CN113472940A - Mobile terminal optimization processing method and device based on wearable device and mobile terminal - Google Patents

Abstract

The invention discloses a mobile terminal optimization processing method and device based on wearable equipment, a mobile terminal and a storage medium, wherein the method comprises the following steps: detecting whether the mobile terminal is connected with the wearable device; when the wearable equipment is connected and a screen-off event instruction is received, detecting whether the wearable equipment is in a use state; when the mobile terminal is in a use state, the mobile terminal controls to close the screen but does not perform system dormancy; and when the mobile terminal is not in the use state, the mobile terminal controls to close the screen and carry out system dormancy. The method aims to solve the problem that the screen must be on when the mobile terminal is connected with the wearable device for use, so that a user only closes the screen of the mobile terminal to keep the wearable device running normally when using the wearable device and receiving a screen-off event instruction; when the wearable device is not used and a screen-off event instruction is received, the screen of the mobile terminal is closed and the system is controlled to sleep, so that the power consumption of the system is further reduced, the service time of the mobile terminal is prolonged, and the user experience effect is improved.

Description

Mobile terminal optimization processing method and device based on wearable device and mobile terminal

Technical Field

The invention relates to the technical field of mobile terminals, in particular to a mobile terminal optimization processing method and device based on wearable equipment, a mobile terminal and a storage medium.

Background

With the development of science and technology and the continuous improvement of the living standard of people, people are pursuing various new products and new experiences, wherein the intelligent glasses widely known as intelligent wearing equipment or remote sensing equipment specially used for motion sensing games, such as Google glasses or holographic intelligent glasses specially used for playing motion sensing games are not lacked, most of the intelligent glasses and remote sensing equipment are required to be connected with terminal equipment such as a mobile phone for use, the intelligent glasses and remote sensing equipment can present 3D movie and television works and games in the mobile phone in front of users, and colorful entertainment experiences are provided for the users. However, in the prior art, when part of the wearable devices are connected with a mobile terminal such as smart glasses and remote sensing and connected with a mobile phone, the mobile phone is always in a bright screen state, the service time of the mobile phone is greatly influenced, and the smart glasses and the remote sensing cannot be used after the mobile phone is powered off.

Thus, there is a need for improvements and enhancements in the art.

Disclosure of Invention

The mobile terminal can respond to a screen-off event instruction of the mobile terminal differently according to whether the intelligent device is in a use state or not after being connected with the intelligent device, so that the connected mobile terminal is controlled to be screen-off but not enter a dormant state to enable the wearable device to be normally used when a user uses the wearable device, and the connected mobile terminal is controlled to enter the dormant state while being screen-off when the user detects that the user does not use the wearable device, thereby effectively reducing the power consumption of the mobile terminal and prolonging the operation time.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows:

a mobile terminal optimization processing method based on wearable equipment is disclosed, wherein the method comprises the following steps:

detecting whether the mobile terminal is connected with the wearable device;

when the mobile terminal is connected with the wearable equipment and receives a screen-off triggering event instruction, detecting whether the connected wearable equipment is in a use state;

when the wearable equipment is detected to be in a use state, controlling the response of the mobile terminal to the command for triggering the screen-off event to be that only the screen is controlled to be closed, and protecting the system from being dormant when the system normally operates so as to control the wearable equipment to be normally used when the mobile terminal is in the screen-off state;

when detecting that the mobile terminal is connected with the wearable device and detecting that the wearable device is not in a use state, controlling the response of the mobile terminal to the command triggering the screen-off event to be screen-off and carrying out system dormancy.

The mobile terminal optimization processing method based on the wearable device, wherein the step of detecting whether the mobile terminal is connected with the wearable device comprises the following steps:

the method comprises the steps that whether the wearable equipment is connected with the mobile terminal through a wired or wireless mode is detected by the mobile terminal.

The mobile terminal optimization processing method based on the wearable device, wherein when the mobile terminal is connected with the wearable device and receives a screen-off triggering event instruction, the step of detecting whether the connected wearable device is in a use state comprises the following steps:

the mobile terminal detects whether the connected wearable device is in a use state or not by setting a proximity sensor on the wearable device.

The mobile terminal optimization processing method based on the wearable device, wherein when the mobile terminal is connected with the wearable device and receives a screen-off triggering event instruction, the step of detecting whether the connected wearable device is in a use state comprises the following steps:

when the mobile terminal is connected with the wearable device and receives a screen-off triggering event instruction, whether the connected wearable device is in a desktop mode in a using state is detected.

The mobile terminal optimization processing method based on the wearable device, wherein when the wearable device is detected to be in the in-use state, the mobile terminal is controlled to respond to the command for triggering the screen-off event, only the screen is controlled to be closed, the system is protected from being in a sleep state during normal operation, and the steps of controlling the wearable device to be in a normal use state when the mobile terminal is in the screen-off state include:

when the wearable device is detected to be in the interactive use state with the mobile terminal, the mobile terminal is controlled to respond to the command for triggering the screen-off event, only the screen is controlled to be closed, the system is protected from being in a sleep state during normal operation, and the wearable device can normally use data transmitted by the mobile terminal when the mobile terminal is controlled to be in the screen-off state.

The mobile terminal optimization processing method based on the wearable device, wherein when detecting that the mobile terminal is connected with the wearable device and detecting that the wearable device is not in a use state, the step of controlling the mobile terminal to respond to the command triggering the screen-off event to turn off the screen and perform system dormancy comprises the following steps:

when the fact that the mobile terminal is connected with the wearable device is detected, but the wearable device is detected to be in an out-of-use state without data interaction with the mobile terminal, the mobile terminal is controlled to respond to the command for triggering the screen-off event to be screen-off and the system is in a dormant state.

The mobile terminal optimization processing method based on the wearable device, wherein when detecting that the mobile terminal is connected with the wearable device and detecting that the wearable device is not in a use state, the method comprises the following steps of controlling the response of the mobile terminal to the command for triggering the screen-off event to be screen-off and conducting system dormancy:

when the mobile terminal receives a screen-lightening triggering event instruction, detecting whether the mobile terminal is in a screen-closing and system-keeping running state;

when the mobile terminal is detected to be in a state of closing the screen and keeping the system running, controlling to light the screen;

and controlling the awakening system to light the screen when the mobile terminal is detected to be in a screen closing and system sleeping state.

An apparatus for optimizing a mobile terminal based on a wearable device, wherein the apparatus comprises:

the connection detection module is used for detecting whether the mobile terminal is connected with the wearable device or not;

the mobile terminal comprises a use detection module, a display module and a display module, wherein the use detection module is used for detecting whether the connected wearable equipment is in a use state or not when the mobile terminal is connected with the wearable equipment and receives a screen-off triggering event instruction;

the first screen-off control module is used for controlling the response of the mobile terminal to the command for triggering the screen-off event to be that only the screen is controlled to be closed when the wearable device is detected to be in the in-use state, and protecting the normal operation of the system from dormancy so as to control the wearable device to be normally used when the mobile terminal is in the screen-off state;

the second screen-off control module is used for controlling the response of the mobile terminal to the screen-off event triggering instruction to be screen-off and carrying out system dormancy when detecting that the mobile terminal is connected with the wearable device and detecting that the wearable device is not in a use state;

the screen-off detection module is used for detecting whether a system of the mobile terminal for closing the screen is in an operating state;

and the screen lightening control module is used for controlling the screen to be lightened when the system for closing the screen is detected to be in the running state, and controlling the system for awakening to lighten the screen when the system for closing the screen is detected to be in the dormant state.

A mobile terminal comprises a memory, a processor and an image display program which is stored in the memory and can run on the processor, wherein when the processor executes the image display program, the steps of any one of the wearable device-based mobile terminal optimization processing methods are realized.

A computer readable storage medium, wherein the computer readable storage medium stores thereon an image display program, which when executed by a processor, implements the steps of any one of the wearable device-based mobile terminal optimization processing methods.

Has the advantages that: compared with the prior art, the mobile terminal optimization processing method based on the wearable device can set the mobile terminal to respond to the screen-off event instruction to only close the screen and not to sleep or to sleep while closing the screen according to the use state of the wearable device after the mobile terminal is connected with the wearable device. The mobile terminal reduces the use power consumption when using the wearable device, prolongs the running time and improves the use experience of the user.

Drawings

Fig. 1 is a flowchart of a specific implementation of a wearable device-based mobile terminal optimization processing method according to an embodiment of the present invention.

Fig. 2 is a schematic flow chart illustrating detecting whether a mobile terminal is connected to a wearable device according to an embodiment of the present invention.

Fig. 3 is a schematic flowchart of an in-use state of detecting whether a wearing device is in a desktop mode according to an embodiment of the present invention.

Fig. 4 is a schematic flow chart illustrating a process of controlling a response to a command for triggering a screen-off event to only control a screen to be turned off to keep a system operating normally when the wearable device is in a use state according to an embodiment of the present invention.

Fig. 5 is a schematic flow chart illustrating a process of controlling the screen to be turned off and causing the system to sleep in response to the command for triggering the screen-off event when the wearable device is not in the use state according to the embodiment of the present invention.

Fig. 6 is a schematic flow chart according to a second embodiment of the present invention.

Fig. 7 is a schematic block diagram of a wearable device-based mobile terminal optimization processing apparatus according to an embodiment of the present invention.

Fig. 8 is a schematic diagram of an internal structure of a terminal device according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and effects of the present invention clearer and clearer, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

Along with the development of science and technology and the continuous improvement of people's standard of living, the intelligent wearing equipment of diversified appears in succession, including the intelligent bracelet that can real-time supervision human health, can provide 3D recreation experience and 3D and see the intelligent glasses that shadow experience was experienced, even can tie up the intelligent sports shoes of shoelace automatically in addition.

The intelligent wearable devices have the common point that the intelligent wearable devices need to be connected with the mobile terminal, but some wearable devices depend on the mobile terminal in the using process, the wearable devices can normally operate only when the mobile terminal is kept in a bright screen state in the using process, the mobile terminal cannot continue to provide services for a user when the mobile terminal touches a screen-off event instruction and performs screen-off, but long-time bright screen of the mobile terminal can lead to high power consumption of the mobile terminal, the service time of the mobile terminal and the wearable devices is shortened, and poor using experience is brought to the user.

In order to solve the above problems, embodiments of the present invention provide a mobile terminal optimization processing method based on a wearable device, which can automatically identify whether the wearable device is in a use state, and if the mobile terminal detects that the wearable device is in the use state and receives a screen-off event instruction, only control to close a screen and protect a system from normal operation without hibernation, so as to control the wearable device to be normally used when the mobile terminal is in the screen-off state; and if the mobile terminal detects that the wearable device is not in the using state and simultaneously receives the screen-off event instruction, controlling to close the screen and making the system sleep. The power consumption of the mobile terminal is reduced when the user uses the wearable device, the service life is prolonged, and the use experience of the user is improved.

Exemplary method

First embodiment

As shown in fig. 1, an embodiment of the present invention provides a wearable device-based mobile terminal optimization processing method, which can be used in mobile devices such as a mobile phone, a tablet computer, and a notebook computer. The method in the embodiment of the invention comprises the following steps:

s100, detecting whether the mobile terminal is connected with the wearable device;

in the embodiment, before the system is judged to be on or off, whether the mobile terminal is connected with the wearable device needs to be detected, when no wearable device is connected with the mobile terminal, the mobile terminal keeps the original on or off screen logic, and when the wearable device is connected with the mobile terminal, the running state of the system is controlled when the mobile terminal is turned on or off according to the new on or off screen logic.

Specifically, as shown in fig. 2, the step S100 includes:

step S101, detecting whether the wearable equipment is connected with the mobile terminal through a wire or a wireless mode by the mobile terminal.

For example, the user may connect with the wearable device in a wired or wireless manner, for example, when using the smart wearable watch, the mobile phone uses bluetooth to connect wirelessly; when playing 3D games or watching 3D movies using VR/AR glasses, a wired connection is generally required to guarantee the user's use experience because of the large transmission content. The mobile phone detects whether wired or wireless connection from the wearable device exists through a wired interface of the mobile phone, such as a type-C interface, an apple Lightning interface or a wireless port, such as a Bluetooth port or a WIFI port, before the screen on/off state is controlled.

Further, step S200, when the mobile terminal is connected with the wearable device and receives a screen-off triggering event instruction, detecting whether the connected wearable device is in a use state;

in this embodiment, when it is detected that the mobile terminal is connected to the wearable device and simultaneously receives a command for triggering a screen-off event, it is further detected whether the connected wearable device is in a use state.

Specifically, as shown in fig. 3, step S200 includes:

step S201, when the mobile terminal is connected with the wearable device and receives a screen-off triggering event instruction, detecting whether the connected wearable device is in a desktop mode in a using state.

The mobile terminal detects whether the connected wearable device is in a use state or not by setting a proximity sensor on the wearable device.

For example, when a user receives a screen-off event instruction while playing a 3D game using a mobile phone screen-casting and remote sensing device, for example, the user sets that the mobile phone has no touch screen operation within five minutes to automatically turn off the screen or actively presses a screen-off side key of the mobile phone, the mobile phone further determines whether the connected wearable device is in a use state. For example, whether the wearable device is in a desktop mode in a using state is detected, that is, whether a user operates remote sensing to generate data interaction between the mobile phone and the remote sensing device is judged. The desktop mode is not an operation interface of the mobile phone, but an operation interface appeared after the wearable device is connected with the mobile phone, can be independently controlled with an operation interface of the mobile phone respectively, and is widely applied to wearable devices such as VR/AR glasses.

Another method for detecting whether the user is using the wearable device may be to set a proximity sensor, such as a human infrared sensor or a radar, on the wearable device, when a sensor, such as the human infrared sensor or the radar, which can detect human body signs detects that a person is within 0.3 m of the wearable device, it is determined that the wearable device is in a use state, or detect according to a sensor carried by the wearable device, for example, when a sensor, such as remote sensing, is in a use state, data of an MEMS sensor of the wearable device is always in a change state, and when the remote sensing is not in the use state, the wearable device is generally in a still state, so whether the wearable device is in the use state can be detected through whether data of the sensor carried by the wearable device is changed.

Further, step S300, when it is detected that the wearable device is in the in-use state, controlling the mobile terminal to respond to the command for triggering the screen-off event so as to only control the screen to be turned off, and protecting the system from being in normal operation and not sleeping, so as to control the wearable device to be in normal use when the mobile terminal is in the screen-off state;

in this embodiment, when detecting that wearing equipment is in the user state, control mobile terminal only closes the screen and does not carry out the system dormancy, guarantee that mobile terminal and wearing equipment carry out data interaction, make mobile terminal still can use wearing equipment after the screen goes out, reach the purpose that reduces the consumption.

Specifically, as shown in fig. 4, step S300 includes:

step S301, when the wearable device is detected to be in a use state interacting with the mobile terminal, controlling the mobile terminal to respond to the command for triggering the screen-off event to only control the screen to be closed, and protecting the system from being in a normal operation and not in a dormant state so as to control the wearable device to normally use data transmitted by the mobile terminal when the mobile terminal is in the screen-off state.

For example, when it is detected that a user is playing a 3D game using a mobile phone for screen projection and remote sensing equipment and continuously generates data interaction with a mobile terminal, according to the automatic screen-off time preset by the user, the mobile phone receives a screen-off triggering instruction because the mobile phone is not operated for 5 minutes, and then the mobile phone controls the screen-off operation to only close the screen without keeping the mobile phone system running to enter a dormant state, and at this time, the mobile phone screen is closed, but the user can still play the 3D game using the mobile phone for screen projection and remote sensing equipment, so that the power consumption of the mobile terminal is reduced while the user plays the game using remote sensing, and the purposes of saving energy and prolonging the service time are achieved.

Further, in step S400, when it is detected that the mobile terminal is connected to the wearable device and it is detected that the wearable device is not in a use state, the mobile terminal is controlled to respond to the command for triggering the screen-off event as screen-off and the system is in a sleep mode.

In this embodiment, when the mobile terminal detects that the wearable device is connected but detects that the wearable device is not in a use state, the mobile terminal controls the screen to be turned off and enables the system to enter a sleep state when receiving a trigger screen turn-off event instruction, so that the mobile terminal can further save power consumption when the user does not use the wearable device.

Specifically, as shown in fig. 5, step S400 includes:

step S401, when it is detected that the mobile terminal is connected with the wearable device but the wearable device is detected to be in an out-of-use state without data interaction with the mobile terminal, controlling the response of the mobile terminal to the command for triggering the screen-off event to be screen-off and conducting system dormancy.

For example, when the user needs to leave because of an emergency, the remote sensing device is put down, and the screen-off side key is pressed on the mobile phone in the bright screen state. At the moment, the mobile terminal detects that the remote sensing equipment is connected, but the user takes off the remote sensing equipment, and when the human body infrared sensor detects that the user does not use the remote sensing equipment, the mobile phone responds to the command for triggering the screen-off event by closing the screen of the mobile phone and enabling the system to be dormant, and at the moment, data interaction between the mobile phone and the remote sensing equipment is not generated any more, so that the aim of further saving power consumption is fulfilled.

Further, after the step of detecting that the mobile terminal is connected to the wearable device and detecting that the wearable device is not in a use state, controlling the response of the mobile terminal to the command for triggering the screen-off event to be screen-off and performing system dormancy, the method includes:

when the mobile terminal receives a screen-lightening triggering event instruction, detecting whether the mobile terminal is in a screen-closing and system-keeping running state;

when the mobile terminal is detected to be in a state of closing the screen and keeping the system running, controlling to light the screen;

and controlling the awakening system to light the screen when the mobile terminal is detected to be in a screen closing and system sleeping state.

For example, when a user uses a mobile phone to perform a 3D somatosensory game by screen projection and remote sensing, and the mobile phone is automatically turned off but is not dormant due to no operation of the mobile phone for a long time, and receives an incoming call of a friend, the mobile phone detects that the mobile phone is in a state of turning off a screen but the system is in a running state at the moment, and the control screen is directly lighted up, so that the user can control to answer or hang up a call; when a user is connected with the screen projection and remote sensing of the mobile phone but does not play, and the mobile phone is automatically turned off and enters a dormant state because the mobile phone is not operated for a long time, the mobile phone receives an incoming call of a friend, and controls to wake up the system and turn on the screen when detecting that the mobile phone is turned off and the system enters the dormant state at the moment, and the mobile phone enters an operating state from the dormant state. If the mobile phone only wakes up the screen to be bright and the system is not in the running state, the screen is white in backlight, and color patterns are not displayed, namely the mobile phone system.

And finally, when the user uses the wearable device, the connection with the mobile terminal is disconnected, and the response of the mobile terminal to the screen-off event instruction returns to the default state of the system.

The process of the invention is described in further detail below by means of a specific application example:

in this specific application embodiment, the mobile terminal is a mobile phone, and the wearable device is R/VR glasses, as shown in fig. 6, a method for optimizing a mobile terminal based on a wearable device in this specific application embodiment includes the following steps:

s10, inserting the AR/VR glasses into the mobile phone, connecting the AR/VR glasses with the mobile phone, and then entering S11;

step S11, judging whether to process the desktop mode, if yes, entering step S12, and if no, entering step S30;

step S12, registering bright screen monitoring, and entering S13;

in this step, the registration bright screen monitoring is to monitor whether a call is available, and if a call comes from a normal mobile phone in a screen off state, the bright screen can be displayed, and to achieve the same effect, the relevant monitoring is to be registered.

Step S13, triggering screen-off event, and entering step S14;

step S14, whether the trigger is the first time, if yes, the step S15 is carried out, and if no, the step S16 is carried out;

step S15, popping up Toast to prompt user behavior change, and entering step S16;

step S16, judging whether to forbid screen locking, if yes, entering step S18, and if no, entering step S17;

step S17, disabling screen locking and entering S18;

step S18, judging whether the glasses are in use state, if yes, entering S19, and if no, entering S21;

step S19, closing the screen, keeping the system running normally, and entering step S20 or S22 or S23;

step S20, triggering the event that the glasses are not used, and entering S21;

step S21, the system goes to sleep, and goes to step S22 or S23;

step S22, trigger a bright screen event (because of side key), then proceed to step S24;

step S23, triggering a screen-on event (because of an incoming call), and then proceeding to step S24;

step S24, judging whether the system is in the running state of closing the screen and keeping the system, if yes, entering step S25, and if no, entering step S26;

step S25, lighting a screen;

and step S26, waking up the system to light up.

Step S30, the native logic is maintained, and the step S31 is entered;

and step S31, end.

As can be seen from the above, in the specific application embodiment of the present invention, when a user uses other wearable devices, the method may also be used to achieve the effects of reducing power consumption, prolonging the use time, and improving the user experience, as shown in fig. 6, when the user uses AR/VR glasses to watch a 3D movie, the tablet detects that the AR/VR glasses are connected to the tablet through the apple interface, and further determines whether the current AR/VR glasses wearing device is in the desktop mode, and if the AR/VR glasses are in the screen projection mode that is not in the desktop mode at this time, the display content of the AR/VR glasses is the same as the mobile phone operation interface, the native logic is maintained; when the AR/VR glasses are in the desktop mode, screen-on monitoring is registered in advance, wherein the screen-on monitoring comprises monitoring for notifying an incoming call, notifying an app program, turning on a screen by a side key and the like, and the flat panel system is waited to receive a screen-off triggering event.

Judging whether a screen-off instruction is triggered for the first time or not when a screen-off event is triggered by a panel, if so, popping up Toast to prompt a user to change behaviors, wherein the Toast is a common message frame type in app software; if not, further judging whether the system forbids screen locking. The forbidden screen locking is that the screen locking is not directly carried out when the system receives the screen-off event instruction, but the system needs to wait for whether the system is in a dormant state or not when the system judges to close the screen. For example, when the tablet computer is forbidden to lock the screen, whether the AR/VR glasses are in a use state is further judged, and when the AR/VR glasses are judged not to perform data interaction with the tablet computer and not in the use state, the screen is closed and the system enters a sleep state; and when the AR/VR glasses are judged to have data interaction with the tablet, the screen of the AR/VR glasses is closed and the normal operation of the system is kept when the AR/VR glasses are in the use state, and if the AR/VR glasses are changed from the use state to the non-use state in the later use process, the normal operation state of the tablet system is changed into the sleep state when the screen is closed.

Further, when the flat panel closes the screen, if a screen-on event such as an incoming call notification is monitored, whether a system of the flat panel is in an operating state is judged, and if the system is in the operating state, a user can answer or hang up the call by directly lighting the screen; if the system is in a dormant state, the flat panel control lights up the screen and simultaneously wakes up the system, and the user can answer or hang up the call.

Further, after the user answers the phone, the user waits for the next screen-off event instruction, when the user watches the 3D film, the apple data line is pulled out to disconnect the wired connection between the AR/VR glasses and the tablet, the wearing device exits from the desktop mode, and the tablet returns to the default state of the system in response to the screen-off event instruction.

Exemplary device

As shown in fig. 7, an embodiment of the present invention provides a wearable device-based mobile terminal optimization processing apparatus, including: the screen display control system comprises a connection detection module 710, a use detection module 720, a first screen-off control module 730, a second screen-off control module 740, a screen-off detection module 750 and a screen-on control module 760. Specifically, the connection detection module is used for detecting whether the mobile terminal is connected with the wearable device;

the mobile terminal comprises a use detection module, a display module and a display module, wherein the use detection module is used for detecting whether the connected wearable equipment is in a use state or not when the mobile terminal is connected with the wearable equipment and receives a screen-off triggering event instruction; the first screen turn-off control module 710 is configured to, when it is detected that the wearable device is in a screen turn-off state, control the response of the mobile terminal to the command for triggering the screen turn-off event to be only to control the screen to be turned off, and protect the system from being in a normal operation and being dormant, so that the wearable device can be normally used when the mobile terminal is in the screen turn-off state; the second screen-off control module 720 is configured to, when it is detected that the mobile terminal is connected to the wearable device and the wearable device is not in a use state, control the response of the mobile terminal to the command for triggering the screen-off event to be screen-off and perform system dormancy; the screen-off detection module 730 is configured to detect whether a system of the mobile terminal that closes the screen is in an operating state; the screen-lighting control module 740 controls to light the screen when detecting that the system for closing the screen is in the running state, and controls to wake up the system to light the screen when detecting that the system for closing the screen is in the sleeping state. The screen-off detection module 750 is configured to detect whether a system of the mobile terminal that closes the screen is in an operating state; the screen-lighting control module 760 controls to light the screen when detecting that the system for closing the screen is in the running state, and controls to wake up the system to light the screen when detecting that the system for closing the screen is in the sleeping state.

Based on the above embodiments, the present invention further provides a terminal device, and a schematic block diagram thereof may be as shown in fig. 8. The terminal equipment comprises a processor, a memory, a network interface and a display screen which are connected through a system bus. Wherein the processor of the terminal device is configured to provide computing and control capabilities. The memory of the terminal equipment 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 an operating system and computer programs in the non-volatile storage medium. The network interface of the terminal device is used for connecting and communicating with an external terminal through a network. The computer program is executed by a processor to implement a wearable device based mobile terminal optimization process. The display screen of the terminal equipment can be a liquid crystal display screen or an electronic ink display screen.

It will be understood by those skilled in the art that the block diagram in fig. 8 is only a block diagram of a part of the structure related to the solution of the present invention, and does not constitute a limitation to the terminal device to which the solution of the present invention is applied, and a specific terminal device may include more or less components than those in the figure, or combine some components, or have different component arrangements.

In one embodiment, a terminal device is provided, the terminal device includes a memory, a processor, and a wearable device-based mobile terminal optimization processing program stored on and executable on the processor, and the processing executes the following steps:

detecting whether the mobile terminal is connected with the wearable device;

when the mobile terminal is connected with the wearable equipment and receives a screen-off triggering event instruction, detecting whether the connected wearable equipment is in a use state;

when the wearable equipment is detected to be in a use state, controlling the response of the mobile terminal to the command for triggering the screen-off event to be that only the screen is controlled to be closed, and protecting the system from being dormant when the system normally operates so as to control the wearable equipment to be normally used when the mobile terminal is in the screen-off state;

when detecting that the mobile terminal is connected with the wearable device and detecting that the wearable device is not in a use state, controlling the response of the mobile terminal to the command triggering the screen-off event to be screen-off and carrying out system dormancy.

Wherein, whether the step of detecting mobile terminal and connecting wearing equipment includes:

the method comprises the steps that whether the wearable equipment is connected with the mobile terminal through a wired or wireless mode is detected by the mobile terminal.

Wherein, when mobile terminal is connected with wearing equipment and receives and triggers to go out the screen incident instruction, whether the step that detects the wearing equipment who connects is using the state includes:

the mobile terminal detects whether the connected wearable device is in a use state or not by setting a proximity sensor on the wearable device.

Wherein, when mobile terminal is connected with wearing equipment and receives and triggers to go out the screen incident instruction, whether the step that detects the wearing equipment who connects is using the state includes:

when the mobile terminal is connected with the wearable device and receives a screen-off triggering event instruction, whether the connected wearable device is in a desktop mode in a using state is detected.

Wherein, when detecting that wearing equipment is in the user state, then control mobile terminal to trigger the response of going out the screen incident instruction for, only control and close the screen to protection system normal operating does not carry out dormancy, but wearing equipment normal use's step includes when controlling mobile terminal to be in the state of going out the screen:

when the wearable device is detected to be in the interactive use state with the mobile terminal, the mobile terminal is controlled to respond to the command for triggering the screen-off event, only the screen is controlled to be closed, the system is protected from being in a sleep state during normal operation, and the wearable device can normally use data transmitted by the mobile terminal when the mobile terminal is controlled to be in the screen-off state.

Wherein, when detecting that mobile terminal has connected wearing equipment to it is not in user state to detect wearing equipment, then control mobile terminal to the response of triggering the incident instruction of going out the screen for going out the screen and carry out the step of system dormancy and include:

when the fact that the mobile terminal is connected with the wearable device is detected, but the wearable device is detected to be in an out-of-use state without data interaction with the mobile terminal, the mobile terminal is controlled to respond to the command for triggering the screen-off event to be screen-off and the system is in a dormant state.

Wherein, when detecting that mobile terminal has connected wearing equipment to it is not in user state to detect wearing equipment, then control mobile terminal to the response of triggering the incident instruction of going out the screen for going out the screen and carry out the step that the system sleeps and include after:

when the mobile terminal receives a screen-lightening triggering event instruction, detecting whether the mobile terminal is in a screen-closing and system-keeping running state;

when the mobile terminal is detected to be in a state of closing the screen and keeping the system running, controlling to light the screen;

and controlling the awakening system to light the screen when the mobile terminal is detected to be in a screen closing and system sleeping state.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, databases, or other media used in embodiments provided herein may include non-volatile and/or volatile memory. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

In summary, the present invention discloses a method, an apparatus, a mobile terminal and a storage medium for optimizing a mobile terminal based on a wearable device, wherein the method comprises: detecting whether the mobile terminal is connected with the wearable device; when the wearable equipment is connected and a screen-off event instruction is received, detecting whether the wearable equipment is in a use state; when the mobile terminal is in a use state, the mobile terminal controls to close the screen but does not perform system dormancy; and when the mobile terminal is not in the use state, the mobile terminal controls to close the screen and carry out system dormancy. The method aims to solve the problem that the screen must be on when the mobile terminal is connected with the wearable device for use, so that a user only closes the screen of the mobile terminal to keep the wearable device running normally when using the wearable device and receiving a screen-off event instruction; when the wearable device is not used and a screen-off event instruction is received, the screen of the mobile terminal is closed and the system is controlled to sleep, so that the power consumption of the system is further reduced, the service time of the mobile terminal is prolonged, and the user experience effect is improved.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A mobile terminal optimization processing method based on wearable equipment is characterized by comprising the following steps:

detecting whether the mobile terminal is connected with the wearable device;

when the mobile terminal is connected with the wearable equipment and receives a screen-off triggering event instruction, detecting whether the connected wearable equipment is in a use state;

when the wearable equipment is detected to be in a use state, controlling the response of the mobile terminal to the command for triggering the screen-off event to be that only the screen is controlled to be closed, and protecting the system from being dormant when the system normally operates so as to control the wearable equipment to be normally used when the mobile terminal is in the screen-off state;

when detecting that the mobile terminal is connected with the wearable device and detecting that the wearable device is not in a use state, controlling the response of the mobile terminal to the command triggering the screen-off event to be screen-off and carrying out system dormancy.

2. The method for optimizing the mobile terminal based on the wearable device according to claim 1, wherein the step of detecting whether the mobile terminal is connected to the wearable device comprises:

the method comprises the steps that whether the wearable equipment is connected with the mobile terminal through a wired or wireless mode is detected by the mobile terminal.

3. The method for optimizing the mobile terminal based on the wearable device according to claim 1, wherein the step of detecting whether the connected wearable device is in the use state when the mobile terminal is connected with the wearable device and receives the command of triggering the screen-off event comprises:

when the mobile terminal is connected with the wearable device and receives a screen-off triggering event instruction, whether the connected wearable device is in a desktop mode in a using state is detected.

4. The method for optimizing the mobile terminal based on the wearable device according to claim 1, wherein the step of detecting whether the connected wearable device is in the use state when the mobile terminal is connected with the wearable device and receives the command of triggering the screen-off event comprises:

the mobile terminal detects whether the connected wearable device is in a use state or not by setting a proximity sensor on the wearable device.

5. The method for optimizing the mobile terminal based on the wearable device according to claim 1, wherein when the wearable device is detected to be in the in-use state, the step of controlling the response of the mobile terminal to the command for triggering the screen-off event to be only to control the screen to be turned off and to protect the system from normal operation and not to sleep so as to control the wearable device to be normally used when the mobile terminal is in the screen-off state comprises:

when the wearable device is detected to be in the interactive use state with the mobile terminal, the mobile terminal is controlled to respond to the command for triggering the screen-off event, only the screen is controlled to be closed, the system is protected from being in a sleep state during normal operation, and the wearable device can normally use data transmitted by the mobile terminal when the mobile terminal is controlled to be in the screen-off state.

6. The method for optimizing the mobile terminal based on the wearable device according to claim 1, wherein the step of controlling the mobile terminal to respond to the command triggering the screen-off event to turn off the screen and perform the system sleep when detecting that the mobile terminal is connected to the wearable device and detecting that the wearable device is not in the use state comprises:

when the fact that the mobile terminal is connected with the wearable device is detected, but the wearable device is detected to be in an out-of-use state without data interaction with the mobile terminal, the mobile terminal is controlled to respond to the command for triggering the screen-off event to be screen-off and the system is in a dormant state.

7. The method for optimizing the mobile terminal based on the wearable device according to claim 1, wherein after the step of controlling the mobile terminal to respond to the command triggering the screen-off event to turn off the screen and perform the system sleep when detecting that the mobile terminal is connected to the wearable device and detecting that the wearable device is not in the use state, the method comprises:

when the mobile terminal receives a screen-lightening triggering event instruction, detecting whether the mobile terminal is in a screen-closing and system-keeping running state;

when the mobile terminal is detected to be in a state of closing the screen and keeping the system running, controlling to light the screen;

and controlling the awakening system to light the screen when the mobile terminal is detected to be in a screen closing and system sleeping state.

8. The utility model provides a mobile terminal optimal processing device based on wearing equipment which characterized in that, the device includes:

the connection detection module is used for detecting whether the mobile terminal is connected with the wearable device or not;

the mobile terminal comprises a use detection module, a display module and a display module, wherein the use detection module is used for detecting whether the connected wearable equipment is in a use state or not when the mobile terminal is connected with the wearable equipment and receives a screen-off triggering event instruction;

the first screen-off control module is used for controlling the response of the mobile terminal to the command for triggering the screen-off event to be that only the screen is controlled to be closed when the wearable device is detected to be in the in-use state, and protecting the normal operation of the system from dormancy so as to control the wearable device to be normally used when the mobile terminal is in the screen-off state;

the second screen-off control module is used for controlling the response of the mobile terminal to the screen-off event triggering instruction to be screen-off and carrying out system dormancy when detecting that the mobile terminal is connected with the wearable device and detecting that the wearable device is not in a use state;

the screen-off detection module is used for detecting whether a system of the mobile terminal for closing the screen is in an operating state;

and the screen lightening control module is used for controlling the screen to be lightened when the system for closing the screen is detected to be in the running state, and controlling the system for awakening to lighten the screen when the system for closing the screen is detected to be in the dormant state.

9. A mobile terminal, characterized in that the mobile terminal comprises a memory, a processor and an image display program stored in the memory and executable on the processor, and the processor executes the image display program to implement the steps of the method for optimizing the processing of the mobile terminal based on the wearable device according to any one of claims 1-7.

10. A computer-readable storage medium, wherein an image display program is stored on the computer-readable storage medium, and when the image display program is executed by a processor, the steps of the method for optimizing a processing of a wearable device-based mobile terminal according to any one of claims 1 to 7 are implemented.

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