CN115129143A - Display method and device of screen locking interface, wearable device and storage medium - Google Patents

Abstract

The embodiment of the application provides a display method and device of a lock screen interface, wearable equipment and a storage medium, and relates to the technical field of wearable equipment. The method is applied to wearable equipment, wherein at least a first processor and a second processor are arranged in the wearable equipment, and the power consumption of the second processor is higher than that of the first processor; the method comprises the following steps: setting the screen state corresponding to the second processor to be a screen locking state under the condition that the second processor is in an awakening state and receives a screen locking instruction; synchronizing the screen locking state to the first processor through the second processor; setting a screen state corresponding to the first processor as a screen locking state; and displaying the screen locking interface through the first processor. According to the embodiment of the application, the user interface is displayed through the processor with smaller power consumption in the screen locking state, the power consumption of the wearable device can be reduced, and the endurance time of the wearable device is prolonged.

Description

Display method and device of screen locking interface, wearable device and storage medium

Technical Field

The embodiment of the application relates to the technical field of wearable equipment, in particular to a display method and device of a screen locking interface, wearable equipment and a storage medium.

Background

A wearable device is a portable electronic device that can be worn directly or integrated on a garment or accessory. Common wearable devices include smartwatches, smartbands, smartglasses, and the like.

For portability and wearability, wearable devices are generally designed to be smaller in size, and the smaller size means that the wearable device can only be configured with a battery having a smaller capacity. Taking wearable equipment as an example of the smart watch, the duration of the smart watch is short, and frequent charging is needed.

Disclosure of Invention

The embodiment of the application provides a display method and device of a lock screen interface, wearable equipment and a storage medium. The technical scheme is as follows:

on one hand, the method is applied to wearable equipment, wherein the wearable equipment is at least provided with a first processor and a second processor, and the power consumption of the second processor is higher than that of the first processor;

the method comprises the following steps:

setting a screen state corresponding to the second processor to be a screen locking state under the condition that the second processor is in an awakening state and receives a screen locking instruction;

synchronizing, by the second processor, the lock screen status to the first processor;

setting the screen state corresponding to the first processor as the screen locking state;

displaying a screen locking interface through the first processor.

On the other hand, the display device of the screen locking interface is applied to wearable equipment, wherein the wearable equipment is at least provided with a first processor and a second processor, and the power consumption of the second processor is higher than that of the first processor;

the device comprises:

the state setting module is used for setting the screen state corresponding to the second processor to be the screen locking state under the condition that the second processor is in the awakening state and receives the screen locking instruction;

the state synchronization module is used for synchronizing the screen locking state to the first processor through the second processor;

the state setting module is further configured to set a screen state corresponding to the first processor to the screen locking state;

and the interface display module is used for displaying the screen locking interface through the first processor.

In another aspect, embodiments of the present application provide a wearable device, which includes a processor and a memory; the processor at least comprises a first processor and a second processor, the power consumption of the second processor is higher than that of the first processor, and the memory stores a computer program which is loaded and executed by the processor to realize the display method of the screen locking interface.

In still another aspect, an embodiment of the present application provides a computer-readable storage medium, where a computer program is stored, and the computer program is loaded and executed by a processor to implement the display method of the lock screen interface according to the above aspect.

In yet another aspect, embodiments of the present application provide a computer program product including computer instructions stored in a computer-readable storage medium. The processor of the wearable device reads the computer instructions from the computer-readable storage medium, and the processor executes the computer instructions to cause the wearable device to perform the display method of the screen locking interface according to the above aspect.

The technical scheme provided by the embodiment of the application can bring the following beneficial effects:

be provided with the first treater of low-power consumption and the second treater of high-power consumption in the wearable equipment, can communicate between first treater and the second treater, the second treater can be with lock screen state synchronization for first treater, thereby make the second treater under the condition of receiving lock screen instruction, lock screen interface can be shown to first treater, through the less treater display user interface of consumption under the lock screen state, can reduce the power consumption of wearable equipment, promote the time of endurance of wearable equipment.

Drawings

FIG. 1 is a flowchart illustrating a method for displaying a lock screen interface according to an embodiment of the present application;

FIG. 2 is a flowchart of a method for displaying a lock screen interface according to another embodiment of the present application;

FIG. 3 is a flowchart of a method for displaying a lock screen interface according to another embodiment of the present application;

FIG. 4 is a block diagram of a display device of a lock screen interface provided by an embodiment of the present application;

fig. 5 is a block diagram of a wearable device according to an embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

In the related art, a single processor is disposed in the wearable device, and all system events generated during the operation of the device are processed by an operating system running on the processor, so that the processor needs to have a strong data processing capability and maintain a working state during the operation of the device. However, in the daily use process, the wearable device only needs to realize some functions with lower processing performance in most cases, for example, for a smart watch or a smart bracelet, in most cases, the smart watch or the smart bracelet only needs to perform message prompt and time display. Therefore, keeping the processor in the operating state for a long time does not improve the performance of the wearable device, but increases the power consumption of the device, resulting in a shorter endurance time of the wearable device.

In order to reduce the power consumption of the wearable device while ensuring the performance of the wearable device, the wearable device in the embodiment of the application is at least provided with a first processor and a second processor which have different processing performances and power consumption, the first processor and the second processor can communicate with each other, and the second processor can synchronize the screen locking state to the first processor, so that the first processor can display the screen locking interface under the condition that the second processor receives the screen locking instruction, and the user interface is displayed through the processor with smaller power consumption under the screen locking state, so that the power consumption of the wearable device can be reduced, and the endurance time of the wearable device is prolonged.

The present application is described below with reference to several embodiments.

Referring to fig. 1, a flowchart of a display method of a lock screen interface according to an embodiment of the present application is shown. The method can be applied to a wearable device, wherein at least a first processor and a second processor are arranged in the wearable device, and the power consumption of the second processor is higher than that of the first processor. The method may include several steps as follows.

Step 101, setting the screen state corresponding to the second processor to be the screen locking state under the condition that the second processor is in the wake-up state and the second processor receives the screen locking instruction.

In an embodiment of the application, the power consumption of the first processor is lower than the power consumption of the second processor. Illustratively, the processing performance of the first processor is lower than the processing performance of the second processor, illustratively, the processing capacity and the processing speed of the first processor are both lower than the second processor. Illustratively, a second system run by a second processor is capable of handling events handled by a first system run by a first processor, and the first system is not necessarily capable of handling events handled by the second system.

For example, by taking the wearable device as an intelligent watch as an example for description, the first processor may be an MCU (Micro Controller Unit), the second processor may be a CPU (Central Processing Unit), the first System is an RTOS (Real Time Operating System) running on the MCU, and the second System is an Android (Android) Operating System running on the CPU. Events that can be handled by the first system include, but are not limited to, at least one of: scenes with low requirements on processing performance such as dial display, dial interface switching, notification message display and the like or weak interaction scenes; events that can be handled by the second system include, but are not limited to, at least one of: the method comprises the following steps of answering a call, starting an application, compiling a dial plate, setting functions and the like, wherein the scenes or strong interaction scenes have high requirements on processing performance.

The wake-up state refers to being in a running state, and the processor being in the wake-up state refers to the processor being in a running state, that is, the processor being in a normal working state.

The screen locking instruction refers to an instruction to lock a screen. Illustratively, the screen locking instruction can be triggered by voice, gesture, touch, pressing a physical key, and the like. For example, the user may speak "lock screen" into the wearable device, thereby triggering the second processor to receive a lock screen instruction; for another example, the user may swipe a gesture corresponding to "screen lock" against the wearable device, thereby triggering the second processor to receive the screen lock instruction; for another example, the user may touch a "screen lock" icon on the wearable device, thereby triggering the second processor to receive a screen lock instruction; for another example, the user may press an entity key on the wearable device (e.g., the user may press a power key on the wearable device), thereby triggering the second processor to receive the screen lock instruction.

In a possible implementation, when the running time of the second processor reaches the screen locking time (which is equivalent to the second processor receiving the screen locking instruction), the second processor automatically sets the screen state to the screen locking state. The screen locking time may be set by a user, or may be default time, which is not limited in the embodiment of the present application.

In embodiments of the present application, the wearable device has a display screen (which may also be referred to as a screen). The screen state of display screen includes lock screen state and unlock state, and the unlock state means that the display screen of wearable equipment is in the state of normal demonstration, and unlock state and lock screen state are two kinds of different states. The display screen may be controlled by the first processor or by the second processor. And when the second processor receives the screen locking instruction, setting the screen state corresponding to the second processor as the screen locking state.

The screen state corresponding to the processor refers to a state of a display screen of the wearable device when a system operated by the processor obtains the screen control right. Illustratively, the screen state corresponding to the second processor refers to a state of a display screen of the wearable device when the second system operated by the second processor obtains the screen control right. The screen state corresponding to the first processor refers to a state of a display screen of the wearable device when the first system operated by the first processor obtains the screen control right.

In a possible implementation manner, the screen state corresponding to the second system is set to be the screen locking state.

And 102, synchronizing the screen locking state to the first processor through the second processor.

Communication may be between the second processor and the first processor. After the second processor receives the screen locking instruction and the screen state of the second processor is set to the screen locking state, the second processor needs to synchronize the screen state to the first processor, so that the screen state of the first processor and the screen state of the second processor are synchronized, and the display screen can normally display when the system is switched.

In a possible implementation, the lock screen status is synchronized to the first system by the second system.

In a possible implementation manner, the second processor synchronizes the screen state by sending data of the byte stream to the first processor, and exemplarily, taking the screen state as the screen locking state as an example, the data of the corresponding byte stream may be as follows:

the message SyncLockScreenStatus {// message screen state is the lock screen state

int32 status 1; v/State field is assigned a value of 1 and State field is a 32-bit integer

}

And 103, setting the screen state corresponding to the first processor as a screen locking state.

After the screen state corresponding to the second processor is set to be the screen locking state, correspondingly, the screen state corresponding to the first processor is set to be the screen locking state.

In a possible implementation manner, the screen state corresponding to the first system is set to be the screen locking state.

And 104, displaying a screen locking interface through the first processor.

The screen locking interface is an interface displayed when the wearable device is not unlocked, and is an interface displayed when the wearable device is in a screen locking state.

After the second processor receives the screen locking instruction, it shows that the user does not need to use the second processor to handle comparatively complicated events this moment, at this moment, can be through the display screen of first treater control wearable equipment, that is, through the screen locking interface of first treater display, because first treater consumption is lower, consequently, can promote wearable equipment's time of endurance.

In a possible implementation, a lock screen interface is displayed by the first system.

In a possible implementation, step 103 and step 104 may be performed simultaneously; step 103 may be executed first, and then step 104 may be executed; step 104 may be executed first, and then step 103 is executed, which is not limited in this embodiment of the application.

In a possible implementation manner, under the condition that the first processor is in an awakening state and receives a screen locking instruction, setting a screen state corresponding to the first processor to be a screen locking state; synchronizing the screen locking state to a second processor through a first processor; setting the screen state corresponding to the second processor as a screen locking state; and displaying the screen locking interface through the first processor. Under the condition that the screen locking instruction is received at first treater, set up the screen state that first treater corresponds into the screen locking state to give the second treater in step, be convenient for follow-up through the wearable equipment of second treater unblock.

To sum up, among the technical scheme that this application embodiment provided, be provided with the first treater of low-power consumption and the second treater of high-power consumption in the wearable equipment, can communicate between first treater and the second treater, the second treater can give first treater with the lock screen state synchronization, thereby make the second treater under the condition of receiving the lock screen instruction, the lock screen interface can be shown to first treater, show user interface through the less treater of consumption under the lock screen state, can reduce the power consumption of wearable equipment, promote the duration of wearable equipment.

Referring to fig. 2, a flowchart of a display method of a lock screen interface according to another embodiment of the present application is shown. The method can be applied to a wearable device, wherein at least a first processor and a second processor are arranged in the wearable device, and the power consumption of the second processor is higher than that of the first processor. The method may include several steps as follows.

Step 201, setting the screen state corresponding to the second processor to be the screen locking state under the condition that the second processor is in the wake-up state and the second processor receives the screen locking instruction.

In a possible implementation, the screen locking state includes an encrypted screen locking state and an unencrypted screen locking state. The encrypted screen locking state refers to a state that the screen can be unlocked only by inputting verification information, and the unencrypted screen locking state refers to a state that the screen can be unlocked without inputting verification information.

And 202, synchronizing the encrypted screen locking state to the first processor through the second processor under the condition that the screen locking state comprises the encrypted screen locking state.

When the second processor sets the screen locking verification, namely, when the screen state corresponding to the second processor is the encrypted screen locking state, the encrypted screen locking state is synchronized to the first processor through the second processor, so that the first processor knows that the second processor needs to be awakened when unlocking is performed.

In a possible implementation, the encrypted screen locking state is synchronized to the first system through the second system in a case that the screen locking state includes the encrypted screen locking state.

And step 203, synchronizing the unencrypted screen locking state to the first processor through the second processor under the condition that the screen locking state comprises the unencrypted screen locking state.

In a possible implementation, the unencrypted screen locking state is synchronized to the first system through the second system in the case that the screen locking state includes an unencrypted screen locking state.

And after the encrypted screen locking state or the unencrypted screen locking state is synchronized to the first processor through the second processor, setting the screen state corresponding to the first processor to be the screen locking state.

And 204, setting the screen state corresponding to the first processor as an encrypted screen locking state.

In a possible implementation manner, the screen state corresponding to the first system is set to be the encrypted screen locking state.

Step 205, setting the screen state corresponding to the first processor to be an unencrypted screen locking state.

In a possible implementation manner, the screen state corresponding to the first system is set to be the unencrypted screen locking state.

It should be noted that step 202 and step 203 are not executed at the same time, and step 204 and step 205 are not executed at the same time. After step 202 is executed, step 204 is executed; alternatively, after step 203 is executed, step 205 is executed; or, simultaneously executing step 202 and step 204, or, simultaneously executing step 203 and step 205; or, step 204 is executed first, and then step 202 is executed; alternatively, step 205 is executed first, and then step 203 is executed, which is not limited in this embodiment of the application.

And step 206, displaying a screen locking interface through the first processor.

In a possible implementation, a lock screen interface is displayed by the first system.

Illustratively, the screen locking interfaces corresponding to the encrypted screen locking state and the unencrypted screen locking state are the same, and the interfaces triggered after unlocking are different. Under the condition that the screen locking state comprises an encrypted screen locking state, an interface triggered after unlocking is an unlocking interface; and under the condition that the screen locking state comprises the unencrypted screen locking state, the interface triggered after unlocking is directly the user interface without passing through an unlocking interface.

Illustratively, the screen locking interface corresponding to the encrypted screen locking state and the unencrypted screen locking state is different. Under the condition that the screen locking state comprises the encrypted screen locking state, screen locking prompt information is displayed on the screen locking interface and used for prompting a user that the user needs to unlock (input correct verification information) to open the user interface.

Referring to fig. 3, a flowchart of a display method of a lock screen interface according to another embodiment of the present application is shown. The method can be applied to a wearable device, wherein at least a first processor and a second processor are arranged in the wearable device, and the power consumption of the second processor is higher than that of the first processor. The method may include several steps as follows.

Step 301, setting the screen state corresponding to the second processor to the screen locking state under the condition that the second processor is in the wake-up state and the second processor receives the screen locking instruction.

Step 302, synchronizing the lock screen state to the first processor through the second processor.

Step 303, setting the screen state corresponding to the first processor as a screen locking state.

And 304, displaying a screen locking interface through the first processor.

In a possible implementation, step 303 and step 304 may be performed simultaneously; step 303 may be performed first, and then step 304 may be performed; step 304 may be executed first, and then step 303 is executed, which is not limited in this embodiment of the application.

The descriptions of step 301 to step 304 can be found in the above embodiments, and are not repeated herein.

And 305, awakening the second processor through the first processor under the condition that the second processor is in a dormant state and the first processor receives an unlocking instruction, wherein the screen locking state comprises an encrypted screen locking state.

The sleep state refers to an inactive state, i.e., a non-operational state. A processor being in a sleep state refers to the processor being in an inoperative state.

The unlocking instruction refers to an instruction for unlocking a display screen of the wearable device. In a possible implementation manner, the unlocking instruction may be triggered by voice, gesture, touch, or the like, for example, the user may "unlock" by speaking to the wearable device, so as to trigger the first processor to receive the unlocking instruction; for another example, the user may trigger the first processor to receive an unlocking instruction by stroking a corresponding gesture to "unlock" the wearable device; for another example, the user may trigger the first processor to receive the unlock instruction by sliding the lock screen interface upward.

Because the display screen of the wearable device is controlled by the first processor in the screen locking state, the unlocking instruction is also received by the first processor, and when the first processor receives the unlocking instruction, the second processor is awakened by the first processor.

And awakening the second processor through the first processor under the condition that the screen locking state comprises an encrypted screen locking state, the second processor is in a dormant state and the first processor receives an unlocking instruction.

In a possible implementation manner, when the screen locking state includes an encrypted screen locking state, the second processor is in a sleep state, and the first system receives an unlocking instruction, the second system is awakened through the first system.

And step 306, receiving authentication information input by a user through the second processor.

In this embodiment, the authentication information is used to trigger the second processor to perform authentication. The authentication information may include any one of: password, voice, face, iris, fingerprint.

Illustratively, the authentication information is used to trigger authentication by the second system.

In a possible implementation, the first processor corresponds to a first system, the first system refers to a system executed by the first processor, the second processor corresponds to a second system, and the second system refers to a system executed by the second processor. Illustratively, the first system may be referred to as a corelet and the second system may be referred to as a corelet.

Step 306 may include several substeps as follows:

and step 306a, displaying an unlocking interface through the second system.

The unlocking interface is an interface for unlocking, the unlocking interface is an interface for a user to input verification information, and the user can input the verification information in the unlocking interface.

Since the process of waking up and displaying the second system takes a certain time, a phenomenon of short-time no response may occur in the process of switching from the first system to the second system, which affects the use experience. In order to reduce the display delay of the screen locking interface in the system switching process, when the first system wakes up the second system, an unlocking interface (only responsible for drawing an interface image and not executing a specific function of the second system under the first system) can be drawn and displayed through the first system, wherein the unlocking interface is a user interface of the second system; and responding to the drawing of the second system to finish the unlocking interface, and displaying the unlocking interface through the second system. After the second system finishes drawing the unlocking interface, the system operated by the wearable device is switched from the first system to the second system, so that the screen locking interface is displayed through the second system, and a corresponding unlocking function is executed. Because the unlocking interfaces drawn and displayed by the first system and the second system are consistent, the problem of sudden change of the front and back pictures of the system can not occur, and the system switching process is not easy to be perceived. Because the first system is in the awakening state, the first system can draw and display the screen locking interface immediately after receiving the unlocking instruction, and therefore the switching speed of the system is improved visually.

In a possible implementation manner, after the unlocking interface is displayed through the second system, the first system can still be in an awakening state, and the power consumption of the first system is low, so that the endurance influence on the wearable device is low; of course, after the unlocking interface is displayed by the second system, the first system may be in a sleep state, which is not limited in the embodiment of the present application.

In a possible implementation manner, in order to ensure that after the first system draws and completely displays the unlocking interface, the system is switched to the second system in time, the situation that after the first system completely displays the unlocking interface, no response is generated in user operation (the screen locking interface is drawn and displayed by the first system at the moment) is avoided, the sliding speed of the unlocking interface is determined according to the time when the second system wakes up and draws the unlocking interface, when the unlocking interface drawn by the first system completely occupies the display interface of the wearable device, the unlocking interface is drawn by the second system, and the system switching is realized under the situation that the user does not sense.

And step 306b, receiving the verification information input by the user at the unlocking interface through the second system.

Because the safety of the second system is higher than that of the first system, the second system receives the verification information input by the user on the unlocking interface, and the safety of the information can be ensured.

And 307, executing an unlocking process through the second processor based on the authentication information input by the user and preset authentication information.

The preset authentication information may be information that is pre-stored in the wearable device by the user and used for authenticating the identity of the user. The preset authentication information is consistent with the type of the authentication information input by the user, that is, when the authentication information input by the user is a password, the preset authentication information is also the password; when the verification information input by the user is voice, the preset verification information is also voice; when the verification information input by the user is a face, the preset verification information is also the face; when the verification information input by the user is the iris, the preset verification information is also the iris; when the authentication information input by the user is a fingerprint, the preset authentication information is also a fingerprint.

In a possible implementation, step 307 may comprise several sub-steps as follows:

and 307a, confirming whether the verification information input by the user is consistent with preset verification information through the second system.

And 307b, responding to the consistency of the verification information input by the user and the preset verification information, and displaying a user interface through the first system or the second system based on the operation mode of the wearable device.

Taking the authentication information as the password as an example, displaying an unlocking interface through the second system, receiving the password input by the user in the unlocking interface through the second system, responding to the input password being consistent with the preset password, and displaying the user interface through the first system or the second system based on the operation mode of the wearable device.

In a possible implementation manner, a plurality of preset verification information may be stored in the wearable device in advance, and when the verification information input by the user is consistent with one of the plurality of preset verification information, the user interface is displayed through the first system or the second system based on the operation mode of the wearable device.

In a possible implementation, step 307b may comprise several sub-steps as follows:

1. in a case that the operation mode of the wearable device includes a smart mode, displaying, by the second system, the first user interface.

2. In a case that the operation mode of the wearable device includes a non-smart mode, displaying, by the first system, a second user interface.

In a possible implementation, the operation modes of the wearable device include a smart mode and a non-smart mode. The intelligent mode can also be called as a performance mode, and refers to a mode in which the first processor and the second processor both keep an awake state, and the wearable device can quickly execute an event with higher processing performance in the intelligent mode; the non-smart mode, which may also be referred to as a low power mode, refers to a mode in which only the first processor remains in a wake-up state while the second processor is in a sleep state. Of course, in other possible implementations, the wearable device may also have other operation modes, which is not limited in this embodiment of the application.

Unlike smart phones and other electronic devices with strong interaction properties, wearable devices, as an auxiliary electronic device, only have weak interaction with users in most usage scenarios. For example, a user is looking only through a smart watch in most scenarios. Therefore, when the wearable device processes an event through the first processor (the first system processes the event), the second processor is controlled to be in the sleep state (the second system is in the sleep state), and the overall power consumption of the wearable device can be reduced.

According to the embodiment of the application, the display diversity of the wearable device is improved by intelligently displaying the user interface after unlocking based on the operation mode of the wearable device.

The first user interface refers to an interface controlled by the first system. In a possible implementation manner, the first user interface may display an exercise health icon, a weather icon, an alarm clock icon, a system switching icon, and the like, which is not limited in the embodiment of the present application.

The second user interface refers to an interface controlled by the second system. In a possible implementation manner, the second user interface may display a voice assistant icon, an icon of each application program, and the like, which is not limited in this embodiment of the application.

In a possible implementation manner, the first user interface is displayed through the first processor under the condition that the screen locking state comprises an unencrypted screen locking state and the first processor receives an unlocking instruction.

In a possible implementation manner, the method may further include the following steps:

firstly, displaying a third user interface through the first processor under the condition that the second processor is in a dormant state and the first processor is in an awakening state;

and secondly, responding to a system switching instruction, and displaying a fourth user interface through the second processor.

In a possible implementation, the system switching instruction is an instruction triggered by a shortcut key (e.g., a physical key provided on the wearable device) or an instruction triggered by sliding (e.g., by sliding a display screen of the wearable device with a single finger or a double finger) or other means.

And responding to a system switching instruction, and skipping to display the fourth user interface from the third user interface. The third user interface refers to an interface controlled by the first system and the fourth user interface refers to an interface controlled by the second system.

During operation, the wearable device processes events of low performance processing requirements through a first system operating on a low power processor and maintains a high power processor in a sleep state (and correspondingly, a second system operated by the high power processor is in the sleep state). The power consumption of the wearable equipment is reduced while the basic functions of the wearable equipment are realized; when an event with high-performance processing requirements exists (such as when an application program is started), the high-power processor is awakened, the second system is switched to process the event, the triggered event can be timely responded and processed, and the performance requirements of the wearable device are met.

For example, when a user needs to use a function that is not available in a user interface displayed by the first system, the wearable device needs to switch the first system to the second system, so that the user selects the function that needs to be used from the user interface displayed by the second system.

When the first processor is in an awake state (at this time, the interface of the wearable device is a user interface displayed by the first system), and the second processor is in a sleep state, when a system switching instruction is received, it indicates that the first system needs to be switched to the second system, and because the first processor does not have a function and a capability of processing a corresponding event, the second processor in the sleep state needs to be woken up, so that the second system can process the event.

The following are embodiments of the apparatus of the present application that may be used to perform embodiments of the method of the present application. For details which are not disclosed in the embodiments of the apparatus of the present application, reference is made to the embodiments of the method of the present application.

Referring to fig. 4, a block diagram of a display device of a screen locking interface according to an embodiment of the present application is shown, where the display device is applied to a wearable device, where at least a first processor and a second processor are disposed in the wearable device, and power consumption of the second processor is higher than that of the first processor; the device has the functions of implementing the method examples, and the functions can be realized by hardware or by hardware executing corresponding software. The apparatus 400 may include:

a state setting module 410, configured to set a screen state corresponding to the second processor to a screen locking state when the second processor is in an awake state and the second processor receives a screen locking instruction;

a state synchronization module 420, configured to synchronize the screen locking state to the first processor through the second processor;

the state setting module 410 is further configured to set a screen state corresponding to the first processor to the screen locking state;

and an interface display module 430, configured to display a screen locking interface through the first processor.

To sum up, among the technical scheme that this application embodiment provided, be provided with the first treater of low-power consumption and the second treater of high-power consumption in the wearable equipment, can communicate between first treater and the second treater, the second treater can be with lock screen state synchronization for first treater, thereby make the second treater under the condition of receiving lock screen instruction, lock screen interface can be shown to first treater, through the less treater display user interface of consumption under the lock screen state, can reduce the power consumption of wearable equipment, promote the duration of wearable equipment.

In an exemplary embodiment, the screen locking state comprises an encrypted screen locking state and an unencrypted screen locking state;

the state synchronization module 420 is configured to:

under the condition that the screen locking state comprises the encrypted screen locking state, synchronizing the encrypted screen locking state to the first processor through the second processor;

and under the condition that the screen locking state comprises the unencrypted screen locking state, synchronizing the unencrypted screen locking state to the first processor through the second processor.

In an exemplary embodiment, the apparatus 400 further includes:

a processor wake-up module (not shown in the figure) configured to wake up the second processor through the first processor when the screen locking state includes an encrypted screen locking state, and the second processor is in a sleep state and the first processor receives an unlocking instruction;

an information receiving module (not shown in the figure) for receiving, by the second processor, authentication information input by a user, where the authentication information is used for triggering the second processor to perform identity authentication;

and an information unlocking module (not shown in the figure) for executing an unlocking process based on the verification information input by the user and preset verification information through the second processor.

In an exemplary embodiment, the first processor corresponds to a first system, the first system refers to a system executed by the first processor, the second processor corresponds to a second system, the second system refers to a system executed by the second processor;

the information receiving module is configured to:

displaying an unlocking interface through the second system;

and receiving the verification information input by the user at the unlocking interface through the second system.

In an exemplary embodiment, the information unlocking module includes:

an information confirmation unit (not shown in the figure) for confirming whether the authentication information input by the user is consistent with preset authentication information through the second system;

an interface display unit (not shown in the figure) for displaying a user interface through the first system or the second system based on the operation mode of the wearable device in response to the authentication information input by the user being consistent with preset authentication information.

In an exemplary embodiment, the interface display unit is configured to:

displaying, by the second system, a first user interface if the operating mode of the wearable device comprises a smart mode;

displaying, by the first system, a second user interface if the mode of operation of the wearable device includes a non-smart mode.

In an exemplary embodiment, the interface display module 430 is further configured to:

displaying, by the first processor, a third user interface while the second processor is in a sleep state and the first processor is in a wake state;

displaying, by the second processor, a fourth user interface in response to a system switch instruction.

It should be noted that, when the apparatus provided in the foregoing embodiment implements the functions thereof, only the division of the functional modules is illustrated, and in practical applications, the functions may be distributed by different functional modules according to needs, that is, the internal structure of the apparatus may be divided into different functional modules to implement all or part of the functions described above. In addition, the apparatus and method embodiments provided by the above embodiments belong to the same concept, and specific implementation processes thereof are described in the method embodiments for details, which are not described herein again.

Please refer to fig. 5, which shows a block diagram of a wearable device according to an embodiment of the present application.

The wearable device in the embodiments of the present application may include one or more of the following components: a processor 510 and a memory 520.

Processor 510 may include one or more processing cores. Illustratively, the processor 510 includes at least a first processor 511 and a second processor 512. The first processor 511 may be used to operate a first system, the second processor 512 may be used to operate a second system, and the power consumption of the first processor 511 is lower than that of the second processor 512. The processor 510 interfaces with various interfaces and circuitry throughout the wearable device to perform various functions of the wearable device and process data by executing or executing instructions, programs, code sets, or instruction sets stored in the memory 520 and invoking data stored in the memory 520. Alternatively, the processor 510 may be implemented in hardware using at least one of Digital Signal Processing (DSP), Field-Programmable Gate Array (FPGA), and Programmable Logic Array (PLA). The processor 510 may integrate one or more of a Central Processing Unit (CPU), a Graphics Processing Unit (GPU), a Neural-Network Processing Unit (NPU), a modem, and the like. Wherein, the CPU mainly processes an operating system, a user interface, an application program and the like; the GPU is used for rendering and drawing contents required to be displayed by the touch display screen; the NPU is used for realizing an Artificial Intelligence (AI) function; the modem is used to handle wireless communications. It is understood that the modem may not be integrated into the processor 510, but may be implemented by a single chip.

Optionally, the processor 510, when executing the program instructions in the memory 520, implements the methods provided by the various method embodiments described above.

The Memory 520 may include a Random Access Memory (RAM) or a Read-Only Memory (ROM). Optionally, the memory 520 includes a non-transitory computer-readable medium. The memory 520 may be used to store instructions, programs, code sets, or instruction sets. The memory 520 may include a program storage area and a data storage area, wherein the program storage area may store instructions for implementing an operating system, instructions for at least one function (such as a touch function, a sound playing function, an image playing function, etc.), instructions for implementing the above-described method embodiments, and the like; the storage data area may store data created from use of the wearable device (such as audio data, a phone book), and the like.

The wearable device in embodiments of the present application further comprises a communication component 530 and a display component 540. The Communication component 530 may be a bluetooth component, a WiFi (Wireless local area network) component, an NFC (Near Field Communication) component, or the like, and is configured to communicate with an external device (a server or other terminal device) through a wired or Wireless network; the display component 540 is used to perform graphical user interface presentation and/or receive user interaction.

In addition, those skilled in the art will appreciate that the structure of the wearable device shown in the above figures does not constitute a limitation of the wearable device, and that the wearable device may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components. For example, the wearable device further includes a radio frequency circuit, an input unit, a sensor, an audio circuit, a speaker, a microphone, a power supply, and other components, which are not described herein again.

In an exemplary embodiment, a computer readable storage medium is further provided, in which a computer program is stored, and the computer program is loaded and executed by a processor of a wearable device to implement the steps in the display method embodiment of the lock screen interface described above.

In an exemplary embodiment, a computer program product is provided that includes computer instructions stored in a computer readable storage medium. The processor of the wearable device reads the computer instructions from the computer readable storage medium, and executes the computer instructions, so that the wearable device executes the display method of the screen locking interface.

The above description is only exemplary of the application and should not be taken as limiting the application, and any modifications, equivalents, improvements and the like that are made within the spirit and principle of the application should be included in the protection scope of the application.

Claims (10)

1. The display method of the screen locking interface is applied to wearable equipment, wherein the wearable equipment is at least provided with a first processor and a second processor, and the power consumption of the second processor is higher than that of the first processor;

the method comprises the following steps:

setting a screen state corresponding to the second processor to be a screen locking state under the condition that the second processor is in an awakening state and receives a screen locking instruction;

synchronizing, by the second processor, the lock screen status to the first processor;

setting the screen state corresponding to the first processor as the screen locking state;

displaying a screen locking interface through the first processor.

2. The method of claim 1, wherein the lock screen state comprises an encrypted lock screen state and an unencrypted lock screen state;

the synchronizing, by the second processor, the lock screen status to the first processor, comprising:

synchronizing the encrypted screen locking state to the first processor through the second processor under the condition that the screen locking state comprises the encrypted screen locking state;

and under the condition that the screen locking state comprises the unencrypted screen locking state, synchronizing the unencrypted screen locking state to the first processor through the second processor.

3. The method of claim 1, further comprising, after displaying, by the first processor, a lock screen interface:

the screen locking state comprises an encrypted screen locking state, and the second processor is awakened through the first processor under the condition that the second processor is in a dormant state and the first processor receives an unlocking instruction;

receiving authentication information input by a user through the second processor, wherein the authentication information is used for triggering the second processor to carry out identity authentication;

and executing an unlocking process based on the verification information input by the user and preset verification information through the second processor.

4. The method of claim 3, wherein the first processor corresponds to a first system, the first system being a system executed by the first processor, the second processor corresponds to a second system, the second system being a system executed by the second processor;

the receiving, by the second processor, the authentication information input by the user includes:

displaying an unlocking interface through the second system;

and receiving the verification information input by the user at the unlocking interface through the second system.

5. The method according to claim 4, wherein the performing, by the second processor, an unlocking procedure based on the authentication information input by the user and preset authentication information comprises:

confirming whether the verification information input by the user is consistent with preset verification information or not through the second system;

and in response to the verification information input by the user being consistent with preset verification information, displaying a user interface through the first system or the second system based on the operation mode of the wearable device.

6. The method of claim 5, wherein the displaying a user interface through the first system or the second system based on the operating mode of the wearable device comprises:

displaying, by the second system, a first user interface if the operating mode of the wearable device comprises a smart mode;

displaying, by the first system, a second user interface if the mode of operation of the wearable device includes a non-smart mode.

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

displaying, by the first processor, a third user interface while the second processor is in a sleep state and the first processor is in a wake state;

displaying, by the second processor, a fourth user interface in response to a system switch instruction.

8. The display device of the screen locking interface is applied to wearable equipment, wherein at least a first processor and a second processor are arranged in the wearable equipment, and the power consumption of the second processor is higher than that of the first processor;

the device comprises:

the state setting module is used for setting the screen state corresponding to the second processor to be the screen locking state under the condition that the second processor is in the awakening state and receives the screen locking instruction;

the state synchronization module is used for synchronizing the screen locking state to the first processor through the second processor;

the state setting module is further configured to set a screen state corresponding to the first processor to the screen locking state;

and the interface display module is used for displaying the screen locking interface through the first processor.

9. A wearable device, wherein the wearable device comprises a processor and a memory; the processor includes at least a first processor and a second processor, the power consumption of the second processor is higher than that of the first processor, and the memory stores a computer program that is loaded and executed by the processor to implement the display method of the screen locking interface according to any one of claims 1 to 7.

10. A computer-readable storage medium, in which a computer program is stored, the computer program being loaded and executed by a processor to implement the display method of the lock screen interface according to any one of claims 1 to 7.

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