CN113766611B - Low-power consumption control optimization method and device, mobile terminal and storage medium - Google Patents

Abstract

The application relates to a low-power consumption control optimization method, a low-power consumption control optimization device, a mobile terminal and a storage medium. The method comprises the following steps: the method comprises the steps of monitoring that the mobile terminal is awakened to lighten a screen in a low-power consumption mode; when the mobile terminal is switched from a bright screen state to a dead screen state, acquiring the wake-up time of the mobile terminal in the bright screen state; and when the wake-up time is less than or equal to the preset bright screen time, controlling the mobile terminal to enter a low power consumption mode. By adopting the method, the time for the mobile terminal to enter the low-power consumption mode can be reduced.

Description

Low-power consumption control optimization method and device, mobile terminal and storage medium

Technical Field

The present application relates to the field of mobile terminals, and in particular, to a low power consumption control optimization method, apparatus, mobile terminal, and storage medium.

Background

With the development of mobile terminals, people wake up the battery life of the mobile terminals more and more. In order to prolong the wake-up time of a battery, a power consumption optimization mode of a Doze mechanism introduced by a mobile terminal is used, when equipment is not connected to a power supply and is in an idle state for a long time, a system can enter the Doze state by using the equipment, and the wake-up of a CPU and network activities of an app background of the mobile terminal are delayed.

The traditional Doze mechanism exits the Doze mode after the mobile terminal enters the Doze mode and operates the bright screen in a short time, and the mobile terminal needs to wait for a fixed time period and then reenters the Doze mode, so that the time for the mobile terminal to enter the low-power consumption mode is long.

Disclosure of Invention

In view of the foregoing, it is desirable to provide a low power consumption control optimization method, apparatus, mobile terminal, and storage medium capable of reducing the time for a mobile terminal to enter a low power consumption mode.

A low power consumption control optimization method, the method comprising:

the method comprises the steps of monitoring that the mobile terminal is awakened to lighten a screen in a low-power consumption mode;

when the mobile terminal is switched from a bright screen state to a dead screen state, acquiring the awakening time of the mobile terminal in the bright screen state;

and when the awakening time is smaller than or equal to the preset bright screen time, controlling the mobile terminal to enter the low power consumption mode.

In one embodiment, the method further comprises:

acquiring the current electric quantity of a battery of the mobile terminal, and determining the preset screen-lighting duration of the mobile terminal entering the low-power-consumption mode according to the current electric quantity.

In one embodiment, the low power consumption mode includes a first idle state with slight idle and a second idle state with deep idle, and when the wake-up duration is less than or equal to the preset bright screen duration, controlling the mobile terminal to enter the low power consumption mode includes:

And when the wake-up time is smaller than or equal to the preset bright screen time, controlling the mobile terminal system to enter a second idle state of deep idle of the low power consumption mode.

In one embodiment, the low power mode includes a first idle state that is lightly idle and a second idle state that is deeply idle, the method further comprising:

when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle;

and when the duration that the mobile terminal is in the first idle state is equal to a preset duration, controlling the mobile terminal to enter a second idle state with deep idle.

In one embodiment, the method further comprises:

when the mobile terminal enters the first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state;

when the screen-lighting time is less than or equal to the preset time, controlling the mobile terminal to enter the second idle state;

and when the screen-lighting duration is longer than the preset duration, controlling the mobile terminal to reenter the first idle state.

In one embodiment, the method further comprises:

when the mobile terminal enters the low power consumption mode, acquiring an application of the mobile terminal which is awakened in the bright screen state;

updating a white list corresponding to the low power consumption mode according to the awakened application; the whitelist is a set of applications that are set to run in the background in the low power mode;

and managing each application in the updated white list according to the updated white list.

In one embodiment, the managing each application in the updated whitelist according to the updated whitelist includes:

distributing the application authority of the wake-up lock to each application in the updated white list;

when the duration that each application holds the wake lock is equal to a first preset duration, each application is enabled to release the wake lock and delete each application from the white list.

In one embodiment, the managing each application in the updated whitelist according to the updated whitelist includes:

extending the network access time length of each application in the updated white list;

And when the network access duration is equal to a second preset duration, interrupting access of the applications to the network and deleting the applications from the white list.

A low power consumption control optimization apparatus, the apparatus comprising:

the monitoring module is used for monitoring that the mobile terminal is awakened to be on a screen in a low power consumption mode;

the acquisition module is used for acquiring the awakening time length of the mobile terminal in the bright screen state when the mobile terminal is switched from the bright screen state to the off screen state;

and the control module is used for controlling the mobile terminal to enter the low power consumption mode when the wake-up time length is smaller than or equal to the preset bright screen time length.

A mobile terminal comprising a memory and a processor, the memory storing a computer program, the processor implementing the following steps when executing the computer program:

the method comprises the steps of monitoring that the mobile terminal is awakened to lighten a screen in a low-power consumption mode;

when the mobile terminal is switched from a bright screen state to a dead screen state, acquiring the awakening time of the mobile terminal in the bright screen state;

and when the awakening time is smaller than or equal to the preset bright screen time, controlling the mobile terminal to enter the low power consumption mode.

A computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps of:

the method comprises the steps of monitoring that the mobile terminal is awakened to lighten a screen in a low-power consumption mode;

when the mobile terminal is switched from a bright screen state to a dead screen state, acquiring the awakening time of the mobile terminal in the bright screen state;

and when the awakening time is smaller than or equal to the preset bright screen time, controlling the mobile terminal to enter the low power consumption mode.

According to the low-power-consumption control optimization method, the low-power-consumption control optimization device, the mobile terminal and the storage medium, when the mobile terminal is monitored to wake up the bright screen in the low-power-consumption mode, the wake-up time of the mobile terminal in the bright screen state is acquired when the mobile terminal is switched from the bright screen state to the off screen state; comparing the wake-up time length of the mobile terminal which is wakened up to the bright screen with the preset bright screen time length in the low power consumption mode, and controlling the mobile terminal to enter the low power consumption mode when the wake-up time length is smaller than or equal to the preset bright screen time length; the mobile terminal is operated in a short time, and can enter the low-power-consumption mode without waiting for a set time, so that the time period for the mobile terminal to enter the low-power-consumption mode is shortened, and the energy consumption of the mobile terminal is further reduced.

Drawings

FIG. 1 is a flow chart of a low power consumption control optimization method in one embodiment;

FIG. 2 is a flow chart of a low power consumption control optimization method according to another embodiment;

FIG. 3 is a schematic diagram showing the effect of a low power consumption control optimization method in one embodiment;

FIG. 4 is a schematic diagram illustrating the effect of a low power consumption control optimization method according to another embodiment;

FIG. 5 is a flow chart of a low power consumption control optimization method according to another embodiment;

FIG. 6 is a flow chart of a low power control optimization step in one embodiment;

FIG. 7 is a block diagram of a low power control optimization method in one embodiment;

FIG. 8 is a block diagram of a low power control optimizing apparatus in one embodiment;

FIG. 9 is a block diagram of a low power control optimizing apparatus according to another embodiment;

fig. 10 is an internal structural diagram of a mobile terminal in one embodiment.

Detailed Description

The present application will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present application more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

In one embodiment, as shown in fig. 1, a low power consumption control optimization method is provided, and this embodiment is illustrated by applying the method to a mobile terminal, it can be understood that the method can also be applied to a server, and can also be applied to a system including a mobile terminal and a server, and implemented through interaction between the mobile terminal and the server. In this embodiment, the method includes the steps of:

Step 102, the mobile terminal is monitored to be awakened to be on a screen in a low power consumption mode.

The low power consumption mode refers to that under the condition that the mobile terminal is not connected to a power supply and is not awakened or deactivated for a long time, applications in a non-white list in the mobile terminal are limited to occupy a central processing unit (Central Processing Unit, CPU) and access to a network, so that the purpose of reducing electric quantity consumption is achieved. The white list refers to a set of applications that are set to run in the background in a low power mode; a non-whitelist refers to a collection of applications that are prohibited from running in the background in Doze mode. The low power Mode (Doze Mode) may include Light Idle (Light ild) and Deep Idle (Deep Idle), where Light ild refers to a lightweight limitation, and the mobile terminal may limit network policy, delay JobSchedule and synchronization tasks when entering Light ild; the mobile terminal is larger than the Light Ild limit range in Deep Idle, and entering Deep Idle can limit NetworkPolicy, wakeLock (wake lock), delay JobSchedule, sync task, standard Alarm, and stop WiFi scan. The network policy is a policy for controlling the network connection of the three-party application, and the three-party application cannot access the network under the condition of lower priority of a non-foreground process or a process state or a non-white list; wakeLock is that in a low power consumption mode, an application under the conditions of no foreground process, low priority of a process state or no white list cannot apply; jobSchedule refers to execution after being delayed to leave the low power consumption mode, and normally executed in the low power consumption mode under a white list; alarm refers to delayed response Alarm, with no effect on accurately waking Alarm; wifi scan refers to stopping Wifi scanning.

Specifically, when the sensor of the mobile terminal detects that the mobile terminal wakes up the bright screen from the Doze mode, the mobile terminal exits from the Doze mode. For example, by clicking a bright screen button of the mobile terminal, the mobile terminal receives a bright screen instruction, and controls the mobile terminal to exit from the Doze mode and bright screen.

Step 104, when the mobile terminal is switched from the bright screen state to the off screen state, the wake-up time of the mobile terminal in the bright screen state is obtained.

Specifically, the mobile terminal exits from the low power consumption mode, is turned off after being awakened for a period of time in a bright screen state, is switched to the off screen state, and obtains the awakening time of the mobile terminal in the bright screen state. The mobile terminal entering the off-screen state may be the user triggering an off-screen button on the mobile terminal.

And 106, controlling the mobile terminal to enter a low power consumption mode when the wake-up time is less than or equal to the preset bright screen time.

The preset screen-lighting time is when the screen-lighting time of the mobile terminal reaches the preset time, and the mobile terminal is controlled to enter a low-power consumption mode. The preset screen-lighting time length can also be determined according to the electric quantity of the battery of the mobile terminal, and the preset screen-lighting time length is prolonged along with the reduction of the electric quantity of the battery of the mobile terminal.

Specifically, when the wake-up time of the mobile terminal in the bright screen state is smaller than the preset bright screen time, the mobile terminal is controlled to enter a low power consumption mode, and the network policy, the delay JobSchedule and the like applied in the mobile terminal are limited. Optionally, when the wake-up duration is less than or equal to the preset bright screen duration, controlling the mobile terminal to enter a deep idle second idle state of the low power consumption mode, where the terminal non-white list application is limited by NetworkPolicy, delay JobScheduleWakeLock, jobSchedule, standard Alarm and stop wifi scan.

In the low-power-consumption control optimization method, when the mobile terminal is monitored to wake up the screen in the low-power-consumption mode and is switched from the screen-on state to the screen-off state, the wake-up time length of the mobile terminal in the screen-on state is obtained; comparing the wake-up time length of the mobile terminal which is wakened up to the bright screen with the preset bright screen time length in the low power consumption mode, and controlling the mobile terminal to enter the low power consumption mode when the wake-up time length is smaller than or equal to the preset bright screen time length; the mobile terminal is operated in a short time, and can enter the low-power-consumption mode without waiting for a set time, so that the time period for the mobile terminal to enter the low-power-consumption mode is shortened, and the energy consumption of the mobile terminal is further reduced.

In another embodiment, as shown in fig. 2, a low power consumption control optimization method is provided, and the method is applied to a mobile terminal for illustration, and the method includes the following steps:

step 202, obtaining the current electric quantity of a battery of the mobile terminal, and determining the preset screen-lighting duration of the mobile terminal entering the low-power-consumption mode according to the current electric quantity.

Optionally, the preset screen-lighting duration may be determined according to the electric quantity of the battery of the mobile terminal, where the preset screen-lighting duration is prolonged along with the reduction of the electric quantity of the battery of the mobile terminal. For example, when the electric quantity is smaller than 10 libraries, presetting the screen-lighting duration T to be 5min; when the electric quantity is more than or equal to 10 libraries and less than 20 libraries, presetting the screen-on duration T to be 4min; when the electric quantity is more than or equal to 20 libraries and less than 40 libraries, presetting the screen-on duration T to be 3min; when the electric quantity is more than or equal to 40 libraries and less than 60 libraries, presetting the screen-on duration T to be 2min; when the electric quantity is more than or equal to 60 libraries, the preset screen-lighting duration T is 1min.

Step 204, the mobile terminal is monitored to wake up the bright screen in the low power consumption mode.

And step 206, when the mobile terminal is switched from the bright screen state to the off screen state, acquiring the awakening time length of the mobile terminal in the bright screen state.

The mobile terminal exits the low power consumption mode, is turned off after being awakened for a period of time in a bright screen state, is switched to the off screen state, and obtains the awakening time of the mobile terminal in the bright screen state. For example, the mobile terminal is a mobile phone, the mobile phone is unlocked and exits from a low power consumption mode, the screen is turned off after clicking to view information in the mobile phone, and the duration of viewing the information of the mobile phone is the wake-up duration of the mobile phone in a bright screen state.

And step 208, when the wake-up time is longer than the preset bright screen time, controlling the mobile terminal to enter a first idle state of slight idle.

Specifically, when the mobile terminal exits the low power mode and is awakened by the bright screen, the first idle state when the awakening time is longer than the preset bright screen time refers to when the mobile terminal enters the light idle state, and the non-white list application is limited to awaken NetworkPolicy, jobSchedule and synchronize tasks.

Step 210, controlling the mobile terminal to enter a second idle state with deep idle when the duration of the mobile terminal in the first idle state is equal to the preset duration.

The preset duration is a duration from a first idle state of light idle to a second idle state of deep idle, and is shorter than a duration from the first idle state of light idle to the second idle state of deep idle in the native Doze mode. For example, the duration from the first idle state of light idle to the second idle state of deep idle in the native Doze mode is 2min, and the preset duration is 1min.

Specifically, when the duration of the mobile terminal in the first idle state is equal to the preset duration, the mobile terminal is controlled to enter a deep idle second idle state from the first idle state of the low power consumption mode, and JobSchedule, a delay standard Alarm, a synchronous task and a wifi scan applied in a non-white list are limited. As shown in fig. 3, when the mobile terminal is awakened to be on screen in the low power consumption mode, when the awakening time is less than or equal to the preset on screen time, controlling the mobile terminal to enter a deep idle second idle state of the low power consumption mode, and in the original low power consumption mode, the mobile terminal first enters the slight idle second idle state of the low power consumption mode and then enters the deep idle second idle state; when the wake-up time is longer than the preset bright screen time, the mobile terminal is controlled to enter a first idle state with slight idle, when the time of the mobile terminal in the first idle state is equal to the preset time, the mobile terminal is controlled to enter a second idle state with deep idle, and the preset time is shorter than the time of entering the second idle state with deep idle from the first idle state with slight idle in the original low power consumption mode.

In one embodiment, when the mobile terminal enters a first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state; when the screen-lighting time is less than or equal to the preset time, controlling the mobile terminal to enter a second idle state; and when the screen-lighting time is longer than the preset time, controlling the mobile terminal to reenter the first idle state. As shown in fig. 4, in the original low power mode, the mobile terminal wakes up the bright screen in the first idle state, and needs to reenter the second idle state of the low power mode, which is slightly idle, and then reenters the second idle state of deep idle. When the mobile terminal enters a first idle state, the mobile terminal enters a second idle state from the first idle state when the screen-lighting time of the mobile terminal in the first idle state is less than the preset time, so that the time period of the mobile terminal entering the second idle state is shortened, the mobile terminal rapidly enters the second idle state, the current is reduced, the power consumption loss of the mobile terminal is reduced, and the wake-up service life of a mobile terminal battery is prolonged.

In another embodiment, as shown in fig. 5, a low power consumption control optimization method is provided, and the method is applied to a mobile terminal for illustration, and in this embodiment, the method includes the following steps:

step 502, when the mobile terminal enters a low power consumption mode, acquiring an application of the mobile terminal which is awakened in a bright screen state.

Alternatively, the Application that the mobile terminal is awakened in the bright screen state may be an Application program (Application), a Light Application (Light APP), etc., where the Light Application is an Application program that is ready to use without downloading, such as an applet; the application may be a communication application, an office application, or a reading application, etc.

Step 504, updating a white list corresponding to the low power consumption mode according to the awakened application; a whitelist is a collection of applications that are set to run in the background in a low power mode.

And step 506, managing each application in the updated white list according to the updated white list.

Specifically, the application awakened in the bright screen state is added to a white list of the mobile terminal, the application awakened in the bright screen state in the white list is delayed, and actions such as access network, authority of application WakeLock, timed awakening and the like of each application in the updated white list are delayed and managed.

Optionally, managing each application in the updated whitelist according to the updated whitelist includes: the application authority of the wake-up lock is distributed to each application in the updated white list; when the duration of each application holding the wake-up lock is equal to the first preset duration, releasing the wake-up lock by each application and deleting each application from the white list. For example, applications that wake up in the bright screen state include an a application and a B application, and the a application and the B application are added to the white list, and action permissions of the a application and the B application are limited by a delay. For example, in the low power consumption mode, the permission of the application a for Wake Lock is limited by delaying for 30min, i.e. the application a can continue to apply for acquiring Wake Lock within 30 min; the alarm is set again, the application a is removed from the white list after 30min, and the limitation rule of Wake Lock is updated. By adding the application awakened in the bright screen state into the white list, delay limiting permission is given to the application awakened in the bright screen state, data delay and data loss caused by the fact that the mobile terminal rapidly enters a low-power mode are avoided, and normal awakening of the application is ensured.

Optionally, managing each application in the updated whitelist according to the updated whitelist includes: prolonging the network access time length of each application in the updated white list; and when the network access time is equal to the second preset time, interrupting the access of each application to the network and deleting each application from the white list. For example, the application awakened by the mobile terminal in the bright screen state is added into the white list, when the application awakened by the mobile terminal in the bright screen state is in the low power consumption mode, the network policy of the operating system in the mobile terminal is updated, the network access duration of each application in the updated white list is prolonged, for example, the length of time of each application is prolonged by 5 minutes, alarm is set, after 5 minutes, the application awakened by the mobile terminal in the bright screen state is deleted from the white list, and the network policy is updated. By adding the application awakened in the bright screen state into the white list, delay limiting permission is given to the application awakened in the bright screen state, data delay and data loss caused by the fact that the mobile terminal rapidly enters a low-power mode are avoided, and normal awakening of the application is ensured.

In the low-power consumption control optimization method, when the mobile terminal enters a low-power consumption mode, the application of the mobile terminal which is awakened in a bright screen state is acquired; updating a white list corresponding to the low power consumption mode according to the awakened application; the whitelist is a collection of applications that are set to run in the background in a low power mode; and managing each application in the updated white list according to the updated white list. Namely, after the mobile terminal enters the low power consumption mode, the application which is awakened in the bright screen state is added into the white list, so that delay limiting permission of the application which is awakened in the bright screen state is given, data delay and data loss caused by the fact that the mobile terminal rapidly enters the low power consumption mode are avoided, data timeliness and integrity are guaranteed, and normal awakening of the application is guaranteed.

In one embodiment, as shown in fig. 6, a low power consumption control optimization step is provided, and this embodiment is applied to a mobile terminal for illustration, and this embodiment includes the following steps:

step 602, when the mobile terminal is switched from the bright screen state to the off screen state, acquiring the wake-up time of the mobile terminal in the bright screen state.

Step 604, determining whether the wake-up duration is longer than the preset bright screen duration, if not, executing step 606, otherwise, executing step 608.

The preset screen-lighting duration is determined according to the current electric quantity of the battery of the mobile terminal.

Step 606, controlling the mobile terminal to enter a deep idle state.

In step 608, the mobile terminal is controlled to enter a first idle state with slight idle.

Step 610, it is determined whether the mobile terminal is lit in the first idle state with slight idle, if yes, step 614 is performed, otherwise step 612 is performed.

In step 612, when the duration of the mobile terminal in the first idle state is equal to the preset duration, the mobile terminal is controlled to enter a second idle state with deep idle.

Step 614, obtaining the screen-on duration of the mobile terminal in the first idle state.

Step 616, determining whether the duration of the screen brightness is greater than the preset duration, if yes, executing step 618, otherwise, executing step 606.

In step 618, the mobile terminal is controlled to reenter the first idle state of the slight idle.

In the low-power-consumption control optimization step, the preset screen-lighting time length of the mobile terminal entering the low-power-consumption mode is determined according to the current electric quantity by acquiring the current electric quantity of the battery of the mobile terminal; when the mobile terminal is monitored to be awakened to a bright screen in a low power consumption mode, acquiring the awakening time length of the mobile terminal in the bright screen state when the mobile terminal is switched from the bright screen state to the off screen state; the low power consumption mode comprises a first idle state with slight idle and a second idle state with deep idle, and when the awakening time is less than or equal to the preset screen-lighting time, the mobile terminal system is controlled to enter the second idle state with deep idle in the low power consumption mode; when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle; and when the duration of the mobile terminal in the first idle state is equal to the preset duration, controlling the mobile terminal to enter a second idle state of deep idle. When the mobile terminal enters a first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state; when the screen-lighting time is less than or equal to the preset time, controlling an operating system of the mobile terminal to enter a second idle state; and when the screen-lighting time is longer than the preset time, controlling the mobile terminal to reenter the first idle state. The time period of the mobile terminal entering the low power consumption mode is shortened, the mobile terminal is enabled to enter the low power consumption mode quickly, the current is reduced, the power consumption loss of the mobile terminal is reduced, and the awakening life of the battery of the mobile terminal is prolonged.

In one embodiment, as shown in fig. 7, a structure diagram of a low power consumption control optimization method is provided, and the embodiment is applied to a mobile terminal for illustration by the method, where the structure diagram of the low power consumption control optimization method includes a low power consumption control function, a device idle state monitoring function, a power management service function and a network policy management function; for example, the low power control function is smartdoze.java, the device idle state monitoring function is deviceidleController.java, the power management service function is powermanager service.java, and the network policy management function is networkpolicy manager service.java.

The method comprises the steps that when the mobile terminal is monitored to be awakened to be on a screen in a low power consumption mode, when the mobile terminal is switched from the on-screen state to the off-screen state, the awakening time of the mobile terminal in the on-screen state is obtained, whether the awakening time is longer than the preset on-screen time or not is judged through a low power consumption control function SmartDoze.java, and when the awakening time is shorter than or equal to the preset on-screen time, the mobile terminal is controlled to enter a second idle state of deep idle of the low power consumption mode; when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle; when the duration of the mobile terminal in the first idle state is equal to the preset duration, controlling the mobile terminal to enter a second idle state of deep idle; when the mobile terminal enters a low power consumption mode, the equipment idle state monitoring function is DeviceIdleController.Java, the application of the mobile terminal which is awakened in a bright screen state is obtained, a white list corresponding to the low power consumption mode is updated according to the awakened application, the updated white list is sent to a low power consumption control function SmartDoze.Java, the low power consumption control function SmartDoze.Java sends the updated white list to the equipment idle state monitoring function to be DeviceIdleController.Java and the power management service function to be PowerManagerService.Java, and DeviceIdleController.Java and PowerManagerService.Java are called through interfaces; powerManagerService java is mainly used for controlling whether Wake Lock needs to be limited, after receiving a white list transmitted by SmartDoze.java, entering a low power consumption mode, not limiting the authority of each application WakeLock in the white list, setting alarm again, removing the application awakened in the bright screen state in the white list after 30min, and updating the limiting rule of the Wake Lock; the network policy manager service.java is used for controlling the network policy, after receiving the white list transmitted by SmartDoze.java, updating the network policy of the operating system in the mobile terminal, prolonging the network access duration of each application in the updated white list, if prolonging 5min, setting alarm, deleting the application awakened in the bright screen state from the white list after 5min, and updating the network policy. The mobile terminal is operated in a short time, so that the time period for the mobile terminal to enter a low-power consumption mode is shortened, and the energy consumption of the mobile terminal is further reduced; and ensures the normal wake-up of the application within a certain period of time after entering the low power mode.

In one embodiment, a preset screen-lighting duration of the mobile terminal entering a low-power mode is determined according to the current electric quantity by acquiring the current electric quantity of a battery of the mobile terminal; when the mobile terminal is monitored to be awakened to a bright screen in a low power consumption mode, acquiring the awakening time length of the mobile terminal in the bright screen state when the mobile terminal is switched from the bright screen state to the off screen state; the low power consumption mode comprises a first idle state with slight idle and a second idle state with deep idle, and when the awakening time is less than or equal to the preset screen-lighting time, the mobile terminal system is controlled to enter the second idle state with deep idle in the low power consumption mode; when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle; and when the duration of the mobile terminal in the first idle state is equal to the preset duration, controlling the mobile terminal to enter a second idle state of deep idle. When the mobile terminal enters a first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state; when the screen-lighting time is less than or equal to the preset time, controlling an operating system of the mobile terminal to enter a second idle state; and when the screen-lighting time is longer than the preset time, controlling the mobile terminal to reenter the first idle state.

When the mobile terminal enters a low power consumption mode, acquiring an application of the mobile terminal which is awakened in a bright screen state; updating a white list corresponding to the low power consumption mode according to the awakened application, wherein the white list is a set of applications which are set to run in the background in the low power consumption mode; and managing each application in the updated white list according to the updated white list. Wherein, according to the updated white list, managing each application in the updated white list includes: the application authority of the wake-up lock is distributed to each application in the updated white list, and when the duration of each application holding the wake-up lock is equal to the first preset duration, each application releases the wake-up lock and deletes each application from the white list; prolonging the network access time length of each application in the updated white list; and when the network access time is equal to the second preset time, interrupting the access of each application to the network and deleting each application from the white list. The mobile terminal is operated in a short time, and can enter a low power consumption mode without waiting for a set time, so that the time period for the mobile terminal to enter the low power consumption mode is shortened, and the energy consumption of the mobile terminal is further reduced; and by adding the application which is awakened in the bright screen state to the white list, the delay limiting authority of the application which is awakened in the bright screen state is given, so that the data delay and the data loss caused by the mobile terminal rapidly entering the low power consumption mode are avoided, and the normal awakening of the application is ensured.

It should be understood that, although the steps in the flowcharts of fig. 1-2 and 5-7 are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited to the order of execution unless explicitly recited herein, and the steps may be executed in other orders. Moreover, at least a portion of the steps of fig. 1-2, 5-7 may include multiple steps or stages that are not necessarily performed at the same time, but may be performed at different times, nor does the order in which the steps or stages are performed necessarily occur sequentially, but may be performed alternately or alternately with other steps or at least a portion of the steps or stages in other steps.

In one embodiment, as shown in fig. 8, there is provided a low power consumption control optimizing apparatus, comprising: a monitoring module 802, an acquisition module 804, and a control module 806, wherein:

a monitoring module 802, configured to monitor that the mobile terminal is awakened to light a screen in a low power consumption mode;

an obtaining module 804, configured to obtain a wake-up duration of the mobile terminal in the on-screen state when the mobile terminal is switched from the on-screen state to the off-screen state;

And a control module 806, configured to control the mobile terminal to enter the low power consumption mode when the wake-up duration is less than or equal to the preset bright screen duration.

In the low-power-consumption control optimizing device, when the mobile terminal is monitored to wake up the screen in the low-power-consumption mode and is switched from the screen-on state to the screen-off state, the wake-up time length of the mobile terminal in the screen-on state is obtained; comparing the wake-up time length of the mobile terminal which is wakened up to the bright screen with the preset bright screen time length in the low power consumption mode, and controlling the mobile terminal to enter the low power consumption mode when the wake-up time length is smaller than or equal to the preset bright screen time length; the mobile terminal is operated in a short time, and can enter the low-power-consumption mode without waiting for a set time, so that the time period for the mobile terminal to enter the low-power-consumption mode is shortened, and the energy consumption of the mobile terminal is further reduced.

In another embodiment, as shown in fig. 9, a low power consumption control optimizing apparatus is provided, which includes, in addition to a monitoring module 802, an obtaining module 804, and a control module 806: a determination module 808, an update module 810, a management module 812, an allocation module 814, and a delay module 816, wherein:

The determining module 808 is configured to obtain a current power of the battery of the mobile terminal, and determine a preset screen lighting duration of the mobile terminal entering the low power consumption mode according to the current power.

In one embodiment, the control module 806 is further configured to control the mobile terminal system to enter a second idle state of deep idle in the low power consumption mode when the wake-up duration is less than or equal to the preset bright screen duration;

when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle;

and when the duration of the mobile terminal in the first idle state is equal to the preset duration, controlling the mobile terminal to enter a second idle state of deep idle.

In one embodiment, the control module 806 is further configured to obtain a screen lighting duration of the mobile terminal in the first idle state when the mobile terminal enters the first idle state; when the screen-lighting time is less than or equal to the preset time, controlling an operating system of the mobile terminal to enter a second idle state; and when the screen-lighting time is longer than the preset time, controlling the mobile terminal to reenter the first idle state.

In one embodiment, the obtaining module 804 is further configured to obtain, when the mobile terminal enters the low power mode, an application that the mobile terminal wakes up in the on-screen state.

An updating module 810, configured to update the whitelist corresponding to the low power consumption mode according to the awakened application; a whitelist is a collection of applications that are set to run in the background in a low power mode.

In one embodiment, the updating module 810 is further configured to, when the duration of each application holding the wake lock is equal to the first preset duration, cause each application to release the wake lock and delete each application from the whitelist.

In one embodiment, the updating module 810 is further configured to interrupt access to the network by each application and delete each application from the whitelist when the network access duration is equal to the second preset duration.

And the management module 812 is configured to manage each application in the updated whitelist according to the updated whitelist.

The allocation module 814 is configured to allocate the application authority of the wake lock to each application in the updated whitelist.

And a delay module 816, configured to extend the network access duration of each application in the updated whitelist.

In one embodiment, the current electric quantity of the battery of the mobile terminal is obtained through the determining module 808, and the preset screen-lighting duration of the mobile terminal entering the low power consumption mode is determined according to the current electric quantity; the monitoring module 802 monitors that the mobile terminal is awakened to be on-screen in a low power consumption mode, and when the mobile terminal is switched from the on-screen state to the off-screen state, the obtaining module 804 obtains the awakening time of the mobile terminal in the on-screen state; the low power consumption mode comprises a first idle state with slight idle and a second idle state with deep idle, and when the wake-up time is less than or equal to the preset screen-on time, the control module 806 controls the mobile terminal system to enter the second idle state with deep idle in the low power consumption mode; when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle; when the duration of the mobile terminal in the first idle state is equal to the preset duration, the control module 806 controls the mobile terminal to enter a second idle state of deep idle. When the mobile terminal enters a first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state; when the duration of the bright screen is less than or equal to the preset duration, the control module 806 controls the operating system of the mobile terminal to enter a second idle state; when the duration of the bright screen is greater than the preset duration, the control module 806 controls the mobile terminal to reenter the first idle state.

When the mobile terminal enters a low power consumption mode, an acquisition module 804 acquires an application of the mobile terminal which is awakened in a bright screen state; the updating module 810 updates a white list corresponding to the low power mode according to the awakened application, wherein the white list is a set of applications which are set to run in the background in the low power mode; the management module 812 manages each application in the updated whitelist according to the updated whitelist. Wherein, according to the updated white list, managing each application in the updated white list includes: the allocation module 814 allocates the application authority of the wake lock to each application in the updated whitelist, and when the duration that each application holds the wake lock is equal to the first preset duration, the update module 810 causes each application to release the wake lock and delete each application from the whitelist; the delay module 816 extends the network access duration of each application in the updated whitelist; when the network access duration is equal to the second preset duration, the update module 810 interrupts access of each application to the network and deletes each application from the whitelist. The mobile terminal is operated in a short time, and can enter a low power consumption mode without waiting for a set time length, so that the energy consumption of the mobile terminal is reduced; by adding the application awakened in the bright screen state into the white list, delay limiting permission is given to the application awakened in the bright screen state, data delay and data loss caused by the fact that the mobile terminal rapidly enters a low-power mode are avoided, and normal awakening of the application is ensured.

For specific limitations of the low power consumption control optimizing apparatus, reference may be made to the above limitations of the low power consumption control optimizing method, and no further description is given here. The above-described respective modules in the low power consumption control optimizing apparatus may be realized in whole or in part by software, hardware, and a combination thereof. The above modules may be embedded in hardware or independent of a processor in the mobile terminal, or may be stored in software in a memory in the mobile terminal, so that the processor may call and execute operations corresponding to the above modules.

In one embodiment, a mobile terminal is provided, an internal structure of which may be as shown in fig. 10. The mobile terminal includes a processor, a memory, a communication interface, a display screen, and an input device connected by a system bus. Wherein the processor of the mobile terminal is configured to provide computing and control capabilities. The memory of the mobile terminal comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The communication interface of the mobile terminal is used for carrying out wired or wireless communication with an external terminal, and the wireless mode can be realized through WIFI, an operator network, NFC (near field communication) or other technologies. The computer program, when executed by a processor, implements a low power consumption control optimization method. The display screen of the mobile terminal can be a liquid crystal display screen or an electronic ink display screen, and the input device of the mobile terminal can be a touch layer covered on the display screen, can also be keys, a track ball or a touch pad arranged on the shell of the mobile terminal, and can also be an external keyboard, a touch pad or a mouse and the like.

It will be appreciated by persons skilled in the art that the architecture shown in fig. 10 is merely a block diagram of some of the architecture associated with the present inventive arrangements and is not limiting of the mobile terminal to which the present inventive arrangements are applied, and that a particular mobile terminal may include more or fewer components than shown, or may combine some of the components, or have a different arrangement of components.

In one embodiment, a mobile terminal is provided, comprising a memory and a processor, the memory storing a computer program, the processor implementing the following steps when executing the computer program:

the method comprises the steps of monitoring that the mobile terminal is awakened to lighten a screen in a low-power consumption mode;

when the mobile terminal is switched from a bright screen state to a dead screen state, acquiring the wake-up time of the mobile terminal in the bright screen state;

and when the wake-up time is less than or equal to the preset bright screen time, controlling the mobile terminal to enter a low power consumption mode.

In one embodiment, the processor when executing the computer program further performs the steps of:

the method comprises the steps of obtaining the current electric quantity of a battery of the mobile terminal, and determining the preset screen-lighting duration of the mobile terminal entering the low-power-consumption mode according to the current electric quantity.

In one embodiment, the processor when executing the computer program further performs the steps of:

The low power consumption mode comprises a first idle state with slight idle and a second idle state with deep idle;

and when the wake-up time is less than or equal to the preset bright screen time, controlling the mobile terminal system to enter a deep idle second idle state of the low power consumption mode.

In one embodiment, the processor when executing the computer program further performs the steps of:

when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle;

and when the duration of the mobile terminal in the first idle state is equal to the preset duration, controlling the mobile terminal to enter a second idle state of deep idle.

In one embodiment, the processor when executing the computer program further performs the steps of:

when the mobile terminal enters a first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state;

when the screen-lighting time is less than or equal to the preset time, controlling the mobile terminal to enter a second idle state;

and when the screen-lighting time is longer than the preset time, controlling the mobile terminal to reenter the first idle state.

In one embodiment, the processor when executing the computer program further performs the steps of:

when the mobile terminal enters a low power consumption mode, acquiring an application of the mobile terminal which is awakened in a bright screen state;

Updating a white list corresponding to the low power consumption mode according to the awakened application; the whitelist is a collection of applications that are set to run in the background in a low power mode;

and managing each application in the updated white list according to the updated white list.

In one embodiment, the processor when executing the computer program further performs the steps of:

the application authority of the wake-up lock is distributed to each application in the updated white list;

when the duration of each application holding the wake-up lock is equal to the first preset duration, releasing the wake-up lock by each application and deleting each application from the white list.

In one embodiment, the processor when executing the computer program further performs the steps of:

prolonging the network access time length of each application in the updated white list;

and when the network access time is equal to the second preset time, interrupting the access of each application to the network and deleting each application from the white list.

In one embodiment, a computer readable storage medium is provided having a computer program stored thereon, which when executed by a processor, performs the steps of:

the method comprises the steps of monitoring that the mobile terminal is awakened to lighten a screen in a low-power consumption mode;

when the mobile terminal is switched from a bright screen state to a dead screen state, acquiring the wake-up time of the mobile terminal in the bright screen state;

And when the wake-up time is less than or equal to the preset bright screen time, controlling the mobile terminal to enter a low power consumption mode.

In one embodiment, the computer program when executed by the processor further performs the steps of:

the method comprises the steps of obtaining the current electric quantity of a battery of the mobile terminal, and determining the preset screen-lighting duration of the mobile terminal entering the low-power-consumption mode according to the current electric quantity.

In one embodiment, the computer program when executed by the processor further performs the steps of:

the low power consumption mode comprises a first idle state with slight idle and a second idle state with deep idle;

and when the wake-up time is less than or equal to the preset bright screen time, controlling the mobile terminal system to enter a deep idle second idle state of the low power consumption mode.

In one embodiment, the computer program when executed by the processor further performs the steps of:

when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle;

and when the duration of the mobile terminal in the first idle state is equal to the preset duration, controlling the mobile terminal to enter a second idle state of deep idle.

In one embodiment, the computer program when executed by the processor further performs the steps of:

When the mobile terminal enters a first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state;

when the screen-lighting time is less than or equal to the preset time, controlling the mobile terminal to enter a second idle state;

and when the screen-lighting time is longer than the preset time, controlling the mobile terminal to reenter the first idle state.

In one embodiment, the computer program when executed by the processor further performs the steps of:

when the mobile terminal enters a low power consumption mode, acquiring an application of the mobile terminal which is awakened in a bright screen state;

updating a white list corresponding to the low power consumption mode according to the awakened application; the whitelist is a collection of applications that are set to run in the background in a low power mode;

and managing each application in the updated white list according to the updated white list.

In one embodiment, the computer program when executed by the processor further performs the steps of:

the application authority of the wake-up lock is distributed to each application in the updated white list;

when the duration of each application holding the wake-up lock is equal to the first preset duration, releasing the wake-up lock by each application and deleting each application from the white list.

In one embodiment, the computer program when executed by the processor further performs the steps of:

Prolonging the network access time length of each application in the updated white list;

and when the network access time is equal to the second preset time, interrupting the access of each application to the network and deleting each application from the white list.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium that is awakened in embodiments provided herein may include at least one of non-volatile and volatile memory. The nonvolatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, or the like. Volatile memory can include random access memory (Random Access Memory, RAM) or external cache memory. By way of illustration, and not limitation, RAM can be in the form of a variety of forms, such as static random access memory (Static Random Access Memory, SRAM) or dynamic random access memory (Dynamic Random Access Memory, DRAM), and the like.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the application, which are described in detail and are not to be construed as limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (11)

1. A low power consumption control optimization method, the method comprising:

the method comprises the steps of monitoring that the mobile terminal is awakened to lighten a screen in a low-power consumption mode;

when the mobile terminal is switched from a bright screen state to a dead screen state, acquiring the awakening time of the mobile terminal in the bright screen state;

and when the awakening time is less than or equal to the preset screen-lighting time, controlling the mobile terminal to enter a second idle state of deep idle of the low-power consumption mode.

2. The method according to claim 1, wherein the method further comprises:

acquiring the current electric quantity of a battery of the mobile terminal, and determining the preset screen-lighting duration of the mobile terminal entering the low-power-consumption mode according to the current electric quantity.

3. The method of claim 1, wherein the preset light screen duration is extended as the battery level of the mobile terminal is reduced.

4. The method of claim 1, wherein the low power mode comprises a first idle state that is lightly idle and the second idle state that is deeply idle, the method further comprising:

when the awakening time is longer than the preset screen-lighting time, controlling the mobile terminal to enter a first idle state of slight idle;

and when the duration that the mobile terminal is in the first idle state is equal to a preset duration, controlling the mobile terminal to enter a second idle state with deep idle.

5. The method according to claim 4, wherein the method further comprises:

when the mobile terminal enters the first idle state, acquiring the screen-lighting duration of the mobile terminal in the first idle state;

When the screen-lighting time is less than or equal to the preset time, controlling the mobile terminal to enter the second idle state;

and when the screen-lighting duration is longer than the preset duration, controlling the mobile terminal to reenter the first idle state.

6. The method according to any one of claims 1 to 5, further comprising:

when the mobile terminal enters the low power consumption mode, acquiring an application of the mobile terminal which is awakened in the bright screen state;

updating a white list corresponding to the low power consumption mode according to the awakened application; the whitelist is a set of applications that are set to run in the background in the low power mode;

and managing each application in the updated white list according to the updated white list.

7. The method of claim 6, wherein managing applications in the updated whitelist according to the updated whitelist comprises:

distributing the application authority of the wake-up lock to each application in the updated white list;

when the duration that each application holds the wake lock is equal to a first preset duration, each application is enabled to release the wake lock and delete each application from the white list.

8. The method of claim 6, wherein managing applications in the updated whitelist according to the updated whitelist comprises:

extending the network access time length of each application in the updated white list;

and when the network access duration is equal to a second preset duration, interrupting access of the applications to the network and deleting the applications from the white list.

9. A low power consumption control optimizing apparatus, the apparatus comprising:

the monitoring module is used for monitoring that the mobile terminal is awakened to be on a screen in a low-power consumption mode;

the acquisition module is used for acquiring the awakening time length of the mobile terminal in the bright screen state when the mobile terminal is switched from the bright screen state to the off screen state;

and the control module is used for controlling the mobile terminal to enter a second idle state of deep idle of the low-power consumption mode when the wake-up time is smaller than or equal to the preset bright screen time.

10. A mobile terminal comprising a memory and a processor, the memory storing a computer program, characterized in that the processor implements the steps of the method of any of claims 1 to 8 when the computer program is executed.

11. A computer readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the steps of the method of any of claims 1 to 8.