality of the data traffic signal in the space in which the electronic device is located is monitored.

Based on this, in step 102, the target communication module may be controlled to adjust its operating parameters based on the signal quality and the change information of the data traffic demand.

Wherein the signal quality may be expressed in terms of the signal strength of the data traffic signal.

Specifically, in step 102, when the target communication module is controlled to adjust its operating parameters based on the change information of the signal quality and the data traffic demand, at least one implementation manner may be included as follows:

in one implementation, if the target communication module is operating in the second frequency band and the signal quality of the data traffic signal in the second frequency band is lower than the fifth threshold value, the target communication module is controlled to be adjusted from operating in the second frequency band to simultaneously operating in the second frequency band and the first frequency band.

Specifically, in this embodiment, the change condition of the data traffic demand and the signal quality of the data traffic signal on the working frequency band where the target communication module is located are continuously monitored, if the data traffic demand is unchanged in the case that the target communication module is currently working in the second frequency band, but the signal quality of the data traffic signal on the second frequency band where the target communication module is currently working is reduced and is reduced to be lower than the fifth threshold, in order to meet the data traffic demand on the target communication module, the lower first frequency band can be opened, so that the target communication module is simultaneously working in the higher second frequency band and the lower first frequency band, and the situation that the signal quality on the second frequency band is reduced and cannot meet the data traffic demand is avoided.

For example, in this embodiment, the throughput rate of surfing the internet of the mobile phone and the signal quality of the WiFi module of the mobile phone on the current 5G frequency band are monitored, if the throughput rate is unchanged but the signal quality on the 5G frequency band is reduced and is lower than the fifth threshold, at this time, the WiFi module of the mobile phone is controlled to open the 2.4G frequency band under the condition that the 5G frequency band is kept open, so that the WiFi module is adjusted from working on the 5G frequency band to working on the 2.4G frequency band and the 5G frequency band simultaneously, and therefore, the data flow requirement of surfing the internet of the mobile phone is met by increasing the working frequency band of 2.4G on the WiFi module and further under the condition that the signal quality on the 5G frequency band is reduced.

In one implementation, if the target communication module is simultaneously operated in the first frequency band and the second frequency band and the signal quality of the data traffic signal in the second frequency band is higher than the fifth threshold under the condition that the data traffic demand is unchanged, the target communication module is controlled to be adjusted from being simultaneously operated in the first frequency band and the second frequency band to being operated in the second frequency band.

Specifically, in this embodiment, the change condition of the data traffic demand and the signal quality of the data traffic signal on the working frequency band where the target communication module is located are continuously monitored, if the data traffic demand is unchanged and the signal quality of the target communication module on the second frequency band is raised to be higher than the fifth threshold value under the condition that the target communication module works on the lower first frequency band and the higher second frequency band, the lower first frequency band can be closed, the data traffic on the second frequency band can meet the data traffic demand, and therefore the target communication module is adjusted to work on the second frequency band from the second frequency band and the first frequency band at the same time, and therefore the power consumption of the electronic device is reduced by reducing the number of the working frequency bands of the target communication module under the condition that the data traffic demand is met.

For example, in this embodiment, the throughput rate of surfing the internet of a mobile phone and the signal quality on the 5G frequency band when the WiFi module of the mobile phone works on the 2.4G frequency band and the 5G frequency band simultaneously are monitored, if the throughput rate is unchanged and the signal quality on the 5G frequency band is raised and is higher than the fifth threshold, at this time, the WiFi module of the mobile phone is controlled to close the 2.4G frequency band under the condition that the 5G frequency band is kept open, so that the WiFi module is adjusted from working on the 2.4G frequency band and the 5G frequency band to working on the 5G frequency band simultaneously, thereby, by closing the working frequency band of 2.4G on the WiFi module, the signal quality on the 5G frequency band is raised to the condition that the data flow requirement of surfing the internet of the mobile phone can be met, and the power consumption of the electronic device can be reduced.

In one implementation, in the case where the target communication module operates in the second frequency band, if the data traffic demand increases, the target communication module is controlled based on the signal quality of the data traffic signal in the first frequency band and the third frequency band from operating in the second frequency band to simultaneously operating in the first frequency band and the second frequency band, or simultaneously operating in the second frequency band and the third frequency band, or simultaneously operating in the first frequency band, the second frequency band, and the third frequency band.

Specifically, in this embodiment, the change condition of the data traffic demand and the signal quality of the data traffic signal on the idle frequency band of the target communication module are continuously monitored, and if the data traffic demand increases under the condition that the target communication module works in the second frequency band of the middle-grade, the working frequency band is increased for the target communication module according to the signal quality of the data traffic signal in the first frequency band and the third frequency band.

For example, if the signal quality in the first frequency band is higher than the fifth threshold, the first frequency band is started, that is, the target communication module is controlled to be adjusted from working in the second frequency band to working in the first frequency band and the second frequency band simultaneously; if the signal quality on the third frequency band is higher than a fifth threshold, the third frequency band is started, namely the target communication module is controlled to be adjusted from working in the second frequency band to working in the second frequency band and the third frequency band at the same time; if the signal quality on the first frequency band is higher than the fifth threshold and the signal quality on the third frequency band is higher than the fifth threshold, the first frequency band and the second frequency band are simultaneously started, namely the target communication module is controlled to be adjusted from working in the second frequency band to working in the first frequency band, the second frequency band and the third frequency band simultaneously. Thus, the target communication module can work more working frequency bands at the same time. It can be seen that, in this embodiment, under the condition that the data traffic demand increases, the number of working frequency bands is increased for the target communication module according to the signal quality on each idle frequency band, so as to meet the increased data traffic demand.

For example, in this embodiment, the throughput rate of surfing the internet of the mobile phone and the signal quality on the 2.4G frequency band and the 6G frequency band when the WiFi module of the mobile phone works in the 5G frequency band are monitored, if the throughput rate increases, the working frequency band added to the WiFi module is determined according to the signal quality on the 2.4G frequency band and the 6G frequency band, if the signal quality on the 2.4G frequency band is higher than the fifth threshold, at this time, the WiFi module of the mobile phone is controlled to synchronously open the 2.4G frequency band under the condition that the 5G frequency band is kept open, so that the WiFi module is adjusted from working in the 5G frequency band to working in the 2.4G frequency band and the 5G frequency band simultaneously; if the signal quality on the 6G frequency band is higher than a fifth threshold, at the moment, the WiFi module of the mobile phone is controlled to synchronously start the 6G frequency band under the condition that the 5G frequency band is kept to be started, so that the WiFi module is adjusted from working in the 5G frequency band to working in the 6G frequency band and the 5G frequency band at the same time; if the signal quality on the 2.4G frequency band and the 6G frequency band is higher than the fifth threshold, at this time, the WiFi module of the mobile phone is controlled to synchronously start the 2.4G frequency band and the 6G frequency band under the condition that the 5G frequency band is kept to be started, so that the WiFi module is adjusted from working in the 5G frequency band to working in the 2.4G frequency band, the 5G frequency band and the 6G frequency band at the same time, and therefore, under the condition that the demand of the mobile phone for data flow is increased, the idle frequency band with higher signal quality is started to meet the increased data flow demand.

In one implementation, in a case where the target communication module operates in the third frequency band, if the data traffic demand decreases, the target communication module is controlled to adjust from operating in the third frequency band to operating in the second frequency band or the first frequency band based on the signal quality of the data traffic signal in the first frequency band and the second frequency band.

Specifically, in this embodiment, the change condition of the data traffic demand and the signal quality of the data traffic signal on the idle frequency band of the target communication module are continuously monitored, and if the data traffic demand is reduced in the case that the target communication module works in the higher third frequency band, the working frequency band is switched for the target communication module according to the signal quality of the data traffic signal in the second frequency band and the first frequency band.

For example, if the signal quality on the first frequency band is higher than the fifth threshold, the first frequency band is turned on and the third frequency band is turned off, that is, the target communication module is controlled to be adjusted from operating in the third frequency band to operating in the first frequency band; and if the signal quality on the second frequency band is higher than the fifth threshold, starting the second frequency band and closing the third frequency band, namely controlling the target communication module to adjust from working in the third frequency band to working in the third frequency band. Therefore, the target communication module is switched from a third frequency band with higher frequency band to a second frequency band or a first frequency band with lower frequency band but higher signal quality. If the signal quality on the first frequency band is higher than the fifth threshold and the signal quality on the second frequency band is higher than the fifth threshold, the first frequency band and the second frequency band are started and the third frequency band is closed, namely the target communication module is controlled to be adjusted from working in the third frequency band to working in the first frequency band and the second frequency band simultaneously. Therefore, in the case of reduced data traffic demand, the method switches the working frequency band with the lower frequency band for the target communication module according to the signal quality on each idle frequency band, so as to reduce the power consumption of the electronic device under the condition of meeting the reduced data traffic demand.

For example, in this embodiment, the throughput rate of surfing the internet of the mobile phone and the signal quality on the 2.4G frequency band and the 5G frequency band when the WiFi module of the mobile phone works in the 6G frequency band are monitored, if the throughput rate is reduced, the working frequency band switched by the WiFi module is determined according to the signal quality on the 2.4G frequency band and the 5G frequency band, if the signal quality on the 2.4G frequency band is higher than the fifth threshold and the 2.4G frequency band can also meet the reduced throughput rate, at this time, the WiFi module of the mobile phone is controlled to open the 2.4G frequency band and close the 6G frequency band, so that the WiFi module is adjusted from working in the 6G frequency band to working in the 2.4G frequency band; if the signal quality on the 5G frequency band is higher than a fifth threshold and can meet the reduced throughput rate, at the moment, controlling the WiFi module of the mobile phone to start the 5G frequency band and close the 6G frequency band, so that the WiFi module is adjusted from working in the 6G frequency band to working in the 5G frequency band; if the signal quality on the 5G frequency band is higher than the fifth threshold and the signal quality on the 2.4G frequency band is higher than the fifth threshold, but the reduced throughput rate cannot be satisfied on the 5G frequency band alone and the reduced throughput rate cannot be satisfied on the 2.4G frequency band alone, at this time, the WiFi module of the mobile phone is controlled to turn on the 5G frequency band and the 2.4G frequency band and turn off the 6G frequency band, so that the WiFi module is adjusted from operating in the 6G frequency band to operating in both the 2.4G frequency band and the 5G frequency band. Therefore, under the condition that the demand of the mobile phone for data flow is reduced, one or more idle frequency bands with higher signal quality are started, so that the power consumption of the mobile phone is reduced under the condition that the demand of the reduced data flow is met.

In one implementation manner, when the signal quality of the first type of data traffic signal in the space where the electronic device is located does not meet the corresponding signal quality threshold value and/or the first communication module of the electronic device cannot meet the data traffic demand, the second communication module of the electronic device is controlled to adjust the working frequency band and/or the networking mode.

The first type can be WiFi type, the first communication module can be WiFi module, the second communication module is different from the first communication module in type, the second communication module can be WAN module, networking mode of the second communication module can have independent networking mode, non-independent networking mode and the like. The signal quality of the data traffic signal of the first type not meeting the corresponding signal quality threshold may be: the signal quality of the data traffic signal of the first type is less than or equal to the corresponding signal quality threshold. The first communication module failing to satisfy the data traffic demand may be: the maximum data traffic of the first communication module on the current working frequency band is smaller than the highest data traffic in the data traffic demand.

For example, if the following occurs on a cell phone: and if the signal quality of the WiFi data flow in the space where the mobile phone is positioned is lower than a fifth threshold value, and/or the maximum data throughput rate of the WiFi module of the mobile phone on the working frequency band is lower than the required throughput rate, the mobile phone can be switched to the WAN module to operate in a corresponding working frequency band and independent networking or non-independent networking mode, so that the mobile phone is switched to the WAN network to meet the data flow requirement, and the situation that the WiFi module cannot meet the data flow requirement is avoided.

In one implementation manner, when the signal quality of the first type of data traffic signal in the space where the electronic device is located does not meet the corresponding signal quality threshold value and/or the first communication module of the electronic device cannot meet the data traffic demand, the second communication module of the electronic device is controlled to adjust the working frequency band and/or the networking mode thereof so as to provide the required data traffic for the electronic device in cooperation with the first communication module.

For example, if the following occurs on a cell phone: and if the signal quality of the WiFi data flow in the space where the mobile phone is located is lower than a fifth threshold value, and/or the maximum data throughput rate of the WiFi module of the mobile phone on the working frequency band is lower than the required throughput rate, the WAN module can be synchronously started to operate in a corresponding working frequency band and an independent networking or non-independent networking mode under the condition that the WiFi module is started, so that the data flow requirement is met on the mobile phone through the WiFi network and the WAN network at the same time, and the situation that the data flow requirement cannot be met by independently using the WiFi module is avoided.

In one implementation manner, under the condition that a first data traffic signal provided by a first network end and a second data traffic signal provided by a second network end are provided in a space where electronic equipment is located, a corresponding communication connection is established between a signal quality control target communication module based on change information of data traffic demands and the data traffic signal and the first network end and/or the second network end under different communication parameters.

The first network end and the second network end may be network hotspot devices, such as routers, in a space where the electronic device is located. The space where the electronic device is located has a first data traffic signal provided by a first network end and a second data traffic signal provided by a second network end, specifically: the electronic device can be connected to the first network end and the second network end, and further can use the first data traffic signal provided by the first network end and the second data traffic signal provided by the second network end.

Based on this, in step 102, the target communication module may be controlled to establish a communication connection corresponding to the first network end and/or the second network end according to the situation that the data traffic demand is increased or decreased and the signal quality of each of the first data traffic signal and the second data traffic signal, and the communication parameters between the target communication module and the first network end may be the same or different from the communication parameters between the target communication module and the second network end. If the data traffic demand is larger and the signal quality of each of the first data traffic signal and the second data traffic signal is larger than the fifth threshold, the target communication module is controlled to establish corresponding communication connection with the first network end and/or the second network end at the same time, and the working frequency band between the target communication module and the first network end is different from the working frequency band between the target communication module and the second network end. If the data traffic demand is smaller and the signal quality of each of the first data traffic signal and the second data traffic signal is greater than the fifth threshold, the control target communication module establishes a corresponding communication connection with only the first network end, or the control target communication module establishes a corresponding communication connection with only the second network end. If the signal quality of the first data traffic signal is greater than the fifth threshold, but the signal quality of the second data traffic signal is less than the fifth threshold, the control target communication module only establishes a corresponding communication connection with the first network side. If the signal quality of the first data traffic signal is smaller than the fifth threshold value, but the signal quality of the second data traffic signal is larger than the fifth threshold value, the control target communication module only establishes corresponding communication connection with the second network end. Etc.

For example, two or more routers are used as hot spot devices in an indoor space where the mobile phone is located to provide data flow signals for the mobile phone, and if the signal quality of the data flow signals provided by the router A is higher than a fifth threshold value and the data flow requirement is larger, the WiFi module of the mobile phone is controlled to be connected to the hot spot of the router A, and the WiFi module works in a higher 5G frequency band; as the data traffic demand continues to grow, the data traffic signal provided by the router a cannot meet the data traffic demand, at this time, if the signal quality of the data traffic signal provided by the router B is lower than the fifth threshold, the WiFi module of the mobile phone is controlled to be simultaneously connected to the hotspot of the router B, and the WiFi module operates in the lower 2.4G frequency band, and if the signal quality of the data traffic signal provided by the router B is higher than the fifth threshold, the WiFi module of the mobile phone is controlled to be simultaneously connected to the hotspot of the router B, and the WiFi module operates in the higher 6G frequency band. If the signal quality of the data traffic signal provided by the router A is lower than the fifth threshold, controlling the WiFi module of the mobile phone to be connected to the hot spot of the router A, and enabling the WiFi module to work in a 2.4G frequency band, and meanwhile, in order to meet the requirement of the increased data traffic, enabling the WiFi module of the mobile phone to be connected to the hot spot of the router B, and enabling the WiFi module to work in a 5G frequency band or a 6G frequency band.

Based on the above implementation scheme, in one implementation manner, the use condition of the data traffic signal of each frequency band provided by the network side may also be obtained in this embodiment, and then in step 102, the target communication module may be controlled to adjust the working parameters thereof based on the use condition and the change information of the data traffic demand.

Specifically, the usage of the data traffic signal of each frequency band provided by the network side may refer to: whether the number of the devices connected by the network end in each frequency band exceeds a limit value. For example, if the number of devices connected by the network end on a certain working frequency band has reached a limit value, the control target control module obtains the data traffic signal provided by the network end on other working frequency bands. If the number of the devices connected by the network end on a certain working frequency band does not reach the limit value, the control target control module obtains the data flow signal provided by the network end on the working frequency band.

For example, a router is arranged in an indoor space where the mobile phone is located and used as a hot spot device to provide data flow signals for the mobile phone, communication connection on a plurality of frequency bands such as 2.4G, 5G and 6G can be realized between the mobile phone and the router, the number of devices connected by the router on the 6G frequency band is monitored on the mobile phone, if 5 devices are connected on the 6G frequency band, namely, the limit value is exceeded, and the data flow signals on the 5G frequency band can meet the data flow requirements, a WiFi module on the mobile phone is connected to the 5G frequency band of the router, and the WiFi module works on the 5G frequency band.

For another example, a router is arranged in an indoor space where the mobile phone is located and used as a hot spot device to provide data flow signals for the mobile phone, communication connection on a plurality of frequency bands such as 2.4G, 5G and 6G can be realized between the mobile phone and the router, the number of devices connected by the router on the 6G frequency band is monitored on the mobile phone, if 5 devices are connected on the 6G frequency band, namely, the limit value is exceeded, but the data flow signals on the 5G frequency band can not meet the data flow requirements, a WiFi module on the mobile phone is connected to the 5G frequency band and the 2.4G frequency band of the router, so that the WiFi module works on the 2.4G frequency band and the 5G frequency band simultaneously, and communication connection is realized on a plurality of working frequency bands, so as to meet the data flow requirements of the mobile phone.

In one implementation manner, in this embodiment, the usage situation of the data traffic signal of each frequency band provided by the network side may also be obtained, and then in step 102, the target communication module may be controlled to adjust the working parameters thereof based on the usage situation, the signal quality and the change information of the data traffic demand.

Specifically, if the number of devices connected by the network end on a certain working frequency band has reached a limit value and the signal quality of the data traffic signals on other working frequency bands is greater than a fifth threshold value, the control target control module obtains the data traffic signals provided by the network end on the other working frequency bands. If the number of the devices connected by the network end on a certain working frequency band does not reach the limit value and the signal quality of the data flow signals on other working frequency bands is larger than a fifth threshold value, the control target control module obtains the data flow signals provided by the network end on the working frequency band. If the number of the devices connected by the network end on a certain working frequency band does not reach the limit value, but the signal quality of the data flow signals on the working frequency band is smaller than a fifth threshold value, the control target communication module obtains the data flow signals provided by the network end on other working frequency bands. If the data traffic demand increases, detecting whether the number of the devices connected with the network end on other working frequency bands reaches a limit value, and if the number of the devices connected with the working frequency bands does not reach the limit value, controlling the target communication module to obtain the data traffic signal provided by the network end on the working frequency band so as to increase the number of the working frequency bands of the target communication module to meet the data traffic demand.

For example, a router is arranged in an indoor space where the mobile phone is located and used as a hot spot device to provide data flow signals for the mobile phone, communication connection on a plurality of frequency bands such as 2.4G, 5G and 6G can be realized between the mobile phone and the router, the number of devices connected by the router on the 6G frequency band is monitored on the mobile phone, if 5 devices are connected on the 6G frequency band, namely, the limit value is exceeded, the data flow signals on the 5G frequency band can meet the data flow requirements, and the signal quality is also larger than a fifth threshold value, a WiFi module on the mobile phone is connected to the 5G frequency band of the router, so that the WiFi module works on the 5G frequency band. Along with the data flow requirement becoming big, then monitor the equipment quantity that is connected on other frequency channels on the cell-phone, if the equipment quantity that is connected on 2.4G frequency channel does not surpass the limit value, the wiFi module on the cell-phone is connected to the 2.4G frequency channel of router for wiFi module simultaneous working is in 2.4G frequency channel and 5G frequency channel, in order to satisfy the data flow requirement that increases on the cell-phone.

In other implementations, in this embodiment, motion data of the electronic device may be monitored, and then the motion data is used to characterize signal quality of a data traffic signal in a space where the electronic device is located, so as to adjust working parameters of the target communication module in real time based on the motion data.

Specifically, under the condition that the target communication module works in the second frequency band or the third frequency band, if the electronic equipment moves away from the network end at a faster speed, the target communication module is controlled to work in the first frequency band; and under the condition that the target communication module works in the second frequency band or the first frequency band, if the electronic equipment moves close to the network end at a faster speed, controlling the target communication module to work in a third frequency band.

For example, in the case that the WiFi module of the mobile phone operates in the 5G frequency band or the 6G frequency band, if the mobile phone moves away from the router at a faster rate, that is, the signal quality of the WiFi module in the 5G frequency band or the 6G frequency band is poor, the WiFi module is controlled to operate in the 2.4G frequency band; under the condition that the WiFi module of the mobile phone works in the 2.4G frequency band, if the mobile phone moves close to the router at a faster speed, namely the signal quality of the WiFi module on the 5G frequency band or the 6G frequency band becomes stronger, the WiFi module is controlled to work in the 5G frequency band, the 6G frequency band or both the 5G frequency band and the 6G frequency band.

Referring to fig. 3, a schematic structural diagram of a control device according to a second embodiment of the present application may be configured in an electronic device, such as a mobile phone, a tablet computer, a notebook, etc., having a communication module and capable of performing data communication. The technical scheme in the embodiment is mainly used for reducing the operation complexity of the control communication module so as to improve the use experience of a user on the electronic equipment.

Specifically, the apparatus in this embodiment may include the following units:

a demand monitoring unit 301, configured to monitor a data traffic demand of an electronic device, where the data traffic at least enables the electronic device to access or load a target data content of a network side;

a parameter control unit 302, configured to control the target communication module of the electronic device to adjust the working parameter thereof based on the change information of the data traffic demand;

the target communication module has different power consumption and/or communication parameters before and after the working parameters are adjusted, and the communication parameters can influence the data flow generated by the electronic equipment.

It can be seen from the above technical solution that, in the control device provided in the second embodiment of the present application, the data flow requirement of the electronic device for accessing or loading the target data content of the network end is monitored, and then the target communication module of the electronic device is controlled to adjust the working parameters thereof based on the change information of the data flow requirement, and the power consumption of the target communication module before and after the adjustment of the working parameters thereof and/or the communication parameters affecting the data flow generated by the electronic device are different. Therefore, in this embodiment, the target communication module is controlled to be under the working parameters of different power consumption and/or different communication parameters according to the change information of the data flow requirement of the network side data content accessed or loaded by the electronic device, and the working parameter adjustment is not required to be manually performed on the communication module, so that the operation complexity is reduced, and the use experience of the user on the electronic device is improved.

In one implementation, the demand monitoring unit 301 monitors the data traffic demand of the electronic device, which may be implemented by at least one of the following:

acquiring operation information of a target application of the electronic equipment, and monitoring the data flow demand based on the operation information, wherein the target application is an application which needs to access a network side in the electronic equipment to acquire target data content;

obtaining usage pattern information of the electronic device, and monitoring the data traffic demand based on the usage pattern information;

acquiring using environment information of the electronic equipment, and monitoring the data flow requirement based on the using environment information;

obtaining the type and/or the acquisition mode of the target data content, and monitoring the data flow requirement based on the type and/or the acquisition mode;

and monitoring a request instruction obtained by the electronic equipment, and monitoring the data flow demand based on the request instruction, wherein the request instruction is used for adjusting the data flow.

In one implementation, when controlling the target communication module of the electronic device to adjust the working parameters based on the change information of the data traffic demand, the parameter control unit 302 may be implemented by at least one of the following:

If the change information characterizes that the data flow requirement of the electronic equipment is increased, the working frequency band of the target communication module is controlled to be increased and/or increased;

if the change information represents that the data flow requirement of the electronic equipment is reduced, controlling the working frequency band of the target communication module to be reduced and/or reduced;

if the target index parameter of the electronic equipment exceeds a first threshold value and lasts for a first duration, controlling the target communication module to adjust from working in a first frequency band to simultaneously working in a first frequency band and a second frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, and the second frequency band is larger than the first frequency band;

if the target index parameter of the electronic equipment exceeds a second threshold value and lasts for a second duration, controlling the target communication module to adjust from simultaneously working in a first frequency band and a second frequency band to simultaneously working in the first frequency band, the second frequency band and a third frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, the third frequency band is larger than the second frequency band, and the second frequency band is larger than the first frequency band;

if the target index parameter of the electronic equipment is smaller than a third threshold value and lasts for a third duration, the target communication module is controlled to be adjusted from simultaneously working in a first frequency band, a second frequency band and a third frequency band to simultaneously working in the first frequency band and the second frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, the third frequency band is larger than the second frequency band, and the second frequency band is larger than the first frequency band;

And if the target index parameter of the electronic equipment is smaller than a fourth threshold value and lasts for a fourth duration, controlling the target communication module to adjust from simultaneously working in a first frequency band and a second frequency band to working in the first frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, and the second frequency band is larger than the first frequency band.

In one implementation, the demand monitoring unit 301 is further configured to: monitoring the signal quality of a data flow signal in a space where the electronic equipment is located; based on this, the parameter control unit 302 specifically functions to: and controlling the target communication module to adjust working parameters based on the signal quality and the change information of the data flow demand.

In one implementation, the parameter control unit 302 may control the target communication module to adjust its operating parameter based on the signal quality and the change information of the data traffic demand, where the parameter control unit may be implemented by at least one of the following:

under the condition that the data traffic demand is unchanged, if the target communication module works in a second frequency band and the signal quality of a data traffic signal of the second frequency band is lower than a fifth threshold, controlling the target communication module to adjust from working in the second frequency band to simultaneously working in the second frequency band and a first frequency band, wherein the second frequency band is larger than the first frequency band;

Under the condition that the data flow demand is unchanged, if the target communication module works in a first frequency band and a second frequency band at the same time and the signal quality of a data flow signal of the second frequency band is higher than a fifth threshold value, controlling the target communication module to adjust from the first frequency band and the second frequency band to the second frequency band, wherein the second frequency band is larger than the first frequency band;

if the data traffic demand increases, controlling the target communication module to adjust from operating in the second frequency band to simultaneously operating in the first frequency band and the second frequency band, or simultaneously operating in the second frequency band and the third frequency band, or simultaneously operating in the first frequency band, the second frequency band and the third frequency band based on the signal quality of the data traffic signal in the first frequency band and the third frequency band under the condition that the target communication module operates in the second frequency band;

if the data traffic demand is reduced under the condition that the target communication module works in a third frequency band, controlling the target communication module to adjust from working in the third frequency band to working in a second frequency band or the first frequency band based on the signal quality of the data traffic signal in the first frequency band and the second frequency band;

Controlling a second communication module of the electronic equipment to adjust the working frequency band and/or networking mode of the second communication module under the condition that the signal quality of a first type of data flow signal in the space where the electronic equipment is located does not meet a corresponding signal quality threshold value and/or the first communication module of the electronic equipment cannot meet the data flow requirement;

controlling a second communication module of the electronic equipment to adjust the working frequency band and/or networking mode of the second communication module under the condition that the signal quality of a first type of data flow signal in the space where the electronic equipment is located does not meet a corresponding signal quality threshold value and/or a first communication module of the electronic equipment cannot meet the data flow requirement so as to provide the required data flow for the electronic equipment in cooperation with the first communication module;

wherein the first communication module is different from the second communication module in type;

under the condition that a first data flow signal provided by a first network end and a second data flow signal provided by a second network end are arranged in a space where the electronic equipment is located, controlling the target communication module to establish corresponding communication connection with the first network end and/or the second network end under different communication parameters based on the change information of the data flow demand and the signal quality of the data flow signal;

In one implementation, the demand monitoring unit 301 is further configured to: the usage of the data traffic signals of each frequency band provided by the network side is obtained, based on which the parameter control unit 302 may be specifically implemented by at least one of the following:

controlling the target communication module to adjust working parameters based on the use condition and the change information of the data flow demand;

and controlling the target communication module to adjust working parameters based on the use condition, the signal quality and the change information of the data flow demand.

In one implementation, the demand monitoring unit 301 is specifically configured to: monitoring motion data of the electronic device; the parameter control unit 302 is specifically configured to adjust the working parameter of the target communication module in real time based on the motion data.

It should be noted that, the specific implementation of each unit in this embodiment may refer to the corresponding content in the foregoing, which is not described in detail herein.

Referring to fig. 4, a schematic structural diagram of an electronic device according to a third embodiment of the present application is provided, where the electronic device includes:

a target communication module 401;

a processor 402, configured to monitor a data traffic requirement of an electronic device, where the data traffic at least enables the electronic device to access or load a target data content of a network side; controlling the target communication module to adjust working parameters based on the change information of the data flow demand;

The target communication module has different power consumption and/or communication parameters before and after the working parameters are adjusted, and the communication parameters can influence the data flow generated by the electronic equipment.

As can be seen from the above technical solution, in the electronic device provided in the third embodiment of the present application, the data traffic demand of the electronic device for accessing or loading the target data content of the network side is monitored, and then the target communication module of the electronic device is controlled to adjust the working parameters thereof based on the change information of the data traffic demand, and the power consumption of the target communication module before and after the adjustment of the working parameters thereof and/or the communication parameters affecting the data traffic generated by the electronic device are different. Therefore, in this embodiment, the target communication module is controlled to be under the working parameters of different power consumption and/or different communication parameters according to the change information of the data flow requirement of the network side data content accessed or loaded by the electronic device, and the working parameter adjustment is not required to be manually performed on the communication module, so that the operation complexity is reduced, and the use experience of the user on the electronic device is improved.

In the wireless lan WLAN (Wireless LocalArea Network), taking a scenario that the WiFi module in the mobile phone adopts WiFi7 to realize communication as an example, the biggest improvement of WiFi7 is that the maximum transmission rate is improved, and the peak transmission rate is improved from 9.6Gbps to 46Gbps of WiFi 6. I.e. from a transport speed of 1.2GB/s to a transport speed of 5.75 GB/s. The WiFi7 can realize dual-frequency simultaneous operation, increases bandwidth, and improves Multiple-Input Multiple-Output (MIMO) spatial multiplexing capability and throughput. Under the office or home Wifi network, the default is to prefer Wifi5G/6GHz connection, the bandwidth is larger than 2.4G, and the speed is higher; but the penetration effect of 6G/5GHz is weaker than that of 2.4 Ghz; the user needs to manually try to connect 2.4Ghz again after the connection is disabled.

Based on the method, the real-time uplink and downlink network rate of the WiFi module of the mobile phone is detected, whether the 5GHz or 6GHz frequency band of the WiFi is started or not is dynamically controlled, and proper bandwidth resources are allocated, so that the uplink and downlink throughput rate of the mobile phone in big data is guaranteed; the efficiency can be improved as much as possible, the unused bandwidth can be reduced, and the power consumption can be saved.

Referring to the band control flow shown in fig. 5, in order to avoid the ping-pong effect of increasing and closing the bandwidth, a rate threshold X (Mbps) triggering an increase of the bandwidth is set to be well above a rate threshold Y (Mbps) reducing the bandwidth. One control flow in the present application is described below:

firstly, after a terminal such as a mobile phone is started, a WiFi module is connected with a WiFi7, and data traffic provided by the WiFi7 is used;

under the condition that the WiFi module currently works in a 2.4G mode, monitoring whether DL is larger than X1, if DL exceeds X1 and lasts for a certain period of time such as 3 seconds, starting a 5G frequency band, so that the WiFi module works in a 2.4G+5G mode;

under the condition that the WiFi module currently works in a 2.4G mode, monitoring whether DL is larger than X1, and if DL does not exceed X1, not performing other processing;

under the condition that the WiFi module currently works in a 2.4G+5G mode, monitoring whether the real-time throughput rate DL is larger than X2, if the real-time throughput rate DL exceeds X2 and lasts for a certain period of time such as 3 seconds, starting a 6G frequency band of the WiFi module, so that the WiFi module is in a mode of working in a 2.4GHz+5GHz+6GHz;

Under the condition that the WiFi module currently works in a 2.4G+5G mode, monitoring whether DL is smaller than Y1, if the DL is smaller than Y1 and lasts for a certain period of time such as 3 seconds, closing a 5G frequency band to enable the WiFi module to work in a 2.4GHz mode;

under the condition that the WiFi module currently works in a mode of 2.4GHz+5GHz+6GHz, monitoring whether DL is smaller than Y2, if DL exceeds Y2, not performing other processing, and if DL is lower than Y2 for a certain duration such as 3 seconds, closing a 6G frequency band to enable the WiFi module to be in a mode of 2.4G+5G.

Therefore, the method and the device not only ensure the throughput rate requirement and the use experience of uplink and downlink of big data under the WiFi network of the user; the efficiency can be improved as much as possible, the unused bandwidth can be reduced, the WIFI capacity can be increased, and the power consumption of the router and the terminal can be saved.

In order to avoid ping pong, the rate threshold for adjusting the bandwidth in the present application should satisfy the condition: x2 is greater than X1, Y1 is greater than Y2, and Y1 is less than X2.

Referring to the frequency band control flow shown in fig. 6, the technology of supporting simultaneous connection of a plurality of hotspots AP (Access Point) by Wifi7 is used in the present application to realize seamless handover. Taking a WiFi terminal such as a mobile phone as an example, a control flow in the present application is described below:

Firstly, a WiFi module on a mobile phone is limited to connect with an AP by using 5G and 6G frequency bands. Before the background of the mobile phone monitors the Wifi5Ghz/6GHz signal or the signal-to-noise ratio SNR (Signalto Interference plus Noise Ratio) is weak to a certain threshold (for example, -75dBm/SNR < 0) and is not disconnected, the WiFi module of the mobile phone is actively connected with the AP of the 2.4G frequency band to keep double AP connection, and then even if the AP on the 5G or 6G is disconnected, the user can continue to use, so that seamless switching is realized.

Secondly, when the SNR of the hot spot signal of the WiFi5G/6G is higher than a threshold (such as-50 dBm), the WiFi module only leaves AP connection of 5Ghz/6G, such as 5G+5G (two hot spots are respectively connected by 5G) or 5G+6G (two hot spots are respectively connected by 5G and 6G), and the 2.4GHz is closed, so that the workload of an antenna in the WiFi module is reduced, and the power is saved.

In addition, an abnormality monitoring flow is provided in the present application. For example, when the capacity (the number of connectable devices) of a certain AP is full, so that a datastack (only uplink data ULpackage has no downlink data DLpackage) cannot be accessed or occurs, the WiFi module of the mobile phone actively connects to other APs at the same time, and uses dual APs; and realizing that the Wifi data is always connected and available.

And aiming at the scene that the mobile phone leaves the Wifi coverage area, when the WiFi module of the mobile phone cannot be connected with the AP of each frequency band, a data channel is automatically kept through the Celluar, namely seamless switching of user data use is realized by means of a mobile network.

When the data UL/DL throughput rate reaches a threshold (for example, the DL throughput rate reaches 1 Gbps), the user WiFi module actively connects the maximum possible number of APs, and the acceleration is carried out by fully utilizing multiple APs.

In conclusion, the multi-AP automatic monitoring system is designed for multi-AP technology, automatic monitoring/recognition and connection are achieved, and user experience is improved.

In the present specification, each embodiment is described in a progressive manner, and each embodiment is mainly described in a different point from other embodiments, and identical and similar parts between the embodiments are all enough to refer to each other. For the device disclosed in the embodiment, since it corresponds to the method disclosed in the embodiment, the description is relatively simple, and the relevant points refer to the description of the method section.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative elements and steps are described above generally in terms of functionality in order to clearly illustrate the interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present application.

The steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. The software modules may be disposed in Random Access Memory (RAM), memory, read Only Memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A control method, comprising:

monitoring the data flow demand of the electronic equipment, wherein the data flow at least enables the electronic equipment to access or load target data content of a network side;

Controlling a target communication module of the electronic equipment to adjust working parameters based on the change information of the data flow demand;

the target communication module has different power consumption and/or communication parameters before and after the working parameters are adjusted, and the communication parameters can influence the data flow generated by the electronic equipment.

2. The method of claim 1, wherein monitoring data traffic demand of the electronic device comprises at least one of:

acquiring operation information of a target application of the electronic equipment, and monitoring the data flow demand based on the operation information, wherein the target application is an application which needs to access a network side in the electronic equipment to acquire target data content;

obtaining usage pattern information of the electronic device, and monitoring the data traffic demand based on the usage pattern information;

acquiring using environment information of the electronic equipment, and monitoring the data flow requirement based on the using environment information;

obtaining the type and/or the acquisition mode of the target data content, and monitoring the data flow requirement based on the type and/or the acquisition mode;

and monitoring a request instruction obtained by the electronic equipment, and monitoring the data flow demand based on the request instruction, wherein the request instruction is used for adjusting the data flow.

3. The method of claim 1, wherein controlling the target communication module of the electronic device to adjust its operating parameters based on the change information of the data traffic demand comprises at least one of:

if the change information characterizes that the data flow requirement of the electronic equipment is increased, the working frequency band of the target communication module is controlled to be increased and/or increased;

and if the change information characterizes that the data flow requirement of the electronic equipment is reduced, controlling the working frequency band of the target communication module to be reduced and/or reduced.

4. The method of claim 3, wherein controlling the target communication module of the electronic device to adjust its operating parameters based on the change information of the data traffic demand comprises at least one of:

if the target index parameter of the electronic equipment exceeds a first threshold value and lasts for a first duration, controlling the target communication module to adjust from working in a first frequency band to simultaneously working in a first frequency band and a second frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, and the second frequency band is larger than the first frequency band;

if the target index parameter of the electronic equipment exceeds a second threshold value and lasts for a second duration, controlling the target communication module to adjust from simultaneously working in a first frequency band and a second frequency band to simultaneously working in the first frequency band, the second frequency band and a third frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, the third frequency band is larger than the second frequency band, and the second frequency band is larger than the first frequency band;

If the target index parameter of the electronic equipment is smaller than a third threshold value and lasts for a third duration, the target communication module is controlled to be adjusted from simultaneously working in a first frequency band, a second frequency band and a third frequency band to simultaneously working in the first frequency band and the second frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, the third frequency band is larger than the second frequency band, and the second frequency band is larger than the first frequency band;

and if the target index parameter of the electronic equipment is smaller than a fourth threshold value and lasts for a fourth duration, controlling the target communication module to adjust from simultaneously working in a first frequency band and a second frequency band to working in the first frequency band, wherein the target index parameter can indicate the data flow requirement of the electronic equipment, and the second frequency band is larger than the first frequency band.

5. The method of claim 1, further comprising:

and monitoring the signal quality of a data flow signal in a space where the electronic equipment is located, and controlling the target communication module to adjust the working parameters of the target communication module based on the signal quality and the change information of the data flow demand.

6. The method of claim 5, wherein controlling the target communication module to adjust its operating parameters based on the signal quality and the change in data traffic demand information comprises at least one of:

Under the condition that the data traffic demand is unchanged, if the target communication module works in a second frequency band and the signal quality of a data traffic signal of the second frequency band is lower than a fifth threshold, controlling the target communication module to adjust from working in the second frequency band to simultaneously working in the second frequency band and a first frequency band, wherein the second frequency band is larger than the first frequency band;

under the condition that the data flow demand is unchanged, if the target communication module works in a first frequency band and a second frequency band at the same time and the signal quality of a data flow signal of the second frequency band is higher than a fifth threshold value, controlling the target communication module to adjust from the first frequency band and the second frequency band to the second frequency band, wherein the second frequency band is larger than the first frequency band;

if the data traffic demand increases, controlling the target communication module to adjust from operating in the second frequency band to simultaneously operating in the first frequency band and the second frequency band, or simultaneously operating in the second frequency band and the third frequency band, or simultaneously operating in the first frequency band, the second frequency band and the third frequency band based on the signal quality of the data traffic signal in the first frequency band and the third frequency band under the condition that the target communication module operates in the second frequency band;

And under the condition that the target communication module works in a third frequency band, if the data flow demand is reduced, controlling the target communication module to adjust from working in the third frequency band to working in the second frequency band or the first frequency band based on the signal quality of the data flow signal in the first frequency band and the second frequency band.

7. The method of claim 5, controlling the target communication module to adjust its operating parameters based on the signal quality and the change in data traffic demand information, further comprising at least one of:

controlling a second communication module of the electronic equipment to adjust the working frequency band and/or networking mode of the second communication module under the condition that the signal quality of a first type of data flow signal in the space where the electronic equipment is located does not meet a corresponding signal quality threshold value and/or the first communication module of the electronic equipment cannot meet the data flow requirement;

controlling a second communication module of the electronic equipment to adjust the working frequency band and/or networking mode of the second communication module under the condition that the signal quality of a first type of data flow signal in the space where the electronic equipment is located does not meet a corresponding signal quality threshold value and/or a first communication module of the electronic equipment cannot meet the data flow requirement so as to provide the required data flow for the electronic equipment in cooperation with the first communication module;

Wherein the first communication module is of a different type than the second communication module.

8. The method according to claim 1, wherein, in the case that the space where the electronic device is located has a first data traffic signal provided by a first network side and a second data traffic signal provided by a second network side, the target communication module is controlled to establish corresponding communication connection with the first network side and/or the second network side under different communication parameters based on the change information of the data traffic demand and the signal quality of the data traffic signal.

9. The method of claim 5, further comprising at least one of:

acquiring the service condition of data flow signals of each frequency band provided by the network terminal, and controlling the target communication module to adjust the working parameters based on the service condition and the change information of the data flow demand;

acquiring the service condition of data flow signals of each frequency band provided by the network side, and controlling the target communication module to adjust the working parameters based on the service condition, the signal quality and the change information of the data flow requirements;

and monitoring motion data of the electronic equipment, and adjusting working parameters of the target communication module in real time based on the motion data.

10. A control apparatus comprising:

the demand monitoring unit is used for monitoring the data flow demand of the electronic equipment, and the data flow at least enables the electronic equipment to access or load the target data content of the network side;

the parameter control unit is used for controlling the target communication module of the electronic equipment to adjust the working parameters of the target communication module based on the change information of the data flow demand;

the target communication module has different power consumption and/or communication parameters before and after the working parameters are adjusted, and the communication parameters can influence the data flow generated by the electronic equipment.