CN117501700A - Application awakening method, display device, mobile terminal and server - Google Patents

Abstract

The embodiment of the application provides an application awakening method of display equipment, the display equipment, a mobile terminal and a server, wherein the method comprises the following steps: if the display device is in a starting-up state, the display device receives a first wake-up instruction from the server, wherein the first wake-up instruction is an instruction generated according to a first connection request. And the display equipment processor controls the target application to be started according to the first wake-up instruction. And if the display equipment is in a starting-up state, the display equipment receives a second wake-up instruction from the server, wherein the second wake-up instruction is an instruction generated according to a second connection request. And the processor of the display device controls the display device to enter the starting state from the standby state according to the second wake-up instruction, and then controls the target application to be started according to the second wake-up instruction.

Description

Application awakening method, display device, mobile terminal and server

Cross Reference to Related Applications

The present application claims priority from chinese patent application No. 202110342826.6 filed at 30/03/2021, chinese patent application No. 202110586878. X filed at 27/2021, and chinese patent application No. 202110583580.1 filed at 27/2021, which are incorporated herein by reference in their entirety.

Technical Field

The present disclosure relates to display device technologies, and in particular, to an application wake-up method, a display device, a mobile terminal, and a server.

Background

The television in the related art is generally provided with a key and a remote control receiving component, and the television is controlled to start by receiving the key operation of a user or by receiving the starting key value of a remote controller through the remote control receiving component, and the television generally directly enters a preset system program after being started.

Disclosure of Invention

The embodiment of the application provides a mobile terminal, which comprises: a communication interface for communication between the processor and a server; a processor for:

responding to the received operation, displaying an online list of the display equipment, wherein a display equipment control in the online list is marked as one of a starting state, a standby state or a closing state, the starting state represents a state that a main processor of the corresponding display equipment, which is provided with an operating system, is in a starting state, the standby state represents a state that the main processor of the corresponding display equipment is in a non-starting state but a sub-processor is in a starting state, and the main processor of the corresponding display equipment is in a non-starting state and the sub-processor is in a non-starting state;

Receiving an operation of a first display device control in the online list;

when the first display device control is marked as a starting state or a standby state, a connection request is sent to the server, wherein the connection request comprises a first display device identifier of a first display device corresponding to the first display device control, the connection request is used for starting a target application in the first display device, and call connection is established through the target application;

and when the first display device control is marked as a power-off key state, displaying prompt information representing that the first display device is not connectable.

An embodiment of the application provides a server, including a memory and a processor, the processor is used for:

receiving a connection request sent by a mobile terminal, wherein the connection request comprises a first display device identifier of a first display device corresponding to the first display device control;

responding to the connection request, establishing a virtual session room, and feeding back a message representing waiting for connection to the mobile terminal;

and sending a wake-up instruction to the first display device, wherein the wake-up instruction comprises a room identifier corresponding to the virtual session room, and the wake-up instruction is used for enabling the first display device to start a target application and enabling the target application in the first display device to establish session connection according to the room identifier.

An embodiment of the present application provides a display device, including:

a display;

a communicator for: receiving a wake-up instruction, wherein the wake-up instruction is sent to a main processor of the display device when the main processor is in a starting state, and is sent to a sub-processor when the main processor of the display device is in an un-starting state and the sub-processor is in a starting state, and the wake-up instruction comprises an instruction for starting a target application;

the main processor is configured to: after receiving the wake-up instruction, starting a target application corresponding to the instruction for starting the target application;

the sub-processor is configured to: and after receiving the wake-up instruction, controlling the main processor to start, and sending the instruction for starting the target application to the main processor.

The embodiment of the application provides an application awakening method, which comprises the following steps:

receiving a connection request sent by a mobile terminal, wherein the connection request comprises a first display device identifier of a first display device corresponding to the first display device control;

When the first display device is determined to be in a starting state, a first wake-up instruction is sent to the first display device, wherein the first wake-up instruction comprises an instruction for starting a target application, and the instruction for starting the target application is used for enabling a main processor in the first display device to start the target application;

and when the first display device is in a standby state, sending a second wakeup instruction to the first display device, wherein the second wakeup instruction comprises a starting instruction and an instruction for starting a target application, the starting instruction is used for enabling a sub-processor in the first display device to control a main processor in the first display device to start, and the instruction for starting the target application is used for enabling the main processor in the first display device to start the target application.

Drawings

FIG. 1 illustrates a usage scenario of a display device according to some embodiments;

FIG. 2 illustrates a hardware configuration block diagram of a control device according to some embodiments;

FIG. 3A illustrates a hardware configuration block diagram of a display device according to some embodiments;

FIG. 3B illustrates a hardware configuration block diagram of a display device according to some embodiments;

FIG. 4 illustrates a software configuration diagram in a display device according to some embodiments;

FIG. 5 illustrates an icon control interface display diagram for an application in a display device, in accordance with some embodiments;

FIG. 6 illustrates a remote wakeup system schematic of a display device according to some embodiments;

FIG. 7 illustrates a user interface diagram in a mobile terminal in accordance with some embodiments;

FIG. 8 illustrates a user interface diagram in yet another mobile terminal in accordance with some embodiments;

FIG. 9 illustrates a user interface diagram in yet another mobile terminal in accordance with some embodiments;

FIG. 10 illustrates an application wakeup method signaling diagram for a display device according to some embodiments;

fig. 11 illustrates an application wakeup method signaling diagram for yet another display device, in accordance with some embodiments.

Detailed Description

For purposes of clarity and implementation of the present application, the following description will make clear and complete descriptions of exemplary implementations of the present application with reference to the accompanying drawings in which exemplary implementations of the present application are illustrated, it being apparent that the exemplary implementations described are only some, but not all, of the examples of the present application.

The terms "first," second, "" third and the like in the description and in the claims and in the above-described figures are used for distinguishing between similar or similar objects or entities and not necessarily for limiting a particular order or sequence, unless otherwise indicated. It is to be understood that the terms so used are interchangeable under appropriate circumstances.

Fig. 1 is a schematic diagram of a usage scenario of a display device according to an embodiment. As shown in fig. 1, the display device 200 is also in data communication with a server 400, and a user can operate the display device 200 through the smart device 300 or the control apparatus 100.

In some embodiments, the control apparatus 100 may be a remote controller, and the communication between the remote controller and the display device includes at least one of infrared protocol communication or bluetooth protocol communication, and other short-range communication modes, and the display device 200 is controlled by a wireless or wired mode. The user may control the display apparatus 200 by inputting a user instruction through at least one of a key on a remote controller, a voice input, a control panel input, and the like.

In some embodiments, the smart device 300 may include any of a mobile terminal 300A, a tablet, a computer, a notebook, an AR/VR device, etc.

In some embodiments, the smart device 300 may also be used to control the display device 200. For example, the display device 200 is controlled using an application running on a smart device.

In some embodiments, the smart device 300 and the display device may also be used for communication of data.

In some embodiments, the display device 200 may also perform control in a manner other than the control apparatus 100 and the smart device 300, for example, the voice command control of the user may be directly received through a module configured inside the display device 200 device for acquiring voice commands, or the voice command control of the user may be received through a voice control apparatus configured outside the display device 200 device.

In some embodiments, software steps performed by one step execution body may migrate on demand to be performed on another step execution body in data communication therewith. For example, software steps executed by the server may migrate to be executed on demand on a display device in data communication therewith, and vice versa.

Fig. 2 exemplarily shows a block diagram of a configuration of the control apparatus 100 in accordance with an exemplary embodiment. As shown in fig. 2, the control device 100 includes a controller 110, a communication interface 130, a user input/output interface 140, a memory, and a power supply. The control apparatus 100 may receive an input operation instruction of a user and convert the operation instruction into an instruction recognizable and responsive to the display device 200, and function as an interaction between the user and the display device 200.

In some embodiments, the communication interface 130 is configured to communicate with the outside, including at least one of a WIFI chip, a bluetooth module, NFC, or an alternative module.

In some embodiments, the user input/output interface 140 includes at least one of a microphone, a touchpad, a sensor, keys, or an alternative module.

Fig. 3A shows a hardware configuration block diagram of the display device 200 in accordance with an exemplary embodiment.

In some embodiments, display apparatus 200 includes at least one of a modem 210, a communicator 220, a detector 230, an external device interface 240, a controller 250, a display 260, an audio output interface 270, memory, a power supply, a user interface.

In some embodiments, the display 260 includes a display screen component for presenting a picture, and a driving component for driving an image display, for receiving an image signal from the controller output, for displaying video content, image content, and components of a menu manipulation interface, and a user manipulation UI interface, etc.

In some embodiments, the display 260 may be at least one of a liquid crystal display, an OLED display, and a projection display, and may also be a projection device and a projection screen.

In some embodiments, communicator 220 is a component for communicating with external devices or servers according to various communication protocol types. For example: the communicator may include at least one of a Wifi module, a bluetooth module, a wired ethernet module, or other network communication protocol chip or a near field communication protocol chip, and an infrared receiver. The display apparatus 200 may establish transmission and reception of control signals and data signals with the control device 100 or the server 400 through the communicator 220.

In some embodiments, the detector 230 is used to collect signals of the external environment or interaction with the outside. For example, detector 230 includes a light receiver, a sensor for capturing the intensity of ambient light; alternatively, the detector 230 includes an image collector such as a camera, which may be used to collect external environmental scenes, user attributes, or user interaction gestures, or alternatively, the detector 230 includes a sound collector such as a microphone, or the like, which is used to receive external sounds.

In some embodiments, the external device interface 240 may include, but is not limited to, the following: high Definition Multimedia Interface (HDMI), analog or data high definition component input interface (component), composite video input interface (CVBS), USB input interface (USB), RGB port, etc. The input/output interface may be a composite input/output interface formed by a plurality of interfaces.

In some embodiments, the controller 250 and the modem 210 may be located in separate devices, i.e., the modem 210 may also be located in an external device to the main device in which the controller 250 is located, such as an external set-top box or the like.

In some embodiments, the controller 250 controls the operation of the display device and responds to user operations through various software control programs stored on the memory. The controller 250 controls the overall operation of the display apparatus 200. For example: in response to receiving a user command to select a UI object to be displayed on the display 260, the controller 250 may perform an operation related to the object selected by the user command.

A CPU processor. For executing operating system and application program instructions stored in the memory, and executing various application programs, data and contents according to various interactive instructions received from the outside, so as to finally display and play various audio and video contents. The CPU processor may include a plurality of processors.

In some embodiments, the CPU processor may include one main processor and one sub-processor. The main processor and the sub-processor may be packaged in one chip or may be packaged separately. The embodiment shown in fig. 3B is an embodiment in which the main processor and the sub-processor are packaged separately. In a separately packaged embodiment, the sub-processor is connected to the communicator at one end and to the main processor at one end. When the display device is configured in a standby state, the sub-processor acquires an instruction from the server through the communicator and wakes up the main processor according to the instruction.

In some embodiments, the communicator may be coupled to both the main processor and the sub-processor.

In some embodiments, a user may input a user command through a Graphical User Interface (GUI) displayed on the display 260, and the user interface receives the user input command through the Graphical User Interface (GUI). Alternatively, the user may enter a user command by entering a specific sound or gesture, and the user interface recognizes the sound or gesture through the sensor to receive the user input command.

In some embodiments, the user interface 280 is an interface (e.g., a physical key on the display device body, or the like) that may be used to receive input.

In some embodiments, a system of display devices may include a Kernel (Kernel), a command parser (shell), a file system, and an application program. The kernel, shell, and file system together form the basic operating system architecture that allows users to manage files, run programs, and use the system. After power-up, the kernel is started, the kernel space is activated, hardware is abstracted, hardware parameters are initialized, virtual memory, a scheduler, signal and inter-process communication (IPC) are operated and maintained. After the kernel is started, shell and user application programs are loaded again. The application program is compiled into machine code after being started to form a process.

Referring to FIG. 4, in some embodiments, the system is divided into four layers, from top to bottom, an application layer (simply "application layer"), an application framework layer (Application Framework) layer (simply "framework layer"), a An Zhuoyun row (Android run) and a system library layer (simply "system runtime layer"), and a kernel layer, respectively.

As shown in fig. 4, the application framework layer in the embodiment of the present application includes a manager (manager), a Content Provider (Content Provider), and the like, where the manager includes at least one of the following modules: an Activity Manager (Activity Manager) is used to interact with all activities that are running in the system; a Location Manager (Location Manager) is used to provide system services or applications with access to system Location services; a Package Manager (Package Manager) for retrieving various information about an application Package currently installed on the device; a notification manager (Notification Manager) for controlling the display and clearing of notification messages; a Window Manager (Window Manager) is used to manage bracketing icons, windows, toolbars, wallpaper, and desktop components on the user interface.

In some embodiments, the activity manager is used to manage the lifecycle of the individual applications as well as the usual navigation rollback functions, such as controlling the exit, opening, fallback, etc. of the applications. The window manager is used for managing all window programs, such as obtaining the size of the display screen, judging whether a status bar exists or not, locking the screen, intercepting the screen, controlling the change of the display window (for example, reducing the display window to display, dithering display, distorting display, etc.), etc.

In some embodiments, the system runtime layer provides support for the upper layer, the framework layer, and when the framework layer is in use, the android operating system runs the C/C++ libraries contained in the system runtime layer to implement the functions to be implemented by the framework layer.

In some embodiments, the kernel layer is a layer between hardware and software. As shown in fig. 4, the kernel layer contains at least one of the following drivers: audio drive, display drive, bluetooth drive, camera drive, WIFI drive, USB drive, HDMI drive, sensor drive (e.g., fingerprint sensor, temperature sensor, pressure sensor, etc.), and power supply drive, etc.

In some embodiments, the display device may directly enter the preset vod program interface after being started, where the vod program interface may include at least a navigation bar 510 and a content display area located below the navigation bar 510, as shown in fig. 5, where the content displayed in the content display area may change with the change of the selected control in the navigation bar. The program in the application program layer can be integrated in the video-on-demand program and displayed through one control of the navigation bar, and can be further displayed after the application control in the navigation bar is selected.

In some embodiments, the display device may directly enter the display interface of the signal source selected last time after being started, or the signal source selection interface, where the signal source may be a preset video on demand program, or may be at least one of an HDMI interface, a live tv interface, etc., and after the user selects a different signal source, the display may display the content obtained from the different signal source.

In some embodiments, the user may wake up the display device in close range via a remote control, far field speech, or the like. In some embodiments, the user and the display device have a certain distance, and the wake-up of the display device cannot be performed through the remote controller or far-field voice, so that the remote wake-up function can be provided for the display device. In some embodiments, remote wake-up is a process of enabling a display device to be woken up to enter a start-up state from a state to be woken up by sending a specific data packet to the display device in the state to be woken up (sleep state/standby state) by the network card in combination with other software and hardware.

In the related wake-up function, the television equipment is provided with a first module which is long connected with the server and a second module which is in a standby state, and after the first module receives a remote wake-up instruction, the second module is started to realize startup wake-up.

In some embodiments, waking up in the related art includes the second module restarting the system to cause the system to present a default home page. In some embodiments, the second module is started according to the cached STR data, so that the system presents the page before standby.

In some embodiments, standby refers to the display device being in a powered state, but the corresponding second module of the desktop system is not running, and the backlight is in an off state. The desktop system is a signal source of the display device, and the signal source of the display device may further include signal sources of HDMI, AV, DTV, and the like. By way of example, the signal source of the display device may include: any combination of JUUI desktop system, HDMI, AV, DTV.

However, the current remote wakeup can only realize remote wakeup of the smart television in a standby state to enable the smart television to start a default/prestored signal source, and cannot directly remotely wakeup an application on the smart television, after a user needs to wait for a display device to start the signal source, the user enables the started device to start the application corresponding to the instruction through a remote control instruction again. Resulting in a poor user experience.

In view of the foregoing, as shown in fig. 6, the present application provides a remote wakeup system including at least one display device 200, a server 400, and at least one mobile terminal 300A (only one mobile terminal is shown in the drawing).

Based on the remote wake-up system, the specific process of remote wake-up is as follows:

if a user turns on a certain display device in the system (which may be a display device turned on in a normal mode by a remote controller), a main chip (main processor) of the display device is in a start-up state. The low power chip (sub-processor) is in an inactive state. In this state, the main chip of the display device continuously reports the state information of the display device to the server. Specifically, the heartbeat data is uploaded, and the server determines that the display device is in a starting state according to the heartbeat data uploaded by the main chip. In some embodiments, the main chip is an implementation of the main processor and the low power chip is an implementation of the sub-processor. In some embodiments, the main processor and the sub-processor may be packaged in the same chip.

If the user turns off a certain display device in the system (the display device may be turned off by a remote controller so that the display device is in a standby state). The main chip of the display device is in a closed and non-started state, and the main chip triggers the low-power consumption chip to enter the starting state before entering the non-starting state. In this state, the low-power chip continuously uploads heartbeat data to the server, and the server determines that the display device is in a standby state according to the heartbeat data uploaded by the low-power chip. And the server generates an online list of the display equipment according to the equipment state information reported by the at least one display equipment.

In some embodiments, the low power chip is a chip that remains active after the main chip is turned off while the display device is standby. The computing power and power consumption of the chip are strongly related and the low power chip may be used only for implementing wake-related functions. By arranging the low-power chip, the state information of the display equipment can be continuously reported to the server on the premise of energy conservation.

In some embodiments, the main Chip may be a System-on-a-Chip (SOC) Chip, and the low power Chip may be a DSP (Digital Signal Processing, digital signal processing technology) Chip or an ARM core-M4 (an embedded processor developed by ARM corporation, uk).

In some embodiments, the low power chip may be integrated on the main chip, or may be separated from the main chip, which is not limited in the embodiments of the present application.

In some embodiments, the main processor has a functional unit in communication with the communicator, so that the sub-processor may be turned off when the main processor is started. The communicator transmits signals to the main processor when the main processor is started and transmits signals to the sub-processor when the sub-processor is started. When the main processor and the sub-processor work, different heartbeat data are sent to the server, so that the server confirms whether the display device is in a starting state or a standby state. In some embodiments, different heartbeat data may be different in characteristics of the heartbeat data, or may carry different characterization identifiers.

In some embodiments, the main processor does not contain a functional unit that communicates with the communicator, where it is desirable to maintain the sub-processors on while the processor is powered up. The communication from the main processor must pass through the sub-processor before it can be sent from the communicator, and the signal is received by the sub-processor.

In some embodiments, the sub-processor may send different heartbeat data depending on the switch state of the main processor.

In some embodiments, the sub-processor autonomously transmits the first heartbeat data to the server when the main processor is not operating, and transmits the heartbeat data of the main processor as the second heartbeat data to the server when the main processor is operating and does not transmit the first heartbeat data at this time.

In some embodiments, a target application is installed on the mobile terminal, such as a small-focus home application (audio-visual communication application), a fine-focus application (audio-visual application), a remote control application, and the like. Taking an audio and video communication application as an example, after a user opens a target application on a mobile terminal, a page data request (namely, a state query request) is sent to a server, and the server feeds back an online list of display equipment to the mobile terminal according to the page data request.

The target application of the mobile terminal refers to a mobile terminal version of the target application installed on the mobile terminal, and the target application of the display device is only a display device version of the target application installed on the display device. The example, the mobile phone end installed polite application and the television end installed polite application are different versions of the polite application made for different terminals.

In some embodiments, the target application is an application executing within an operating desktop system, illustratively, the desktop system is a system program of the television itself as one of the signal sources or a preset desktop application, and whenever the user starts the television, the system program is executed on the machine when the signal source is the desktop system, and the target application is a program installed in an application layer, which may be at least one of opened, installed, uninstalled, updated, etc. through a program management interface in the desktop system. If only the default desktop system of the television is started and the target application is not started, no thread is needed to execute the target application later, and the target application is started on the premise that the system program has the condition of starting other applications in the system program, and for a chip, the starting process of the chip is the process of loading the system program. The desktop system is started up with the start-up because of one of the signal sources of the display device at the time of desktop programming. For example, the desktop system may be a LINUX system or an Android system itself, which is used as a signal source. The method can also be a customized application preset on a LINUX system or an Android system, and an exemplary and best-looking desktop application is used as a signal source. The target application is an application that is opened/installed/uninstalled/updated through a program management interface in the desktop system, illustratively a small group home application.

In some embodiments, the mobile terminal may view the display device online list by opening the target application. The online list includes at least one control of the display device. The online list of the display devices comprises the display devices (the display devices for realizing the establishment of the association relation) which are authorized to be accessed by the current account (the account of the current mobile terminal logging in the target application). And in the online list of the display devices, corresponding state identifiers are presented according to the states of different display devices. In some embodiments, the server needs to conduct an authorized authentication process before the display device on-line list is presented.

In some embodiments, when the display device a is powered on, the master chip continuously reports the state information of the display device a to the server through networking, and the reported data can carry a label representing the power on of the display device, and an exemplary label of the master chip. Through the tag, the server can judge that the display device A is in a starting state.

In some embodiments, the low-power chip continuously reports the state information of the display device a to the server through networking when the display device B is standby, and the reported data can carry a label representing the standby state of the display device, and the label of the exemplary low-power chip. With this tag, the server can determine that the display device B is in the standby state.

In some embodiments, the display device C is in a power-off state (in a completely power-off state), so the server cannot receive the status information reported by the display device C, and the server may determine that the display device C is in the power-off state.

In some embodiments, the display device D, in order to continuously report the state information of the display device a to the server through the low-power chip no matter the display device is started or standby, the reported data may carry a tag indicating that the display device is standby or a tag indicating that the display device is started, which may be, for example, a tag indicating that the working state of the main chip is determined by communicating with the main chip.

And the server generates an online list of the display equipment according to the state information reported by each display equipment, and feeds back the online list of the display equipment to the mobile terminal. And simultaneously displaying an online list of the display device on a target application page of the mobile terminal. A user interface schematic of a mobile terminal as shown in fig. 7. The display device a is in an on state (power-on state), and displays the on-state identifier. And if the display equipment B is in a standby state, displaying a standby state identifier. The display device C is in an offline state (shutdown state), and displays the shutdown state identifier, or displays the offline state identifier.

The display device online list may contain all display devices that have been authorized to be accessible to the current account, i.e., contain the display devices in the three states described above. The display device presence list may also contain only display devices in the presence state and standby state. The display device presence list may also contain only display devices in standby state. Therefore, on one hand, page resources are saved, and on the other hand, a user can conveniently select display equipment which can be awakened remotely.

In some embodiments, only when the display device can be connected to the network, the mobile terminal can send a wake-up instruction to the display device to wake up, and no instruction of near field communication (exemplary, infrared communication) is needed to send the instruction of near field communication to the television by other devices such as a smart speaker and the like which are in the same space as the television and can be remotely controlled in a near field manner.

In some embodiments, the status information reported by the display device to the server is in the form of heartbeat packets. The display device periodically sends heartbeat data packets to the server, and the server judges whether the display device is in an on-line state or a standby state. If the preset time threshold is exceeded, for example, more than one minute, and the server does not receive the heartbeat data packet sent by the display device, the display device is judged to be in an offline state. The server feeds back the updated online list of the display device to the mobile terminal, and the mobile terminal changes the state identifier of the display device into an offline state identifier on a user interface. This may be the case when the user suddenly pulls off the power cord of the display device, causing the display device to enter an off-line state from a standby state.

In some embodiments, after the user views the online list of display devices on the target application interface of the mobile terminal, the user may select a display device that needs to be connected. The mobile terminal generates a connection request according to the selection of the user and sends the connection request to the server. The generated connection request carries device information of the selected display device.

In some embodiments, a first connection request is sent to a server if a display device selected by a user on a target application interface of a mobile terminal is in a power-on state in response to a selected operation with the user. The first connection request carries device information of the display device. After receiving the first connection request, the server searches the corresponding display equipment according to the equipment information. The server further generates a first wake-up instruction according to the device state of the display device, and sends the first wake-up instruction to the corresponding display device. Since the display device is in a power-on state, the first wake-up instruction is only used for starting the target application. And finally, the processor of the display device controls the target application to be started according to the first wake-up instruction.

In some embodiments, the communicator of the display device receives and transmits the first wake-up instruction to the master chip. And the main chip responds to the identification of the target application in the first wake-up instruction and starts the target application.

In some embodiments, the first wake-up instruction may be a target application start-up instruction when the display device is in a power-on state.

In some embodiments, in response to a selection operation with the user, a second connection request is sent to the server if the display device selected by the user on the target application interface of the mobile terminal is in a standby state. The second connection request carries device information of the display device. After receiving the second connection request, the server searches the corresponding display equipment according to the equipment information. The server further generates a second wake-up instruction according to the device state of the display device, and sends the second wake-up instruction to the corresponding display device. Since the display device is in the standby state, the second wake-up instruction is used for not only starting the target application, but also controlling the display device to enter the start-up state from the standby state. The processor of the display device firstly controls the display device to enter a starting state from a standby state according to the second wake-up instruction, and then controls the target application to be started according to the second wake-up instruction. In some embodiments, the first connection request and the second connection request may be the same, and exemplary device ID information of the display device is included, but device status information of the display device is not included. Since the server stores the device status information of each display device, when the server receives the connection request, the server can search the stored device status information for the device status information corresponding to the device ID information according to the device ID information. For example, the first connection request carries device ID information of the display device a. After receiving the first connection request, the server searches the equipment state information of the display equipment A to be in a starting state according to the equipment ID information of the display equipment A. The server can generate a corresponding first wake-up instruction for the starting-up state according to the equipment state information. When the equipment state of the A is the standby state, the server can generate a corresponding second wake-up instruction for the standby state according to the equipment state information. In some embodiments, the device state information may include one of a power on state identification, a standby state identification.

In some embodiments, since the mobile terminal may obtain the device status information of each display device from the server, the first connection request and the second connection request in the embodiments of the present application may also be different, which includes, for example, display device information and/or device status information. After the server acquires the connection request, the server does not need to search the corresponding equipment state information according to the equipment ID information. For example, the second connection request carries the device state information of the display device B in a standby state, and the server may generate a corresponding second wake-up instruction according to the device state information in the standby state.

In some embodiments, the first connection request and the second connection request may be different, and illustratively, the first connection request further includes a first string for characterizing that only the target application is launched, although both include device information of the display device and/or the target application identification. The second request includes a second string for characterizing the need to boot and launch the target application.

In some embodiments, the second wake-up instruction may include a power-on instruction and a first wake-up instruction (target application start-up instruction) when the display device is in a standby state. The processor controls the display device to enter a starting state (namely, a software system is started) from a standby state according to the starting instruction, and then controls the target application to be started according to the target application instruction.

In some embodiments, if the display device selected by the user on the target application interface of the mobile terminal is in a power-on state, the main chip of the display device is in a power-on state. The server directly sends a first wake-up instruction to the main chip, wherein the first wake-up instruction is a target application starting instruction. And the main chip controls the opening of the target application according to the opening instruction of the target application.

In some embodiments, when the target application is an audio-video communication application, the connection request (the first connection request and/or the second connection request) further includes a session request identifier, where the session request identifier is used to establish a session connection between the display device ID and the mobile terminal ID for the server.

In some embodiments, the state of the display device in the list presented on the mobile terminal may be marked as one of an on-line state (first state), a standby state (second state), a power-off state (third state). The first processor is started in an on-line state, the first processor is not started in a standby state, and the first processor and the second processor are not started in a shutdown state.

In some embodiments, the mobile terminal receives an operation instruction input by a user, determines a state of the display device, sends a connection request that does not include the state of the display device to the server when the display device is in a power-on state or a standby state, and displays a non-connectable prompt message when the display device is in a power-off state.

In some embodiments, after receiving the connection request, when the connection request does not carry the display device status identifier, the server queries the status of the display device according to the display device ID in the connection request, where the status of the display device is stored in a relationship between the display device ID and the display status established by the server according to the heartbeat connection of the display device.

In some embodiments, after receiving the connection request, the server determines the state of the display device according to the display device state identifier carried in the connection request.

In some embodiments, the server generates a wake-up instruction according to the ID of the display device and the state of the display device, generates a wake-up instruction including a start-up instruction and a start-up target application instruction when the state of the display device is a standby state, and generates a wake-up instruction including a start-up target application instruction not including a start-up instruction when the state of the display device is a start-up state. And sending the generated wake-up instruction to the display device.

In some embodiments, when the state of the display device is a power-off state, the server feeds back a message to the mobile terminal that the display device cannot respond.

In some embodiments, when the target application is an audio-video application, the server determines whether to create a virtual session room based on the session request identification and the state of the display device.

In some embodiments, when the display device is in a power-on or standby state, a virtual room is created for a session of the display device and the mobile terminal according to the display device identifier and the mobile terminal identifier, and a waiting instruction is fed back to the mobile terminal, so that the mobile terminal responds to and waits for a session waiting interface to be displayed.

In some embodiments, when the state of the display device is in a power-off state, the server does not create a virtual room according to the display device identifier and the mobile terminal identifier session, and feeds back a prompt message to the mobile terminal that the display device cannot access. In some embodiments, the non-access hint message may be different from or the same as the non-responsive message.

In some embodiments, after the server creates the conversational virtual room, instructions to access the conversation are sent to the display device to cause the display device to join the audio video conversation.

In some embodiments, the instruction of accessing the session is issued to the mobile terminal as a part of the wake-up instruction, the mobile terminal receives and caches the instruction of accessing the session, and after the preset audio-video communication application is started, the preset audio-video communication application responds to the instruction of accessing the session to join the session, or displays a prompt message.

In some embodiments, the instruction of accessing the session is not issued to the mobile terminal together with the wake-up instruction, after the display device starts the preset audio and video communication application, an identification representing that the application is started up to completion is sent to the server, and the instruction of the server for responding to the access session fed back with the identification representing that the application is started up to completion is received.

The session procedure and the closing procedure after subsequent establishment of the session connection can be referred to the patent previously filed by the applicant.

In some embodiments, the server may not set a virtual room, only the access port is reserved with the mobile terminal and the display device, the display device uploads the audio-video data to the designated port, the server stores the audio-video data uploaded by the display device and the unique identifier of the display device, and the mobile terminal polls the designated window according to the unique identifier of the display device and acquires the uploaded impression data.

In some embodiments, after setting the virtual session room, the server sends a wake-up instruction to the display device, where the wake-up instruction further includes a room identifier of the virtual session room. And after the display equipment starts the target application, joining the virtual session room according to the room identification so as to establish the audio-video session.

In some embodiments, if the display device selected by the user on the target application interface of the mobile terminal is in a standby state, the main chip of the display device is in an inactive state and the low power chip is in an active state. The server sends a second wake-up instruction to the display device, and the communicator of the display device receives and sends the second wake-up instruction to the low-power chip, wherein the second wake-up instruction comprises a starting instruction and a target application starting instruction. The low-power consumption chip firstly controls the main chip to enter a starting state from a non-starting state according to the starting instruction and simultaneously caches a target application starting instruction. After the main chip enters the starting state from the non-starting state, the state result is fed back to the low-power consumption chip. And after the low-power consumption chip receives the state result of the main chip as the starting state, the target application starting instruction in the second wake-up instruction is sent to the main chip. And finally, the main chip controls the opening of the target application according to the opening instruction of the target application. It should be noted that, after completing the process of sending the target application start command to the main chip, the low power chip may maintain the start state. In order to reduce the resource occupation, the main chip can send a closing instruction to the low-power consumption chip after receiving the target application opening instruction, so that the low-power consumption chip enters an un-started state from a started state according to the closing instruction.

In some embodiments, a level signal may be sent within the low power chip to a designated interface/pin of the host chip in response to a power-on command to wake up the start-up of the host chip.

In some embodiments, the low-power chip may further cache the session request instruction, and may send the target application start instruction and the session request instruction to the main chip together after the main chip is started, where the main chip first responds to the target application start instruction to start the target application, and after the target application is started, makes the target application respond to the session request instruction. In some embodiments, after receiving the message of the target application start completion fed back by the master chip, the session request instruction may also be sent to the master chip, so that the master chip controls the target application to respond to the session request instruction.

In some embodiments, the target application start instruction further carries peer invitation information corresponding to the mobile terminal. After the target application is opened, the opposite end invitation information is received, and the opposite end invitation information is analyzed, so that the connection between the target application of the mobile terminal and the target application of the display equipment is established.

In some embodiments, after the target application is started, in response to the session request instruction, the display device displays a reminder message on the display device, where the reminder message is used to remind the display device whether to accept the session request, after receiving an operation instruction that is not received by the user, the display device feeds back a reject identifier to the server, so that the server feeds back a message that the display device does not join the audio-video session to the mobile terminal, and after receiving the operation instruction received by the user, the display device feeds back an agreeable identifier to the server, so as to establish session connection.

In some embodiments, the target application response of the display device automatically responds with a session request instruction to automatically establish the session connection.

In some embodiments, when the server receives a connection request containing a session request identifier, session authentication is performed according to the unique identifier of the display device and the unique identifier of the mobile terminal, whether the session can be automatically established or not, and when the unique identifier of the mobile terminal is authorized by the unique identifier of the display device in the relation with the stored server side, a virtual session room is established and a subsequent procedure is executed. If not, a virtual room is not established, and information is fed back to the mobile terminal to remind the mobile terminal that the display device is not authorized.

In some embodiments, after the display device favors starting the target application, the secondary authentication can be performed for whether the session can be automatically established according to the unique identifier of the display device and the unique identifier of the mobile terminal.

In some embodiments, a router is disposed between the display device and the server. The device information includes an IP address of the display device, a router port number used by the display device, and a MAC address of the display device. And the server sends a wake-up data Packet (which may be a Magic Packet unicast Packet) to the corresponding router according to the IP address of the display device and the router port number contained in the connection request. And after receiving the wake-up data packet, the router identifies the wake-up data packet as a directional broadcast packet. The router broadcasts this broadcast packet to all ports, and the broadcast packet contains the MAC address of the display device. After receiving the broadcast packet, the display device corresponding to the MAC address wakes up the target application of the display device. And after receiving the broadcast packet, the display equipment of other MAC addresses connected with the router directly discards the data packet.

The target application is an application of a small-focus home, a display device needing to be connected is selected on the application of the small-focus home of the mobile terminal, the selected display device can directly open the application of the small-focus home after receiving an opening instruction of the application of the small-focus home, and the connection is established with the mobile terminal through the application of the small-focus home. The home environment can also be monitored by using a camera of the display device.

After the user starts the display device list page, the user may display an interface as shown in fig. 7, where the display devices a-C are marked with their own power-on states for visual display to the user.

The user selects the display device B in the mobile terminal user interface shown in fig. 7, and enters the user interface shown in fig. 8 from the user interface shown in fig. 7 in response to a control instruction indicating the selection of the display device B by the user. The user interface shown in fig. 8 includes a monitoring screen and setting controls for a small group home application. At this time, the mobile terminal and the display device B have not yet established a connection, and a "see home" control for confirming establishment of a connection with the display device B is displayed in the monitor screen shown in fig. 8.

When the user selects the "see home" control, a connection request is sent to the server in response to a control instruction that the user instructs to select the "see home" control. The connection request carries device information of the display device B. The server generates a connection instruction (second wake-up instruction) from the device information of the display device B. Since the display device B is in the standby state, the server first transmits a connection instruction to the low power consumption chip of the display device B. The low-power chip analyzes the starting instruction and the target application starting instruction from the connection instruction. The low-power chip firstly sends a starting instruction to the main chip to trigger the main chip to enter a starting state from a non-starting state.

After the main chip is started to enter the attractive desktop system, a starting result is fed back to the low-power chip, and the target application starting instruction analyzed by the low-power chip sub-office continues to send the target application starting instruction to the main chip. The target application opening instruction is an instruction for opening the small-focus home application. And after receiving an instruction for opening the small-focus home application, the main chip executes business logic for opening the small-focus home application. The target application opening instruction also comprises opposite end invitation information sent by the mobile terminal. And the main chip sends the service instruction to the small-aggregation home application, and the small-aggregation home application analyzes the opposite-end invitation information from the service instruction. The peer invitation information may include device information of the mobile terminal. And according to the opposite-end invitation information, a communication connection is established between the mobile terminal and the display equipment B through the small-focus home application.

After the mobile terminal and the display equipment B are in communication connection, the display equipment B sends the pictures shot by the camera in real time to the mobile terminal. As shown in fig. 9, the mobile terminal can view the picture shot by the camera of the display device B in real time, so as to realize the function of remote monitoring.

In some embodiments, if the selected display device a, the server generates a start connection instruction (first wake-up instruction) according to the device information of the display device a. Since the display device a is in the on state, the server directly transmits the connection instruction to the main chip of the display device a. And the main chip analyzes the target application opening instruction, and responds to the target application opening instruction to execute the business logic of opening the small-focus home application.

In some embodiments, if the selected display device a, the server generates a start connection instruction (first wake-up instruction) according to the device information of the display device a. Because the display equipment A is in a starting-up state, the server directly sends the connection instruction to the low-power chip, and the low-power chip forwards the connection instruction to the main chip of the display equipment A. And the main chip analyzes the target application opening instruction, and responds to the target application opening instruction to execute the business logic of opening the small-focus home application.

In some embodiments, if the selected display device a, the server generates a start connection instruction (first wake-up instruction) according to the device information of the display device a. Because the display equipment A is in a starting state, the server directly sends the connection instruction to the low-power chip, the low-power chip analyzes the target application starting instruction, and the target application starting instruction is sent to the main chip of the display equipment A. And the main chip is used for executing the business logic of the opening small-focus home application in response to the opening instruction of the target application.

In some embodiments, the server includes a business system and an AIOT (artificial intelligence internet of things) system, and the low power chip and the main chip report display device status information to the AIOT system. The AIOT system sends the state information to the service system, and the service system packages the state information to generate an online list of the display equipment. And the mobile terminal directly acquires the related information of the online list of the display device from the service system. In some embodiments, when the mobile terminal sends the same connection request in a standby or starting state of the display device, the server generates and sends an instruction for starting the target application according to the unique identifier of the display device in the received connection request, wherein the instruction for starting the target application is used for controlling the main processor to start a preset application, the communicator of the display device receives the instruction for starting the target application and sends the instruction for starting the target application to the main processor when the main processor is started, the main processor responds to the instruction for starting the target application and sends the instruction for starting the target application to the sub-processor when the main processor is not started, and the sub-processor generates the starting instruction according to the instruction for starting the target application and caches the instruction for starting the target application, so that the main processor is started and the main processor after the starting starts the target application.

In some embodiments, the instruction for starting the target application may be a call request including information such as a unique identifier of the mobile terminal, virtual room information, and a session request instruction.

In some embodiments, host processor startup refers to the host processor loading an operating system (e.g., any of the android operating system, the apple operating system, the hong operating system, etc.). The operating state of the main processor refers to the state in which the operating system in the main chip is running. Starting the target application refers to starting an application in the operating system of the host processor.

Based on the foregoing embodiments, an embodiment of the present application provides an application wake-up method of a display device, as shown in a signaling diagram of the application wake-up method of the display device in fig. 10, where the method includes the following steps:

step one, a user opens a target application user interface on a mobile terminal, and selects display equipment in the target application user interface. And the mobile terminal receives a control instruction which is input by a user and selects the display device.

And step two, responding to the control instruction by the mobile terminal, and generating a first connection request when the display equipment is in a starting-up state, wherein the equipment state of the display equipment pointed by the first connection request is the starting-up state. The mobile terminal sends a first connection request to a server, and the server generates a first wake-up instruction according to the first connection request and sends the first wake-up instruction to a corresponding display device. And the processor of the display device controls the target application to be started according to the first wake-up instruction.

And step four, generating a second connection request when the display equipment is in a standby state, wherein the equipment state of the display equipment pointed by the second connection request is the standby state. The mobile terminal sends a second connection request to the server, and the server generates a second wake-up instruction according to the second connection request and sends the second wake-up instruction to the corresponding display equipment. And the processor of the display device controls the display device to enter the starting state from the standby state according to the second wake-up instruction, and then controls the target application to be started according to the second wake-up instruction.

In the above method embodiment, the online list of the display device is displayed on the target application user interface of the mobile terminal. The display device online list is a list generated by the server according to the state information reported by at least one display device. After a user opens a target application user interface on the mobile terminal, the mobile terminal sends a page data request related to the target application to a server, and the server feeds back an online list of the display device to the mobile terminal according to the page data request.

The embodiment of the application provides another application wake-up method of the display device, the display device is connected with the network through the main chip when being started up, is connected with the network through the low-power chip when being standby,

A signaling diagram of an application wake-up method of a display device as shown in fig. 11, the method comprising the steps of:

when the display equipment is in a starting state, the main chip is in a starting state, the low-power chip is in an un-starting state, and the main chip continuously reports equipment state information (uploads heartbeat data) to the server. When the display device enters a standby state from a starting state, the main chip enters an unactuated state from an actuated state. And triggering the low-power consumption chip to enter the starting state from the starting state before the main chip enters the starting state from the starting state. The low-power chip continuously reports the equipment state information to the server. And the server generates an online list of the display equipment according to the equipment state information reported by the at least one display equipment.

And step two, the user opens a target application on the mobile terminal, such as a small-focus home application. The mobile terminal transmits a page data request to the server in response to an operation of a user. And the server feeds back an online list of the display device to the mobile terminal according to the page data request. After the mobile terminal receives the display device online list, the display device online list is presented on the user interface (step one and step two are not shown in fig. 11).

And step three, the mobile terminal receives a control instruction which is input by a user and selects the display equipment. And the mobile terminal responds to the control instruction, and generates a first connection request if the selected display device is in a starting-up state, wherein the device state of the display device pointed by the first connection request is the starting-up state. The mobile terminal sends a first connection request to a server, and the server generates a first wake-up instruction according to the first connection request and sends the first wake-up instruction to a corresponding display device. The server sends a first wake-up instruction to the selected main chip of the display device to be waken up. And the main chip controls the target application to be started according to the first wake-up instruction (namely the target application starting instruction).

And step four, if the selected display equipment is in a standby state, the server generates a second wake-up instruction according to the connection request, wherein the second wake-up instruction comprises a start-up instruction and a first wake-up instruction. And the server sends the starting-up instruction and the first awakening instruction to the low-power-consumption chip of the selected display equipment to be awakened.

The low-power chip triggers the main chip to start according to the starting instruction. After the main chip is started, a starting result is fed back to the low-power consumption chip. And after the low-power consumption chip receives the starting result, the low-power consumption chip continuously sends a first wake-up instruction to the main chip. The first wake-up instruction is associated with a small group of home applications. And the main chip executes logic for opening the small-focus home application according to the first wake-up instruction, and meanwhile, opposite-end invitation information carried by the first wake-up instruction is sent to the small-focus home application. And after the small-focus home application is opened, establishing communication connection with the mobile terminal according to the opposite-end invitation information.

After the mobile terminal and the display equipment are in communication connection, the display equipment sends the pictures shot by the camera in real time to the mobile terminal. As shown in fig. 9, the mobile terminal can view the picture shot by the camera of the display device B in real time, so as to realize the function of remote monitoring.

In some embodiments, when the display device is turned on or standby, the request generated by the mobile terminal is the same, and the server generates different wake-up instructions according to the request and different states of the display device.

In some embodiments, the mobile terminal may be replaced by a display device, which may also be replaced by the mobile terminal.

The same or similar content may be referred to each other in various embodiments of the present application, and the related embodiments are not described in detail.

The foregoing description, for purposes of explanation, has been presented in conjunction with specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the embodiments to the precise forms disclosed above. Many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles and the practical application, to thereby enable others skilled in the art to best utilize the embodiments and various embodiments with various modifications as are suited to the particular use contemplated.

Claims (11)

1. A mobile terminal, comprising:

   a communication interface for communication between the processor and a server;

   a processor for:

   responding to the received operation, displaying an online list of the display equipment, wherein a display equipment control in the online list is marked as one of a starting state, a standby state or a closing state, the starting state represents a state that a main processor of the corresponding display equipment, which is provided with an operating system, is in a starting state, the standby state represents a state that the main processor of the corresponding display equipment is in a non-starting state but a sub-processor is in a starting state, and the main processor of the corresponding display equipment is in a non-starting state and the sub-processor is in a non-starting state;

   receiving an operation of a first display device control in the online list;

   when the first display device control is marked as a starting state or a standby state, a connection request is sent to the server, wherein the connection request comprises a first display device identifier of a first display device corresponding to the first display device control, the connection request is used for starting a target application in the first display device, and call connection is established through the target application;

   And when the first display device control is marked as a power-off key state, displaying prompt information representing that the first display device is not connectable.
2. The mobile terminal of claim 1, the sending a connection request when the first display device control is marked as either on or standby comprises:

   when the first display equipment control is marked as a starting-up state, a first connection request is sent to a server, wherein the connection request comprises a starting-up state identifier in addition to a first display equipment identifier;

   and when the first display device control is marked as a standby state, sending a second connection request to the server, wherein the connection request comprises a standby state identifier besides the first display device identifier.
3. A server comprising a memory and a processor, the processor to:

   receiving a connection request sent by a mobile terminal, wherein the connection request comprises a first display device identifier of a first display device corresponding to the first display device control;

   responding to the connection request, establishing a virtual session room, and feeding back a message representing waiting for connection to the mobile terminal;

   And sending a wake-up instruction to the first display device, wherein the wake-up instruction comprises a room identifier corresponding to the virtual session room, and the wake-up instruction is used for enabling the first display device to start a target application and enabling the target application in the first display device to establish session connection according to the room identifier.
4. The server of claim 3, the sending a wake-up instruction to the first display device comprising:

   when the first display device is determined to be in a starting state, a first wake-up instruction is sent to the first display device, wherein the first wake-up instruction comprises an instruction for starting a target application and a room identifier corresponding to the virtual session room, the instruction for starting the target application is used for enabling a main processor in the first display device to start the target application, and the target application is used for establishing session connection according to the room identifier after starting;

   and when the first display device is in a standby state, sending a second wakeup instruction to the first display device, wherein the second wakeup instruction comprises a starting instruction, an instruction for starting a target application and a room identifier corresponding to the virtual session room, the starting instruction is used for enabling a sub-processor in the first display device to control a main processor in the first display device to start, the instruction for starting the target application is used for enabling the main processor in the first display device to start the target application, and the target application is used for establishing session connection according to the room identifier after starting.
5. The server according to claim 4,

   the processor determines the state of the display device according to a preset relation and a first display device identifier in the connection request, wherein the preset relation is a mapping relation between the display device identifier and the display device state determined according to heartbeat connection of the display device and the server.
6. The server of claim 4, the connection request comprising a power-on status identifier or a standby status identifier in addition to the first display device identifier;

   when the connection request contains a starting-up state identifier, the processor determines that the display equipment is in a starting-up state;

   and the processor determines that the display equipment is in a standby state when the connection request contains a standby state identifier.
7. A display device, comprising:

   a display;

   a communicator for: receiving a wake-up instruction, wherein the wake-up instruction is sent to a main processor of the display device when the main processor is in a starting state, and is sent to a sub-processor when the main processor of the display device is in an un-starting state and the sub-processor is in a starting state, and the wake-up instruction comprises an instruction for starting a target application;

   The main processor is configured to: after receiving the wake-up instruction, starting a target application corresponding to the instruction for starting the target application;

   the sub-processor is configured to: and after receiving the wake-up instruction, controlling the main processor to start, and sending the instruction for starting the target application to the main processor.
8. The display device of claim 7, the controlling the main processor to initiate comprising:

   responding to the received wake-up instruction and generating a start-up instruction;

   and controlling the main processor to start according to the starting instruction.
9. The display device of claim 7, the wake-up instruction comprising receiving a first wake-up instruction and receiving a second wake-up instruction, wherein the first wake-up instruction comprises an instruction to launch the target application, excluding a boot-up instruction, and the second wake-up instruction comprises an instruction to launch the target application and a boot-up instruction;

   sending the wake-up instruction to the main processor includes: sending the first wake-up instruction to the main processor;

   sending the wake-up instruction to the sub-processor includes: sending the second wake-up instruction to the sub-processor;

   The controlling the main processor to start comprises: and controlling the main processor to start according to the starting instruction in the second wake-up instruction.
10. The display device of claim 7, the

    The wake-up instruction further includes: room identification corresponding to the virtual session room;

    the main processor is further configured to: and responding to the room identification of the virtual session room received from the communicator or the room identification of the virtual session room received from the sub-processor, and controlling the target application to establish session connection according to the room identification of the virtual session room after the target application is started.
11. An application wake-up method, the method comprising:

    receiving a connection request sent by a mobile terminal, wherein the connection request comprises a first display device identifier of a first display device corresponding to the first display device control;

    when the first display device is determined to be in a starting state, a first wake-up instruction is sent to the first display device, wherein the first wake-up instruction comprises an instruction for starting a target application, and the instruction for starting the target application is used for enabling a main processor in the first display device to start the target application;

    And when the first display device is in a standby state, sending a second wakeup instruction to the first display device, wherein the second wakeup instruction comprises a starting instruction and an instruction for starting a target application, the starting instruction is used for enabling a sub-processor in the first display device to control a main processor in the first display device to start, and the instruction for starting the target application is used for enabling the main processor in the first display device to start the target application.