CN113077909B - Display device, control apparatus, and abnormality processing method - Google Patents

Abstract

The application discloses a display device, a control device and an exception handling method. The display device monitors whether user contact abnormality occurs in the process of collecting user health data based on contact between the user and the touch area; if the user contact abnormality occurs, detecting whether the user is contacted with the touch area again within a preset time period after the user contact abnormality occurs; if the user is detected to be in contact with the touch area again within the preset time, the health data of the user are continuously collected until the data collection time reaches the preset collection time. Therefore, in the process of collecting the user health data, if the user contact is temporarily disconnected, the user can also continue to collect the data, so that the operation difficulty of the user is reduced, and the data collection failure caused by the short contact failure or improper operation is avoided. In addition, the user pressure can be reduced, the tension mood of the user is avoided, and the user experience is improved.

Description

Display device, control apparatus, and abnormality processing method

Technical Field

The present disclosure relates to the field of display devices, and in particular, to a display device, a control device, and an exception handling method.

Background

The continuous development of communication technology makes terminal devices such as computers, smart phones, display devices and the like more and more popular. In addition, the requirements of users on functions or services provided by the terminal equipment are also increasing. Display devices, such as smart televisions, can provide users with play pictures, such as audio, video, pictures, etc., and are now of great interest.

With the popularization of display devices, functions provided by the display devices can influence and change lives of users, and demands of users for life, entertainment and leisure through the display devices are also becoming stronger. Based on the increasing attention and importance of families to member personal health conditions and health maintenance modes, how to monitor, record and improve user health through display equipment is a technical problem to be solved at present.

Disclosure of Invention

The application provides a display device, a control device and an exception handling method.

In a first aspect, the present application provides a display device, comprising:

a display;

a controller configured to:

monitoring whether user contact abnormality occurs in the process of collecting user health data based on the contact between the user and the touch area;

if the user contact abnormality occurs, detecting whether the user is contacted with the touch area again within a preset time period after the user contact abnormality occurs;

And if the user is detected to be in contact with the touch area again within the preset time, continuing to acquire the health data of the user until the data acquisition time reaches the preset acquisition time.

In a second aspect, the present application further provides a control device, including:

a touch area;

the touch area is used for being contacted with the user, and the health data acquisition module is used for acquiring health data of the user based on the contact between the user and the touch area;

a controller in communication with the health data acquisition module and the contact detection module configured to:

responding to a data acquisition instruction sent by display equipment, and controlling the health data acquisition module to start acquiring user health data;

every other preset time length, sending a health data packet containing the latest user health data and an abnormality identification to display equipment, wherein the abnormality identification is used for representing whether abnormality detection and abnormality type exist or not;

and when the contact detection module detects that the user is in contact with the touch area again, the health data packet containing the latest user health data and the abnormal mark representing no detection abnormality is sent to the display device.

In a third aspect, the present application further provides an exception handling method, applied to a display device, where the method includes:

monitoring whether user contact abnormality occurs in the process of collecting user health data based on the contact between the user and the touch area;

if the user contact abnormality occurs, detecting whether the user is contacted with the touch area again within a preset time period after the user contact abnormality occurs;

and if the user is detected to be in contact with the touch area again within the preset time, continuing to acquire the health data of the user until the data acquisition time reaches the preset acquisition time.

In a fourth aspect, the present application further provides an anomaly handling method applied to a control device, where the control device includes a touch area, the method including:

responding to a data acquisition instruction sent by the display equipment, and acquiring user health data based on contact between a user and the touch area;

every other preset time length, sending a health data packet containing the latest user health data and an abnormality identification to display equipment, wherein the abnormality identification is used for representing whether abnormality detection and abnormality type exist or not;

and when the user is detected to be in contact with the touch area again, the health data packet containing the latest user health data and the abnormal mark representing no detection abnormality is sent to the display device.

According to the technical scheme, the application provides a display device, a control device and an exception handling method. The display device monitors whether user contact abnormality occurs in the process of collecting user health data based on contact between the user and the touch area; if the user contact abnormality occurs, detecting whether the user is contacted with the touch area again within a preset time period after the user contact abnormality occurs; if the user is detected to be in contact with the touch area again within the preset time, the health data of the user are continuously collected until the data collection time reaches the preset collection time. Therefore, in the process of collecting the user health data, if the user contact is temporarily disconnected, the user can also continue to collect the data, so that the operation difficulty of the user is reduced, and the data collection failure caused by the short contact failure or improper operation is avoided. In addition, the user pressure can be reduced, the tension mood of the user is avoided, and the user experience is improved.

Drawings

In order to more clearly illustrate the technical solutions of the present application, the drawings that are needed in the embodiments will be briefly described below, and it will be obvious to those skilled in the art that other drawings can be obtained from these drawings without inventive effort.

FIG. 1 is a use scenario of a display device shown in some embodiments of the present application;

fig. 2 is a hardware configuration block diagram of the control apparatus 100 shown in some embodiments of the present application;

fig. 3 is a hardware configuration block diagram of a display device 200 shown in some embodiments of the present application;

FIG. 4 is a software configuration diagram in a display device 200 shown in some embodiments of the present application;

FIG. 5A is another use scenario of a display device shown in some embodiments of the present application;

FIG. 5B is a schematic diagram of the appearance of a remote control according to some embodiments of the present application;

FIG. 6 is a schematic diagram of an interaction process of a display device with a remote control, as shown in some embodiments of the present application;

FIG. 7 is a launch page of an application shown in some embodiments of the present application;

FIG. 8 is a user protocol presentation page of an application shown in some embodiments of the present application;

FIG. 9 is an application front page of an application shown in some embodiments of the present application;

FIG. 10 is a profile information input interface as shown in some embodiments herein;

FIG. 11 is a archive management interface shown in some embodiments herein;

FIG. 12 is a schematic diagram of an interaction process of a display device with a remote control, as shown in some embodiments of the present application;

FIG. 13 is an operator guidance interface shown in some embodiments herein;

FIG. 14 is another operator guidance interface shown in some embodiments herein;

FIG. 15 is a schematic diagram of an interaction process of a display device with a remote control, as shown in some embodiments of the present application;

FIG. 16 is another operator guidance interface shown in some embodiments herein;

FIG. 17 is a schematic diagram of an interaction process of a display device with a remote control, as shown in some embodiments of the present application;

FIG. 18 is a detection interface shown in some embodiments herein;

FIG. 19 is an anomaly prompt interface shown in some embodiments herein;

FIG. 20 is a test results interface shown in some embodiments herein;

FIG. 21 is another test result interface shown in some embodiments herein;

FIG. 22 is a method of exception handling as shown in some embodiments of the present application.

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.

It should be noted that the brief description of the terms in the present application is only for convenience in understanding the embodiments described below, and is not intended to limit the embodiments of the present application. Unless otherwise indicated, these terms should be construed in their ordinary and customary meaning.

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.

The terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a product or apparatus that comprises a list of elements is not necessarily limited to all elements explicitly listed, but may include other elements not expressly listed or inherent to such product or apparatus.

The term "module" refers to any known or later developed hardware, software, firmware, artificial intelligence, fuzzy logic, or combination of hardware or/and software code that is capable of performing the function associated with that element.

The application provides a terminal device, which can be a display device such as an intelligent television and a touch control integrated machine, and can also be a portable mobile terminal such as a mobile phone and a tablet personal computer. For convenience of explanation, the following mainly uses a display device as an example to describe a specific implementation of the technical solution related to the embodiment of the present application.

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 one of a mobile terminal, tablet, computer, notebook, 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, the display device 200 is also in data communication with a server 400. The display device 200 may be permitted to make communication connections via a Local Area Network (LAN), a Wireless Local Area Network (WLAN), and other networks. The server 400 may provide various contents and interactions to the display device 200. The server 400 may be a cluster, or may be multiple clusters, and may include one or more types of servers.

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 may perform 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.

In some embodiments, the control device 100 further comprises a health data acquisition module 150 for acquiring user health data including heart rate, blood oxygen status, systolic pressure, diastolic pressure, etc.

In some embodiments, the control device 100 further includes a contact detection module 160 coupled to a touch area on the control device housing for detecting contact entered by a user on the touch area.

In some embodiments, the health data acquisition module and the contact detection module communicate with the controller 110 via a serial port.

In some embodiments, the control device 100 shown in fig. 2 may be a remote control.

Fig. 3 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 controller comprises a central processor, a video processor, an audio processor, a graphics processor, RAM, ROM, a first interface for input/output to an nth 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, the modem 210 receives broadcast television signals via wired or wireless reception and demodulates audio-video signals, such as EPG data signals, from a plurality of wireless or wired broadcast television signals.

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 display device outer surface is provided with a touch area for receiving user contact.

In some embodiments, the detector 230 further includes a health data acquisition module coupled to the touch area for acquiring user health data, such as heart rate, blood oxygen status, systolic pressure, diastolic pressure, etc., based on user contact with the touch area. Alternatively, the health data collection module and the controller 250 may communicate through a serial port, for example, the controller 250 turns on or off a switch of the health data collection module through the serial port, and the health data collection module transmits the collected user health data to the controller 250 through the serial port.

For example, the touch area may be provided at a side of the display device or at a rear case surface. When the user touches a touch area on the side of the display device or the rear case surface, the touch pad detects a contact input by the user.

It should be noted that, for a portable terminal device (such as a mobile phone, a tablet computer, etc.) supporting fingerprint recognition, the health data collection module may be disposed below the fingerprint recognition area to connect with the fingerprint recognition area, so that user health data may be collected based on the contact between the user and the fingerprint recognition area. In addition, the health data acquisition module and the controller of the portable terminal device can communicate through a serial port before, for example, the terminal controller opens or closes a switch of the health data acquisition module through the serial port, and the health data acquisition module transmits the acquired user health data to the terminal controller through the serial port.

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, or the like. 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.

In some embodiments, the object may be any one of selectable objects, such as a hyperlink, an icon, or other operable control. The operations related to the selected object are: displaying an operation of connecting to a hyperlink page, a document, an image, or the like, or executing an operation of a program corresponding to the icon.

In some embodiments the controller includes at least one of a central processing unit (Central Processing Unit, CPU), video processor, audio processor, graphics processor (Graphics Processing Unit, GPU), RAM Random Access Memory, RAM), ROM (Read-Only Memory, ROM), first to nth interfaces for input/output, a communication Bus (Bus), and the like.

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. Such as one main processor and one or more sub-processors.

In some embodiments, a graphics processor is used to generate various graphical objects, such as: at least one of icons, operation menus, and user input instruction display graphics. The graphic processor comprises an arithmetic unit, which is used for receiving various interactive instructions input by a user to operate and displaying various objects according to display attributes; the device also comprises a renderer for rendering various objects obtained based on the arithmetic unit, wherein the rendered objects are used for being displayed on a display.

In some embodiments, the video processor is configured to receive an external video signal, perform at least one of decompression, decoding, scaling, noise reduction, frame rate conversion, resolution conversion, image composition, and the like according to a standard codec protocol of an input signal, and obtain a signal that is displayed or played on the directly displayable device 200.

In some embodiments, the video processor includes at least one of a demultiplexing module, a video decoding module, an image compositing module, a frame rate conversion module, a display formatting module, and the like. The demultiplexing module is used for demultiplexing the input audio and video data stream. And the video decoding module is used for processing the demultiplexed video signal, including decoding, scaling and the like. And an image synthesis module, such as an image synthesizer, for performing superposition mixing processing on the graphic generator and the video image after the scaling processing according to the GUI signal input by the user or generated by the graphic generator, so as to generate an image signal for display. And the frame rate conversion module is used for converting the frame rate of the input video. And the display formatting module is used for converting the received frame rate into a video output signal and changing the video output signal to be in accordance with a display format, such as outputting RGB data signals.

In some embodiments, the audio processor is configured to receive an external audio signal, decompress and decode according to a standard codec protocol of an input signal, and at least one of noise reduction, digital-to-analog conversion, and amplification, to obtain a sound signal that can be played in the speaker.

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

In some embodiments, a "user interface" is a media interface for interaction and exchange of information between an application or operating system and a user that enables conversion between an internal form of information and a form acceptable to the user. A commonly used presentation form of the user interface is a graphical user interface (Graphic User Interface, GUI), which refers to a user interface related to computer operations that is displayed in a graphical manner. It may be an interface element such as an icon, a window, a control, etc. displayed in a display screen of the electronic device, where the control may include at least one of a visual interface element such as an icon, a button, a menu, a tab, a text box, a dialog box, a status bar, a navigation bar, a Widget, etc.

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

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 (referred to as an "application layer"), an application framework layer (Application Framework layer) (referred to as a "framework layer"), a An Zhuoyun row (Android run) and a system library layer (referred to as a "system runtime layer"), and a kernel layer, respectively.

In some embodiments, at least one application program is running in the application program layer, and these application programs may be a Window (Window) program of an operating system, a system setting program, a clock program, or the like; but may also be an application developed by a third party developer, such as the health care application shown in fig. 4. In particular implementations, the application packages in the application layer are not limited to the above examples.

The framework layer provides an application programming interface (application programming interface, API) and programming framework for application programs of the application layer. The application framework layer includes a number of predefined functions. The application framework layer corresponds to a processing center that decides to let the applications in the application layer act. Through the API interface, the application program can access the resources in the system and acquire the services of the system in the execution.

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 controller controls the operation and response of the display device 200, as well as the user operations associated with the display, by running various software control programs in memory, such as an operating system and/or various application programs. For example, control presents a user interface on a display, including a number of UI objects (e.g., controls, icons, items, etc.) thereon; in response to a received user command for a UI object on the user interface, the controller may perform an operation related to the object selected by the user command.

The display device provided by the application has a health detection function. The health detection function is implemented based on a health detection function related application installed on the display device. For ease of description, the application related to the health detection function will be referred to as "health care manager".

Fig. 5A is a schematic view of an application scenario in some embodiments of the present application. As shown in fig. 5A, communication between the remote controller and the display device may be based on a bluetooth low energy (Bluetooth Low Energy, BLE) protocol, such as receiving/transmitting control signals, notification messages, and user health data. In addition, the remote controller collects user health data through a built-in health data collection module of the remote controller and sends the collected user health data to the display device in real time. The display equipment completes interaction control with the remote controller by running a health manager application in an operating system, receives user health data sent by a remote controller end, and sends the user health data to the server. The server receives the user health data sent by the display device, analyzes the user health data through the health application service corresponding to the health manager application, returns the health detection result to the display device, and is displayed to the user by the display device.

As shown in fig. 5B, the remote controller has various keys and a touch area, and the touch area is connected to the health data acquisition module and the contact detection module. The contact detection module may detect user contact when the user makes contact with the touch area. Under the condition that the user keeps contact with the touch area, the health data acquisition module can acquire the health data of the user under the control of the remote controller.

In some embodiments, the user may initiate the health detection function of the display device by making contact with a touch area on the remote control for a predetermined time. It should be appreciated that since the health detection function of the display device is implemented based on a "health care manager" application installed on the display device, the health detection function of the display device, i.e., the "health care manager" application on the display device, is initiated. Illustratively, the user may hold the finger in contact with the touch zone for 3 seconds to launch the "health care provider" application.

Referring to fig. 6, in a specific implementation, when the remote controller is paired with the display device, after the contact detection module detects that the user is in continuous contact with the touch area, the controller of the remote controller is notified through serial communication, and after receiving the notification, the controller of the remote controller sends a control instruction for instructing to start the health detection function to the display device. The display device then responds to the control instruction, starts the 'health care manager' application, and displays an interface of the 'health care manager' application. For example, when the display device plays the video program based on the live television application and the third-party audio/video application, if a control instruction for starting the "health care manager" application is received, the currently running live television application or the third-party audio/video application is diverted to the "health care manager" application, and an interface of the "health care manager" application, such as a starting page or an application home page, is displayed.

Of course, a key for starting the health detection function may also be provided on the remote controller, so that the user may start the related application of the health detection function on the display device by one key, and the specific operation process is not repeated.

It should be noted that, in order to avoid confusion between the controller of the remote controller and the controller of the display device during the description, the remote controllers mentioned below all refer to the controller of the remote controller, such as the controller 110 shown in fig. 2, unless otherwise noted. For example, if reference is made hereinafter to "the remote controller communicates with the health data acquisition module" it is meant that the controller of the remote controller communicates with the health data acquisition module, and if reference is made hereinafter to "the remote controller sends an instruction to the display device" it is meant that the controller of the remote controller sends an instruction to the display device ".

Notably, in the case where the remote control is not paired with the display device, if the remote control detects continuous contact of the user with the touch area, a specific infrared code is emitted. After receiving the specific infrared code, the display device starts a 'health care manager' application, displays an interface of the 'health care manager' application, and simultaneously displays a pairing prompt so as to remind a user to operate the display device to pair with the remote controller through the pairing prompt. For example, the user is reminded to operate the pairing by popping a Toast prompt on the interface of the "health Carriers" application.

In other embodiments, the user may also enter control instructions for launching a "health care manager" application by entering a preset voice password. For example, the user speaks a preset voice password, such as "health detection" or "start health care manager", using a near field voice function or a far field voice function of the display device, and the display device determines a control instruction corresponding to the voice password by recognizing the voice password input by the user, thereby starting the health care manager application.

In other embodiments, the user may also operate the display device to display the application center interface and then launch the "health care" application by clicking on the application icon of the "health care" application displayed in the application center interface.

It should be noted that, for the terminal device with the health data acquisition module, the display device with the touch area as mentioned in the foregoing embodiment, or the portable terminal device supporting the fingerprint identification function, the health detection function is also implemented based on the installed health detection function related application, such as the "health care manager" application. In some embodiments, when such a display device or portable terminal device detects that the user is in contact with the touch area for a preset time, then a "health care manager" application is pulled up, displaying an interface of the application. In one example, the display device has a health data acquisition module built in and a touch area on the rear housing. When the user overlays his finger on the backshell touch area for 3 seconds, the display device will launch the "health care manager" application and jump from the currently displayed interface to the interface of the "health care manager" application. In another example, the user's mobile phone has a health data acquisition module built in and has a fingerprint identification area. When the user overlays his finger over the fingerprint recognition area for 3 seconds, the handset will launch the "health care manager" application and display the interface of the "health care manager" application.

In some embodiments, after the "health care" application is started successfully, a start page as shown in FIG. 7 is displayed first. Alternatively, an introduction to the application-related functionality may be presented on the launch page. Optionally, when the display duration of the start page reaches a predetermined duration, the start page is withdrawn, and the application home page is entered. For example, at the beginning of displaying the start page, a countdown is displayed in the upper left corner of the start page. And when the countdown is finished, the starting page is withdrawn, and the application home page is entered.

In some embodiments, after the "health care" application is launched successfully, the user protocol presentation page is first displayed. For example, in the case where the first start-up of the "health care manager" application is successful, the user protocol presentation page is first displayed. The user agreement presentation page may display application use agreements or specifications, such as exemption terms. The user may agree or decline the displayed protocol content by operating the relevant controls on the user protocol presentation page. If the user inputs an operation of agreeing to the protocol content, the display device withdraws the user protocol presentation page, and enters the start page or directly enters the application home page. If the user inputs an operation of rejecting the protocol content, the display device closes the 'health care manager' application, withdraws the user protocol presentation page, and returns to the interface before the 'health care manager' application is started.

Fig. 8 is a diagram of one possible user protocol presentation page illustratively shown herein. As shown in fig. 8, the user protocol presentation page includes a protocol content display area for displaying content that is application-use protocols or is specified, and a control display area for displaying user-operable controls, such as an "ok" control and a "reject" control. The user may select and determine the "agree" control to input the operation to agree to the protocol content, and may select and determine the "cancel" control to input the operation to reject the protocol content.

In other embodiments, the display device may display a user protocol presentation area at an upper layer of the launch page, in which user protocol content and associated controls are displayed, thereby presenting both the launch page and the user protocol content.

Fig. 9 is a "health care manager" application home page exemplarily shown in the present application, where the application home page is mainly used for guiding a user to perform health detection in a guest mode or establish a health record. As shown in fig. 9, the application home page includes a control "start setup" for triggering the establishment of the health profile and a control "immediate experience" for triggering the immediate detection of health in guest mode. When the application home page is displayed, a user can enter a file information input interface by operating a control for starting to establish, user characteristic information can be input in the file information input interface, and a health detection instruction can be input in a file management interface to instruct a display device to carry out health detection on a specified user, and the embodiment shown in fig. 10-11 can be seen; alternatively, the user may enter a health detection instruction by operating an "immediate experience" control to instruct the display device to immediately detect its health.

Fig. 10 is a profile information input interface exemplarily shown in the present application, which may specifically be an interface entered after a user operates a "start setup" control in an application home page. As shown in fig. 10, the archive information input interface includes a plurality of input items, such as head portraits, nicknames, sexes, ages, heights, weights, and the like. The user can upload the head portrait file when the interface is used, create a nickname of the user and select the gender, the age, the height and the weight. After the input is completed, the display device can be instructed to store the input user characteristic information by operating the 'confirm' control, and enter the archive management interface, or the 'cancel' control is operated to return to the application home page.

FIG. 11 is an exemplary profile management interface that may be specifically an interface that a user enters after operating a "confirm" control in a profile information input interface. As shown in fig. 11, the archive management interface displays created archive cards, where each archive card corresponds to a set of operation controls, and is a control "immediate physical examination" for triggering health detection and a control "physical examination report" for checking a previous health detection result, respectively. The user can select the control on the corresponding archive card to operate according to the detection object so as to input the health detection instruction. For example, when a health test is required for "milk", an "immediate physical examination" control on the archive card of "milk" is operated. In addition, the file management interface also displays a tourist card, so that a user can operate an 'immediate physical examination' control on the tourist card to input a health detection instruction for detecting in a tourist mode. In addition, a control for newly creating member file information 'adding member+' is also displayed in the file management interface, when the user operates the control, the user reenters the file information input interface, and the user can input the file information of the new member in the file information input interface.

Referring to fig. 12, in some embodiments, when the display device receives an input health detection instruction, an operation guidance interface is displayed, and at the same time, a data acquisition instruction is sent to the remote controller to instruct the remote controller to start acquiring user health data.

Fig. 13 is one possible operation guidance interface exemplarily shown in the present application. As shown in fig. 13, the operation guidance interface is displayed with operation guidance information, which information is displayed: the user needs to keep the fingers natural and relaxed and completely cover the touch area, so that the health data acquisition module can successfully acquire the health data of the user.

In some embodiments, the health data acquisition module is started after the remote controller receives the data acquisition instruction sent by the display device. After the health data acquisition module is successfully started, the remote controller sends a notification message indicating that the health data acquisition module is successfully started to the display device. As shown in fig. 12, in a specific implementation, the remote controller responds to a received data acquisition instruction, and opens a switch of the health data acquisition module through serial communication. After the switch of the health data acquisition module is turned on, the health data acquisition module informs the remote controller through serial communication. Furthermore, the remote controller can judge whether the health data acquisition module is started successfully according to whether the notification of the health data acquisition module is received. And when the health data acquisition module is judged to be successfully started, sending a notification message indicating that the health data acquisition module is successfully started to the display equipment. The display device performs a timing operation after transmitting a data acquisition instruction to the remote controller. And if a notification message indicating that the health data acquisition module is successfully started is received within the preset time, displaying a detection interface, wherein the detection interface is used for displaying the detection progress and/or real-time user health data. And if the notification message indicating that the health data acquisition module is successfully started is not received within the preset time, displaying a fault prompt on the operation guidance interface. For example, the content of the fault cue may be "health data acquisition module start failure" shown in fig. 14. And after the prompt is completed, returning to the previous interface.

Referring to fig. 15, in other embodiments, after receiving a data acquisition command sent by the display device, the remote controller starts the health data acquisition module, and detects whether there is user contact on the touch area through the contact detection module. When the contact detection module detects that the user contacts the touch area and the health data acquisition module is successfully started, the remote controller sends a notification message indicating that data acquisition is started to the display device. After sending a data acquisition instruction to the remote controller, the display device performs a timing operation to record the waiting time. If a notification message sent by the remote controller and indicating to start collecting data is received within the preset waiting time (i.e. before the waiting time reaches the preset waiting time), a detection interface is displayed, wherein the detection interface is used for displaying the detection progress and/or real-time user health data. And if the notification message which is sent by the remote controller and indicates to start collecting data is not received within the preset waiting time, displaying a timeout prompt on the operation guidance interface. Illustratively, the content of the timeout indication may be "timeout, no user contact detected" as shown in fig. 16. And after the prompt is completed, returning to the previous interface.

In some embodiments, the timing operation for recording the waiting period is referred to as a first timing operation.

In still other embodiments, when the display device receives an input health detection instruction, an operation guidance interface is displayed in which a "start detection" control for triggering the health detection control, such as in fig. 13, is displayed. When the user operates the control, a data acquisition instruction is sent to the remote controller, and a detection interface is displayed.

In some embodiments, the remote controller transmits the collected user health data to the display device in real time during the process of the health data collection module collecting the user health data.

According to the embodiment, based on interactive control and cooperation of the remote controller and the display device, the user can start the health detection function of the display device through simple operation, and collect the health data of the user, so that the user can perform health detection anytime and anywhere, and the experience is strong.

It should be noted that, for the terminal device with the health data acquisition module, the terminal device controller responds to the health detection instruction input by the user and turns on the switch of the health data acquisition module through the serial port. After the health data acquisition module is successfully started, the terminal equipment controller is informed through the serial port, and the terminal equipment controller controls the operation guidance interface to be displayed on the screen. When the terminal equipment controller detects user contact within the preset waiting time, a detection interface is displayed, and at the moment, the health data acquisition module starts to acquire the user health data. In the data acquisition process, the health data acquisition module transmits the acquired user health data to the terminal equipment controller. After the data acquisition is completed, the terminal equipment controller sends the acquired user health data to the server so as to analyze the user health data through the server and return a health detection result to the terminal equipment.

In some embodiments, to ensure the user experience of the health detection process, the time to collect data may be predefined, namely: the limiting remote controller completes the collection and the sending of the user health data in a preset time, and the limiting display equipment completes the receiving of the user health data in a preset receiving time.

In some embodiments, when the display device receives a notification message sent by the remote controller indicating that data collection is to be started, a timing operation is performed to record the data reception duration. In some embodiments, the timing operation for recording the data reception period is referred to as a second timing operation.

In the data acquisition process, the remote controller packages the user health data acquired by the health data acquisition module into a data packet in real time and sends the data packet to the display equipment until the acquisition is completed. For ease of distinction and explanation, the present application refers to data packets that encapsulate user health data as health data packets.

As shown in fig. 17, in one implementation, after the health data acquisition module is started, user health data is continuously acquired, and the acquired user health data is synchronized to the remote controller in real time through serial communication. And the remote controller encapsulates the acquired latest user health data into a health data packet at regular intervals, and sends the health data packet to the display device until the health data acquisition module finishes acquiring the health data. It is noted that when the remote controller receives a preset number of valid data packets or the data receiving duration reaches a preset duration, the data acquisition is considered to be completed. The preset number=preset receiving duration/interval duration of sending data packets to the display device, and the valid data packet refers to a data packet sent to the display device when no abnormality is detected, and user health data encapsulated in the data packet is valid data. After the data acquisition is completed, the display equipment sends an acquisition stopping instruction to the remote controller. And the remote controller responds to the acquisition stopping instruction and closes the health data acquisition module.

The preset receiving time period is 30s, and the preset number of the health data packets is 24. That is, the remote should send 24 health data packets to the display device within 30 seconds.

In some embodiments, the remote controller encapsulates the collected user health data into a health data packet according to a format pre-agreed with the display device, wherein the health data packet at least comprises a packet sequence identifier, user health data and an abnormality identifier. The packet sequence identifier i represents an ith health data packet sent to the display equipment by the remote controller, and the abnormality identifier characterizes whether abnormality is detected or not and the abnormality type. It should be noted that, the detection abnormality may include detection abnormality caused by a detection environment change, such as a strong light environment, weak communication signal, and the like, and also include contact abnormality between the user and the touch area, such as removal of the finger from the touch area by the user, and the like.

In one example, the data format of the health data packet is as follows:

Byte1

Byte2

Byte3-4

Byte5～68

Byte69

Byte70

Byte71

Byte72-74

Byte75

Byte76

Byte77-78

Byte79

data header code

Packet sequence identification

Reservation of

Heartbeat data

Heart rate of heart

Blood oxygen

Microcirculation

Reservation of

Systolic pressure

Diastolic blood pressure

Reservation of

Anomaly identification

In another example, the data format of the health data packet is as follows:

Byte1	Byte2-6	Byte7～23	Byte24～191	Byte182～197
					data header code	Packet sequence identification	Acquisition hardware ID	Raw health data	Reservation of

In some embodiments, after the display device receives the health data packet, the display device retrieves the required data for displaying the detection interface from the health data packet, and then displays and updates the detection interface according to the retrieved data, where the detection progress and/or at least one item of user health data may be displayed.

In specific implementation, hexadecimal bytes in the health data packet are firstly converted into decimal, and then each item of health data and abnormal identification are selected from the decimal bytes. In one example, the hexadecimal bytes in the health data packet are converted to decimal numbers, resulting in a byte sequence of [1, 12, 76, -1, 29,6, -13, -28, -40, -49, -57, -63, -66, -65, -63, -60, -60, -63, -68, -77, -86, -95, -103, -108, -111, -113, -112, -111, -110, -108, -109, -111, -115, -115, -109, -91, -59, -17, 29, 70, 97, 104, 92, 66, 33,0, -26, -47, -60, -69, -73, -74, -73, -71, -69, -69, -72, -79, -86, -94, -101, -105, -109, -111, -112, -112, -112, 35, 96, -84, -124, 25,0, 111, 73, 46, -43,0], wherein bit 68 represents heart rate, bit 69 represents blood oxygen, bit 70 represents microcirculation, bit 74 represents systolic pressure, bit diastolic pressure, bit 78 represents an abnormal marker. Illustratively, anomaly identification 1 may represent a weak signal, anomaly identification 2 may represent a strong light environment, anomaly identification 3 may represent a contact anomaly, and anomaly identification 0 represents no anomaly.

In some embodiments, the display device determines the current detection progress based on the packet sequence identification in the latest received health data packet and the preset number of health data packets. For example, assuming that the preset number is 24 and the packet sequence identifier of the latest received health data packet is 6, the current detection progress is determined to be 6/24, that is, 25%.

In other embodiments, the display device determines the current detection progress based on the current data reception duration and the preset reception duration. For example, assuming that the current data receiving duration is 10s and the preset receiving duration is 30s, the current detection progress is determined to be 10s/30s, namely 1/3.

It should be appreciated that each time a health data packet is received by the display device, the detection interface is updated in accordance with the health data packet. For example, after the display device receives the 1 st health data packet, in the detection interface, part or all of the user health data in the 1 st health data packet, such as real-time heart rate status data and blood oxygen status data, is displayed, and a detection progress, such as a progress bar representing the detection progress, is displayed, where the detection progress may be determined according to a packet sequence identifier of the health data packet or the collection time. And after the display equipment receives the 2 nd health data packet, updating the detection interface according to the data in the 2 nd health data packet.

In some embodiments, a heart rate status curve is drawn in a content area on the upper side of the detection interface according to heart rate status data in the health data packet, and a heart rate status value, blood oxygen status data and current detection progress are displayed in a content area on the lower side of the detection interface.

Fig. 18 is a diagram showing a detection interface in some exemplary embodiments, where a heart rate status curve changing in real time is displayed in a content area on the upper side of the interface, and a detection progress bar with a heart rate status value of "70BPM", a blood oxygen status value of "85%" and a current progress of "62%" are sequentially displayed in a content area on the lower side of the interface.

In the above embodiment, after the "health care manager" application is started, in response to the input health detection instruction, the data acquisition instruction is sent to the remote controller while the operation instruction interface is displayed. And the remote controller starts the health data acquisition module in response to receiving the data acquisition instruction, and then enters the health detection process described in the embodiment.

It should be appreciated that during the health detection process, the health data acquisition module acquires user health data based on the user's contact with the touch area. Thus, during the health detection process, the user is required to keep the finger in contact with the touch area. Once the user removes the finger from the touch area, the contact between the user and the touch area is disconnected, and then the data collected by the health data collection module is not real health data of the user, so that abnormal detection is caused. For convenience of explanation, in the embodiment of the present application, detection abnormality caused by disconnection of the user's contact with the touch area is referred to as user contact abnormality. It should be appreciated that anomalies that affect the acquisition of user health data also include weak communication signals, strong light environments, and the like.

As described above, the remote controller notifies the display device of the presence or absence of an abnormality and the type of abnormality by encapsulating the abnormality flag in the health data packet. For example, in the process of collecting the health data of the user through the health data collecting module, if the contact detection module detects that the contact between the user and the touch area is disconnected, the contact detection module notifies the remote controller through serial communication, wherein the fact that the user moves the finger away from the touch area is indicated. And the remote controller determines that the user contact abnormality occurs according to the notification of the contact detection module. At this time, the remote controller encapsulates an anomaly identification representing that the user touches the anomaly in the health data packet, and sends the anomaly identification to the display device. The display device can determine that the user contact abnormality occurs according to the abnormality identification in the data packet. When no abnormality exists, the remote controller packages an abnormality identification representing the no abnormality in the health data packet and sends the abnormality identification to the display device; the display device may determine that there is no anomaly currently according to the anomaly identification in the health data packet.

In some embodiments, the contact detection module continues to detect the contact of the user with the touch area after detecting that the contact of the user with the touch area is broken, and at the same time, the health data acquisition module continues to acquire the health data of the user. When the contact detection module detects the re-contact between the user and the touch area, the remote controller is notified through serial communication. And the remote controller determines that the user is in contact with the touch area again according to the notification of the serial communication, namely, the abnormal contact of the user is relieved. At this time, the remote controller encapsulates the abnormal identifier, which characterizes no abnormality, in the health data packet, and sends the abnormal identifier to the display device. The display device can determine whether the user touches the abnormality according to the abnormality identification in the data packet.

In some embodiments, the data packets sent by the remote control to the display device when there is no anomaly (including after the anomaly has been resolved) are valid data packets, i.e., the anomaly identification in the valid data packets characterizes no anomaly. The data packet sent to the display device by the remote controller under the abnormal condition is an invalid data packet, namely, the abnormal identifier in the invalid data packet represents abnormal types such as abnormal user contact, weak communication signals or strong light environment. In this way, the display device can distinguish between valid data packets and invalid data packets based on the anomaly identification in the healthy data packets.

In some embodiments, after the display device receives the health data packet sent by the remote controller, it determines whether the health data packet is a valid data packet according to the abnormal identifier in the health data packet. And if the health data packet is a valid data packet, updating the detection interface according to the health data packet.

It should be understood that the display device may also determine whether the health data packet is valid based on the user health data in the health data packet. For example, when there are a plurality of continuous 0 s in the user health data, it may be determined that the user health data is invalid data, and the health data packet is an invalid data packet.

In some embodiments, the display device counts the number of valid data packets received in real time during the process of receiving data, so as to determine whether the data acquisition process can be terminated according to whether the number of valid data packets reaches a preset number.

In some embodiments, after the display device receives the health data packet sent by the remote controller, determining whether a user contact abnormality occurs according to an abnormality identifier in the health data packet; if the user contact abnormality occurs, timing is performed to record the duration of the abnormality, and whether the user is in contact with the touch area again within the preset time is judged according to whether a valid data packet sent by the remote controller is received within the preset time when the user contact abnormality occurs. If the effective data packet sent by the remote controller is not received within the preset time period when the user contact abnormality occurs, and the user is not contacted with the touch area again within the preset time period, a control instruction for indicating the user to stop collecting data is sent to the remote controller. And the remote controller responds to the control instruction and closes the health data acquisition module. If the effective data packet sent by the remote controller is received within the preset time when the user contact abnormality occurs, the user is in contact with the touch area again within the preset time, namely, the user contact abnormality is relieved, the healthy data packet sent by the remote controller is continuously received, and the number of the received effective data packets is recorded. When the number of the received effective data packets reaches a preset number, a control instruction for indicating the remote controller to stop collecting data is sent to the remote controller, and all the effective data packets are sent to the cloud server. And the remote controller responds to receiving a control instruction for indicating to stop collecting data, and the health data collecting module is closed.

According to the embodiment, in the process of collecting the user health data, if the user contact is temporarily disconnected, the user can also continue to collect the data until the quantity of the collected effective data reaches the preset quantity, so that the operation difficulty of the user is reduced, and the data collection failure caused by the short contact failure or improper operation is avoided. In addition, the user pressure can be reduced, the tension mood of the user is avoided, and the user experience is improved.

If the user contact is disconnected for too long, namely, exceeds the preset time, the data acquisition fails, namely, the health detection fails.

In other embodiments, the display device performs a first timing operation to record a data receiving duration after receiving a notification message sent by the remote controller indicating that data collection is to be started; after the display equipment receives the health data packet sent by the remote controller, judging whether the user contact abnormality occurs according to the abnormality identification in the health data packet; and if the user contact abnormality occurs, executing a second timing operation to record the abnormal duration time, and judging whether the user is in contact with the touch area again within the maximum duration time according to whether a valid data packet sent by the remote controller is received before the abnormal duration time reaches the maximum duration time. And if the effective data packet sent by the remote controller is not received before the abnormal duration reaches the maximum duration, sending a control instruction for indicating the remote controller to stop collecting data to the remote controller. And the remote controller responds to the control instruction and closes the health data acquisition module. And if the effective data packet sent by the remote controller is received before the abnormal duration reaches the maximum duration, continuing to receive the healthy data packet sent by the remote controller until the data receiving duration reaches the preset receiving duration. When the data receiving time length reaches the preset receiving time length, a control instruction for indicating the remote controller to stop collecting data is sent to the remote controller, and all received effective data packets are sent to the cloud server. And the remote controller responds to receiving a control instruction for indicating the remote controller to stop collecting data, and the health data collecting module is closed.

It is noted that in some embodiments, the data acquisition duration is equivalent to the data reception duration, and the preset acquisition duration is equivalent to the preset reception duration.

According to the embodiment, in the process of collecting the user health data, if the user contact is temporarily disconnected, the user can also continue to collect the user health data, so that the operation difficulty of the user is reduced, and the data collection failure caused by the short contact failure or improper operation is avoided. In addition, the user pressure can be reduced, the tension mood of the user is avoided, and the user experience is improved.

If the user contact is disconnected for too long, i.e. the maximum duration is exceeded, the data acquisition fails, i.e. the health detection fails.

In some embodiments, if the health detection fails, an anomaly prompt interface is displayed. The anomaly prompt interface comprises a control for triggering re-detection, and a user can trigger a new detection process by operating the control. In addition, failure reasons, user suggestions and the like can be prompted in the abnormality prompt interface.

FIG. 19 is an anomaly prompt interface as shown in some exemplary embodiments of the present application. As shown in fig. 19, the abnormality presentation interface is displayed with: the failure cause is that the data anomaly rate is higher, the detection result cannot be normally generated, and the user recommends that the detection is re-performed, and the finger is kept to be completely covered in the touch area during the detection. In addition, the anomaly prompt interface also displays a re-detection control and a cancel control, and the user can click the re-detection control to return to the operation guide interface for re-detection and can click the cancel control to return to the application home page.

It should be noted that, for the terminal device with the health data acquisition module, when the terminal device detects that the user touches an abnormality during the process of acquiring the health data of the user through the health data acquisition module, a timing operation is performed to record the duration of the abnormality. If the user contact is not redetected within the maximum duration, the health data acquisition module is turned off to stop acquiring data. If the user contact is detected again within the maximum duration, the health data acquisition module is not closed so as to continue to acquire data until the acquired effective user health data meets the preset quantity, or the data acquisition duration reaches the preset acquisition duration. And closing the health data acquisition module when the acquired effective user health data meet the preset quantity or the data acquisition duration reaches the preset acquisition duration.

As described above, the display device completes the interactive control with the remote controller by running the "health care manager" application in the operating system, and receives the user health data sent by the remote controller. Thus, once the abnormal conditions such as flashing back and blocking occur in the application of the health manager, the display device cannot continue to perform interactive control with the remote controller, and cannot continue to receive the user health data sent by the remote controller.

In some embodiments, to ensure proper communication between the remote control and the display device, the display device periodically sends an online indication message to the remote control after sending a data acquisition instruction to the remote control. When the data receiving duration reaches the preset receiving duration or the effective data receiving quantity meets the preset receiving quantity (the preset quantity 24), the display equipment sends an acquisition stopping instruction to the remote controller and stops sending an online indication message to the remote controller.

And the remote controller judges whether the display equipment is abnormal in communication according to the receiving condition of the online indication message. For example, if the online indication message transmitted by the display device is not received 3 consecutive times, it is determined that the display device communication is abnormal. And if the communication of the display equipment is abnormal, closing the health data acquisition module to stop acquiring the user health data. If the display equipment is always communicated normally, the health data acquisition module is closed when an acquisition stopping instruction sent by the display equipment is received. It should be appreciated that after the health data acquisition module is turned off, no user health data will be sent to the display device and the health detection process is terminated.

In particular, the "health care manager" application sends a heartbeat packet to the remote control at preset intervals. For example, a heartbeat packet is sent to the remote control every 3 seconds. And if the remote controller does not receive the heartbeat packet sent by the health care manager application for 3 times continuously, closing the health data acquisition module. Otherwise, closing the health data acquisition module when receiving an acquisition stopping instruction sent by the display equipment.

In other embodiments, to ensure proper communication between the remote control and the display device, the remote control periodically sends an online query message to the display device during data acquisition. After receiving the online inquiry message sent by the remote controller, the display device returns an online response message. And the remote controller judges whether the display equipment is abnormal in communication according to the receiving condition of the online response message. For example, if the online response message returned by the display device is not received 2 consecutive times, it is determined that the display device communication is abnormal. And if the communication of the display equipment is abnormal, closing the health data acquisition module to stop acquiring the user health data. If the display equipment is always communicated normally, the health data acquisition module is closed when an acquisition stopping instruction sent by the display equipment is received.

In the specific implementation, in the data acquisition process, the remote controller sends a heartbeat packet to the health care manager application at preset intervals. For example, a heartbeat packet is sent to the "health care manager" application every 3 seconds. The health care manager application returns a heartbeat response message to the remote controller after receiving the heartbeat packet sent by the remote controller. The remote controller can determine the communication connection condition with the 'health care manager' application according to the receiving condition of the heartbeat response message. If the remote controller does not receive the heartbeat response message sent by the health care manager application for 2 times continuously, which indicates that the communication of the health care manager application is abnormal, the health data acquisition module is closed, and then the health detection process is terminated. Otherwise, closing the health data acquisition module when receiving an acquisition stopping instruction sent by the display equipment.

In other embodiments, to ensure proper communication between the remote control and the display device, the display device returns a receive response message to the remote control in response to receiving the health data packet sent by the remote control. And the remote controller judges whether the display equipment is abnormal in communication according to the receiving condition of the response message. For example, if the reception response message returned by the display device is not received 2 times in succession, it is determined that the display device communication is abnormal. And if the communication of the display equipment is abnormal, closing the health data acquisition module to stop acquiring the user health data. Otherwise, closing the health data acquisition module when receiving an acquisition stopping instruction sent by the display equipment.

In the implementation, after receiving the health data packet sent by the remote controller, the "health manager" application returns a receiving response message to the remote controller. And the remote controller determines the communication connection condition with the 'health care manager' application according to the receiving condition of the receiving response message. If the remote controller does not receive the receiving response message returned by the 'health care manager' application for 2 times continuously, which indicates that the 'health care manager' application is abnormal in communication, the health data acquisition module is closed, and then the health detection process is terminated.

According to the embodiment, when the display equipment communication is abnormal with the remote controller due to abnormal application of the health care manager, the remote controller can monitor the abnormal communication of the display equipment and actively close the health data acquisition module to terminate the data acquisition process, so that the health data acquisition module is prevented from being in a working state all the time, and the electric quantity of the remote controller is exhausted.

It should be noted that, for the terminal device with the health data acquisition module, if an application abnormality of the health manager, such as flashing back or blocking, is detected during the process of acquiring the health data of the user through the health data acquisition module, the health data acquisition module is closed through the serial port.

In some embodiments, after the user health data collection is finished, the display device sends all the received health data packets to the cloud server.

In one implementation, the display device intercepts user health data from each health data packet, then splices the intercepted user health data with the packet sequence identifier of each health data packet as a splicing sequence, and converts the spliced data into bytes to generate a new data packet. And finally, sending the generated new data packet to a cloud server.

In some embodiments, the remote controller encapsulates the collected user health data into a real-time data packet and an original data packet according to a format agreed with the display device in advance, wherein the real-time data packet is used for displaying a detection interface on the display device, and the original data packet is used for being sent to the cloud server. Illustratively, the data format of the real-time data packet may be the data packet format shown in the first example, and the data format of the original data may be the data packet format shown in the second example.

It should be noted that, the real-time data packet is different from the data header of the original data packet. In this way, the display device can distinguish the real-time data packet from the original data packet according to the data header code of the received data packet. Illustratively, the data header of the original data packet may be 0 and the data header of the real-time data packet may be 1. Then, if the data header code of the data packet received by the display device is 0, the data packet is indicated as an original data packet, and if the data header code of the data packet received by the display device is 1, the data packet is indicated as a real-time data packet.

In these embodiments, the display device needs to parse the real-time data packet, and further may display a detection interface according to the parsing result.

It is worth noting that the display device does not need to analyze the received original data packet, but sends all the received original data packets to the cloud server after the data acquisition is finished.

In some embodiments, the display device intercepts the original health data from each original data packet, then splices the intercepted original health data with the packet sequence identifier of each original data packet as a splicing sequence, and converts the spliced data into bytes to generate a new data packet. And finally, sending the generated new data packet to a cloud server. Illustratively, according to the format of the original data packet, the data from the 23 rd position to the 190 th position is intercepted, and the original health data is obtained.

The format of the data packet sent to the cloud server is as follows:

Byte1	Byte2-169	Byte170-337	……	Byte3677-3844	Byte3845-4012
						data header code	Raw health data (1)	Raw health data (2)	……	Raw health data (23)	Raw health data (24)

The raw health data (1) is user health data in the raw data packet with the packet sequence identifier 1, the raw health data (2) is user health data … … in the raw data packet with the packet sequence identifier 2, and so on, it can be seen that the data packet includes user health data cut from each raw data packet.

In some embodiments, the server receives a data packet sent by the display device, and first parses out user health data in the data packet; then analyzing the user health data by using a preset analysis algorithm to obtain a health detection result; and finally, sending the health detection result to display equipment so as to show the health detection result to a user at the display equipment end. As a possible implementation, the health detection result may include one or more of heart rate variability index, symptom description information, symptom cause analysis, and user advice information.

In one example, the server analyzes the user health data by using a preset analysis algorithm to obtain that the heart rate variability index of the user is 67, and symptoms include palpitation, shortness of breath and the like, symptom reasons include posture change, physical activity, emotional anxiety, fear, agitation, drinking, smoking, drinking tea, drinking coffee and the like, and user suggestions are given to the user including smoking cessation, alcohol withdrawal, little drinking of strong tea, increasing aerobic exercise, little stay up night, avoiding fatigue and the like.

In some embodiments, the display device transmits the user characteristic information to the server at the same time as the user health data is transmitted to the server, so that the server can analyze the user health data in combination with the user characteristic information. The user characteristic information may include, among other things, the user's age, gender, height, weight, etc. It should be appreciated that the user characteristic information may be information entered by the user from an archive information input interface. In a scene that a user triggers health detection by operating an immediate physical examination control on a certain archive card in an archive management interface, after data acquisition is completed, the display equipment sends acquired user health data and user characteristic information corresponding to the archive card to a server.

In some embodiments, the server may further process the health detection result using a preset content recommendation rule, determine recommended content matching the health detection result, and send related information of the recommended content to the display device, so as to push the corresponding recommended content to the user through the display device. For example, if the health detection result shows that the heart rate variability index of the user is high, content which is helpful for improving cardiovascular health of the user, such as a healthy diet recipe, sports teaching video and the like, can be recommended to the user.

For convenience of explanation, in the embodiment of the present application, the related information of the recommended content is referred to as recommendation information. The recommendation information may include display information and jump parameters. The display information comprises pictures, title characters and the like of recommended contents and is used for displaying in a user interface; the jump parameter is then the relevant parameter for opening the recommended content.

It should be noted that, the recommended content may be: applications such as "AI fitness" applications; designating content provided by an application, such as video content in a small video application; video programs, such as sports teaching videos, fat-reducing meal practice videos and the like; it may also be a designated page in a designated application, such as a certain workout project page in an "AI workout" application.

In other embodiments, the server may combine the health detection results with the user characteristic information to determine recommended content that matches both the health detection results and the user characteristics. In this way, the determined recommended content will be consistent with both the health and personal characteristics of the user. For example, if the health detection result shows that the user is overweight and the user characteristic information shows that the user is older, content which is helpful for the user to reduce weight and accords with the senior user, such as health fat-reducing meal, health equipment and fitness projects suitable for the senior user, including jogging, fast walking, taiji and other non-violent exercises, can be recommended to the user. For another example, if the health detection result shows that the user is overweight, and the user characteristic information shows that the user is female, content which is helpful for the user to reduce weight and accords with the female user, such as a health fat-reducing meal, and health equipment and fitness projects (such as yoga, gymnastics and the like) suitable for the female user, can be recommended to the user.

In some embodiments, the server pre-obtains the user interest information, so that the health detection result, the user feature information and the pre-obtained user interest information can be combined to determine the recommended content which is matched with the user interest information, the health detection result and the user feature information at the same time. In this way, the determined recommended content will simultaneously correspond to the user's interests, health and personal characteristics.

It is understood that the content tag has a category distinguishing capability for the content, which may be a keyword included in the content or a category name of a category to which the content belongs. Content sources, i.e., sources of content, include applications or applets, plug-ins, and the like. In some embodiments, the user's level of interest in a content tag or content source of a content may be used to characterize the user's level of interest in the content.

Based on this, the user interest information may include the user's interest level in content tags and/or applications/plugins (e.g., widgets). The interest degree of the user on a certain content label can be determined according to the clicking action of the user on the content with the content label, and the interest degree of the user on a certain application/plug-in can be determined according to the use condition of the user on the application/plug-in. It should be appreciated that the higher the number and frequency of clicks a user has on content with a certain content tag, the higher the user's interest in that content tag; the longer the user uses a certain application/plug-in, the higher the frequency of use, the higher the user's interest in that application/plug-in.

In some implementations of obtaining user interest information, when the display device receives a user selection operation on the content, the display device reports relevant information of the content selected by the user to the server. The server extracts at least one content tag from the content related information reported by the display device, if the extracted content tag is a tag selected by the user, the number of times of selection corresponding to the content tag is increased by 1, if the extracted content tag is a new tag which is not selected by the user, the tag is saved, and the number of times of selection of the content tag by the user is recorded as 1. According to the implementation mode, the server can collect the selected times and the selected frequencies of the user on each content label, namely the clicking times and the clicking frequencies, so that the user interestingness corresponding to each content label can be determined according to the clicking times and the clicking frequencies corresponding to the content label. Notably, the related information of the content may include a content title, a genre, profile information, and the like.

The user interest of the content tag can be represented by an interest score, and the interest score is obtained by evaluating the number and frequency of user clicking corresponding to the content tag based on a preset evaluation strategy. For example, if the number of clicks corresponding to the content tab "fitness" is > M1 and the frequency of clicks is > n1, the user interest level corresponding to the content tab "fitness" is 3 points; if the click frequency of the content label corresponding to the weight reduction is more than M2 and the click frequency is more than n2, the user interestingness of the content label corresponding to the weight reduction is 4 points.

In some implementations of obtaining user interest information, when a user opens an application or an applet plug-in (e.g., a Widget) on a display device, the display device reports a user notification of use of the application or plug-in to a server; when the user closes the application or the plug-in on the display device, the display device reports the duration of the user using the application or the plug-in to the server. And the server records the use condition of each application and each plug-in unit according to the use notification and the use time length reported by the display equipment, and further determines the user interest degree corresponding to each application or plug-in unit according to the use condition of each application or plug-in unit by the user.

The user interest corresponding to the application or the applet can be represented by an interest score, and the interest score is obtained by evaluating the use condition corresponding to the application or the applet based on a preset evaluation strategy. For example, if the "AI workout" application corresponds to a number of uses > S1 and a total duration of use > T1, then the "AI workout" application corresponds to a user interest level of 3 points; if the "AI fitness" application corresponds to a number of uses > S2 and the total duration of use > T2, then the "AI fitness" application corresponds to a user interest level of 4 points.

As described above, the server may combine the health detection result, the user feature information, and the user interest information acquired in advance to determine recommended content that matches the user interest information, the health detection result, and the user feature information at the same time.

In some implementations, the server first processes the user feature information and the health detection result by using a content recommendation rule to primarily screen candidate content matched with the user feature information and the health detection result; then determining content tags for each candidate content; determining the user interest degree corresponding to the content label of each candidate content according to the pre-acquired user interest information, and determining the candidate content to which the content label with the user interest degree larger than a preset interest degree threshold belongs as recommended content; and finally, transmitting a recommendation information set formed by recommendation information corresponding to all the recommendation contents to the display device.

Further, the server may allocate a priority to each recommended content according to the principle that the higher the user interest level is, the higher the priority of the recommended content is, and send the priority identifier as a part of the recommended information to the display device. In this way, the display device can distinguish the interest difference of the user in different recommended contents according to the priority identification in each recommended information, so that the recommended contents which are interested by the user are preferentially displayed.

In another specific implementation manner, the server firstly processes the user characteristic information and the health detection result by using a preset content recommendation rule so as to primarily screen candidate contents matched with the user characteristic information and the health detection result; then determining the content source of each candidate content, wherein the content source of the candidate content is an application or a plug-in on the display device; the method comprises the steps of carrying out a first treatment on the surface of the Determining the user interest degree corresponding to the content source of each candidate content according to the pre-acquired user interest information, and determining the candidate content of the content source with the user interest degree larger than a preset interest degree threshold as recommended content; and finally, transmitting a recommendation information set formed by recommendation information corresponding to all the recommendation contents to the display equipment.

Further, the server may also allocate a priority to each recommended content according to the principle that the higher the interest level of the content source is, the higher the priority of the recommended content is, and send the priority identifier as a part of the recommendation information to the display device. In this way, the display device can distinguish the interest difference of the user in different recommended contents according to the priority identification in each recommended information, so that the recommended contents which are interested by the user are preferentially displayed.

In some embodiments, after the display device receives the health detection result and the recommended information set returned by the server, the display device enters a detection result interface from the detection interface, and the health detection result and at least one recommended content are summarized and displayed on the detection result interface. For example, the health detection result may be displayed in a first content area of the detection result interface, and display information in at least one recommendation information, that is, a title, a picture, etc. of the recommendation content may be displayed in a second content area of the detection result interface.

In some embodiments, at least one tab is displayed in the second content area of the detection result interface, and at least one recommended content randomly screened from the recommended information set is respectively displayed in each tab. For example, a preset number of tabs may be displayed in the second content area, and preset number of recommended contents randomly selected from the recommended information set may be displayed in each tab, respectively.

In some embodiments, the first content area and the second content area are respectively located at the upper side and the lower side of the detection result interface, and the area occupied by each of the first content area and the second content area can be divided according to the requirement of the content to be displayed.

FIG. 20 is a test results interface shown in some exemplary embodiments herein. As shown in fig. 20, specific contents of the health detection result including the heart rate variability index of the user, the heart rate variability concept introduction, the description of the symptoms of the user, the cause of the symptoms, and the user advice are displayed in the first content area on the upper side of the detection result interface. Four recommended content tabs are displayed in a second content area at the lower side of the detection result interface, and the titles of the recommended content tabs are respectively "health fat-reducing meal", "AI body building", "cardiovascular diet", "health preserving large class". The user can click on any one of the tabs to view the recommended content under the corresponding title.

It should be understood that the first content area and the second content area may also be located on the left and right sides of the detection result interface, which is not described in detail in this application.

In some embodiments, the recommendation information includes priority identifiers of the recommended content, and each priority identifier of the recommended content is determined by the server according to a content tag of the recommended content or a user interest level corresponding to a content source, where the user interest level corresponding to the content tag is determined according to a clicking action of a user on the content with the content tag, and the user interest level corresponding to the content source is determined according to a use condition of the user on the content source. And when the detection result interface is displayed, displaying a preset number of tabs in the second content area, and respectively displaying the preset number of recommended contents with the front priority in the recommended information set in each tab.

In some embodiments, a control for updating recommended content is also displayed in the detection result interface, such as the "change batch" control in the detection result interface shown in fig. 16. The user may instruct the display device to replace the currently displayed recommended content by operating the control. And the display equipment responds to the confirmation operation of the control, and respectively displays the preset number of the recommended contents with the front priority in the rest recommended contents in each tab, wherein the rest recommended contents refer to the recommended contents which are not displayed in the recommended content set.

FIG. 21 is another exemplary test results interface presented herein, specifically an interface displayed by a user after operating the "change batch" control in the interface presented in FIG. 20. Unlike fig. 20, in fig. 21, recommended contents displayed in the second content area on the lower side of the detection result interface are respectively: "yoga", "Keep", "healthy light", "fitness suit".

It should be noted that in the above embodiment, each tab in the detection result interface may acquire the focus, and the user may move the focus position by operating the control device to select any one tab. When the focus is on a certain tab, the user can input a confirmation operation to open the corresponding recommended content. Based on the jump parameter, when the display equipment receives the selected operation of the target recommended content input by the user, the jump parameter corresponding to the target recommended content is obtained; and starting the target jump application according to the jump parameter, and displaying a target jump interface.

Specifically, the jump parameter includes a target jump application identifier, which may specifically be an application package name, for enabling the display device to determine a target jump application, and a target jump page identifier, which may specifically be a class name, for enabling the display device to determine a target jump page. In addition, the jump parameter may further include a jump type. Illustratively, one possible skip parameter format is as follows:

{"startupType":4,"startupUrl":[{"key":"startupType","value":1,"type":"int"},{"key":"package Name","value":"com.hisense.tv.mirror","type":"String"},{"key":"className","value":"com.hisense.tv.mirror.PreviewActivity","type":"String"}]}

in the above jump parameter example, the packagenname is an application package name, i.e. the target jump page identifier, and the className is a class name, i.e. the target jump page identifier.

Illustratively, when the user opens the "AI workout" tab of FIG. 20, then the interface shown in FIG. 20 jumps to the application front page of the "AI workout" application.

According to the technical scheme, the health detection result is provided for the user, and meanwhile, the user personalized health detection result, the user interests and the user characteristics are aimed at, so that the user can push proper recommended content for the user, enrich interface content, meet the potential requirements of the user and improve user experience.

According to the display device provided in the above embodiment, the embodiment of the present application further provides an exception handling method, and the execution subject of the method may be a controller of the display device provided in the present application, such as the controller 250 shown in fig. 3. Since the abnormality processing method corresponds to the steps performed by the display device controller in the above-described embodiment, the following embodiment will briefly describe the abnormality processing method. The more specific implementation manner of the exception handling method provided in the present application may be referred to with the foregoing content of the embodiment of the display device.

As shown in fig. 22, the exception handling method may include the steps of:

s221, monitoring whether user contact abnormality occurs in the process of collecting user health data based on the contact of the user with the touch area. If the user contact abnormality occurs, S222 is performed.

In some embodiments, the touch area is provided on a remote controller, and a health data acquisition module is built in the remote controller, and the health data acquisition module is connected with the touch area, and the process of acquiring the health data of the user based on the contact between the user and the touch area comprises the following steps: responding to an input health detection instruction, and sending a data acquisition instruction to a remote controller so as to instruct the remote controller to acquire user health data through the health data acquisition module; and receiving user health data sent by the remote controller. More specifically, the receiving the user health data sent by the remote controller includes: and receiving health data packets sent by the remote controller at intervals, wherein the health data packets at least comprise the latest user health data acquired by the health data acquisition module.

In some embodiments, the health data packet further includes an anomaly identifier, where the anomaly identifier is used to characterize whether there is a detected anomaly and an anomaly type; in the process of collecting user health data based on the contact between the user and the touch area, monitoring whether the user contact abnormality occurs or not comprises the following steps: and judging whether the abnormality identification in the received health data packet represents user contact abnormality.

In other embodiments, the touch area is disposed on the display device body, the display device has a health data acquisition module disposed therein, the health data acquisition module is connected with the touch area, and the process of acquiring health data of the user based on the contact between the user and the touch area comprises: the control health data acquisition module acquires user health data based on contact of the user with the touch area.

S222, detecting whether the user is in contact with the touch area again or not within a preset time period after the user contact abnormality occurs. If the user is detected to be in contact with the touch area again within the preset time period, S223 is executed, otherwise S224 is executed.

In some embodiments, the detecting whether the user is in contact with the touch area again within a preset time period after the abnormal user contact occurs includes: and judging whether the healthy data packet received within the preset time after the occurrence of the contact abnormality is an effective data packet with the abnormality identification representing no abnormality or not.

S223, continuously collecting the user health data until the data collection time length reaches the preset collection time length.

S224, sending an acquisition stopping instruction to the remote controller so that the remote controller can close the health data acquisition module.

In addition, in some embodiments, when the data acquisition duration reaches a preset acquisition duration, an instruction to stop acquisition is sent to the remote controller, so that the remote controller turns off the health data acquisition module.

In some embodiments, the exception handling method further comprises: if the user is not detected to be in contact with the touch area again within the preset time, displaying an abnormal prompt interface, wherein the abnormal prompt interface is used for displaying the detection failure reason, the user proposal and/or the operation control.

As can be seen from the above embodiments, the present application provides a display device, a control apparatus and an exception handling method. The display device monitors whether user contact abnormality occurs in the process of collecting user health data based on contact between the user and the touch area; if the user contact abnormality occurs, detecting whether the user is contacted with the touch area again within a preset time period after the user contact abnormality occurs; if the user is detected to be in contact with the touch area again within the preset time, the health data of the user are continuously collected until the data collection time reaches the preset collection time. Therefore, in the process of collecting the user health data, if the user contact is temporarily disconnected, the user can also continue to collect the data, so that the operation difficulty of the user is reduced, and the data collection failure caused by the short contact failure or improper operation is avoided. In addition, the user pressure can be reduced, the tension mood of the user is avoided, and the user experience is improved.

In a specific implementation, the present invention further provides a computer storage medium, where the computer storage medium may store a program, where the program may include some or all of the steps in each embodiment of the exception handling method provided by the present invention when executed. The storage medium may be a magnetic disk, an optical disk, a read-only memory (ROM), a random-access memory (random access memory, RAM), or the like.

It will be apparent to those skilled in the art that the techniques of embodiments of the present invention may be implemented in software plus a necessary general purpose hardware platform. Based on such understanding, the technical solutions in the embodiments of the present invention may be embodied in essence or what contributes to the prior art in the form of a software product, which may be stored in a storage medium, such as a ROM/RAM, a magnetic disk, an optical disk, etc., including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the method described in the embodiments or some parts of the embodiments of the present invention.

The same or similar parts between the various embodiments in this specification are referred to each other. In particular, for the embodiments, since they are substantially similar to the method embodiments, the description is relatively simple, and reference should be made to the description of the method embodiments for the matters.

The embodiments of the present invention described above do not limit the scope of the present invention.

Claims (8)

1. A display device, characterized by comprising:

a display;

the communicator is used for establishing communication connection with the health data acquisition module and the contact detection module; the health data acquisition module and the contact detection module are respectively connected with the touch area, the health data acquisition module is used for acquiring health data of a user, and the contact detection module is used for detecting contact input by the user on the touch area;

a controller configured to:

after receiving the notification sent by the health data acquisition module indicating to start acquiring data, executing a first timing operation to record the data receiving duration;

in the process of collecting user health data based on the contact between the user and the touch area, receiving a health data packet containing the user health data sent by the health data collecting module; the health data packet also comprises a first identifier for judging whether the user contact abnormality occurs;

if the first identifier in the health data packet represents abnormality, executing a second timing operation to record the duration of the abnormality;

if the first mark in the health data packet is changed from the characterization abnormality to the characterization no abnormality before the abnormality duration reaches the preset duration,

Continuously receiving the health data packet until the data acquisition time length reaches the preset acquisition time length, sending a control instruction for indicating the health data acquisition module to stop acquiring data, and sending a valid data packet in the received health data packet to a cloud server;

and if the effective health data sent by the health data acquisition module is not received before the abnormal duration reaches the preset duration, sending a control instruction for stopping data acquisition to the health data acquisition module.

2. The display device of claim 1, wherein, prior to receiving the indication sent by the health data acquisition module to begin acquiring data, the controller is further configured to:

responding to an input health detection instruction to instruct the health data acquisition module to acquire user health data;

and receiving the user health data sent by the health data acquisition module.

3. The display device of claim 2, wherein the receiving the user health data sent by the health data acquisition module comprises:

and receiving health data packets sent by the health data acquisition module at intervals, wherein the health data packets at least comprise the acquired latest user health data.

4. The display device of claim 2, wherein the controller is further configured to:

and when the data acquisition time length reaches the preset acquisition time length, sending an acquisition stopping instruction to the health data acquisition module so as to close the health data acquisition module.

5. The display device of claim 1, wherein the controller is further configured to:

and if the effective health data sent by the health data acquisition module is not received before the abnormal duration reaches the preset duration, displaying an abnormal prompt interface, wherein the abnormal prompt interface is used for displaying detection failure reasons, user suggestions and/or operation controls.

6. A control apparatus, characterized by comprising:

a touch area;

the touch area is used for being contacted with the user, and the health data acquisition module is used for acquiring health data of the user based on the contact between the user and the touch area;

a controller in communication with the health data acquisition module and the contact detection module configured to:

Responding to a data acquisition instruction sent by display equipment, and controlling the health data acquisition module to start acquiring user health data;

every other preset time length, a health data packet containing the latest user health data and a first identifier is sent to display equipment, wherein the first identifier is used for representing whether detection abnormality and abnormality type exist or not;

when the contact detection module detects that the contact between the user and the touch area is disconnected, a health data packet containing the latest user health data and a first identifier representing the abnormal contact of the user is sent to the display device, so that the display device executes a second timing operation to record the duration of the abnormality;

when the contact detection module detects that the duration of the abnormality is longer than the preset duration, a first mark in the received health data packet is changed from the characteristic abnormality to the characteristic non-abnormality, and the health data packet containing the latest user health data and the first mark indicating the non-detection abnormality is sent to the display equipment;

and when the contact detection module detects that the abnormal duration time reaches the preset duration time, the effective health data sent by the health data acquisition module is not received, and a control instruction for stopping data acquisition sent by the display equipment is received so as to stop data acquisition.

7. An exception handling method, applied to a display device, comprising:

after receiving the notification sent by the health data acquisition module indicating to start acquiring data, executing a first timing operation to record the data receiving duration;

in the process of collecting user health data based on the contact between the user and the touch area, receiving a health data packet containing the user health data sent by the health data collecting module; the health data packet also comprises a first identifier for judging whether the user contact abnormality occurs;

if the first identifier in the health data packet represents abnormality, executing a second timing operation to record the duration of the abnormality;

if the duration of the abnormality is longer than the preset duration, when the first identifier in the health data packet is changed from the abnormal representation to the non-abnormal representation, continuing to receive the health data packet until the data acquisition duration reaches the preset acquisition duration, sending a control instruction for indicating the health data acquisition module to stop acquiring data, and sending the received valid data packet in the health data packet to a cloud server;

and if the effective health data sent by the health data acquisition module is not received before the abnormal duration reaches the preset duration, sending a control instruction for stopping data acquisition to the health data acquisition module.

8. An abnormality processing method, which is applied to a control device, wherein the control device is arranged on a touch area, the method comprising:

responding to a data acquisition instruction sent by the display equipment, and acquiring user health data based on contact between a user and the touch area;

every other preset time length, a health data packet containing the latest user health data and a first identifier is sent to display equipment, wherein the first identifier is used for representing whether detection abnormality and abnormality type exist or not;

when the contact detection module detects that the contact between the user and the touch area is disconnected, a health data packet containing the latest user health data and a first identifier representing the abnormal contact of the user is sent to the display device, so that the display device executes a second timing operation to record the duration of the abnormality;

when the contact detection module detects that the first identifier in the health data packet received before the duration of the abnormality reaches the preset duration, changing the characteristic abnormality into the characteristic non-abnormality, and sending the health data packet containing the latest user health data and the first identifier of the characteristic non-detection abnormality to the display device;

and when the contact detection module detects that the abnormal duration time reaches the preset duration time, the effective health data sent by the health data acquisition module is not received, and a control instruction for stopping data acquisition sent by the display equipment is received so as to stop data acquisition.