WO2022170827A1

WO2022170827A1 - Electronic device, control device, display device, and health check method

Info

Publication number: WO2022170827A1
Application number: PCT/CN2021/134578
Authority: WO
Inventors: 蒋伟; 王守帅; 沈润渊; 徐波; 穆聪聪; 卢可敬; 司洪龙; 姜璐珩; 杨坤; 郑鹏; 杨娟; 刘思波; 张林娜; 程晋
Original assignee: 海信视像科技股份有限公司
Priority date: 2021-02-10
Filing date: 2021-11-30
Publication date: 2022-08-18
Also published as: CN113077860A; CN113077909A; CN113077859A; CN114296578A; CN113077910A; CN114302185B; CN113077909B; CN114903432A; WO2022170828A1; CN113012779B; CN114327345A; CN114903433A; CN113012779A; CN113077861A; CN114302185A; CN114903431A; CN114903430A; WO2022170826A1; CN114903446A

Abstract

Disclosed in some embodiments of the present application are an electronic device, a control device, a display device, and a health check method. The electronic device comprises: a touch module, a health sensing module, and a processing module; the processing module is separately connected to the touch module and the health sensing module; the touch module sends a touch signal to the processing module when a touch of a user is detected; the processing module sends a startup signal to the health sensing module according to the touch signal after the touch signal is received; the health sensing module acquires illumination values reflected by capillaries of the user after the startup signal is received, and sends to the processing module the illumination values reflected by the capillaries of the user; and the processing module generates vital sign data of the user according to the illumination values reflected by the capillaries of the user.

Description

Electronic equipment, control equipment, display equipment, health detection method

This application requires filing on February 10, 2021 with application number 202110182480.8; filed on March 4, 2021 with application number 202110242065.7; filed on March 4, 2021 with application number 202110242169.8; in 2021 Submitted on March 4, 2021, application number 202110241064.0; submitted on March 4, 2021, application number 202110240806.8; submitted on March 4, 2021, application number 202110241118.3; on March 19, 2021 The priority of the Chinese patent application filed with application number 202110298445.2, the entire contents of which are incorporated in this application by reference.

technical field

The present application relates to display device technology, and in particular, to an electronic device, a control device, a display device, and a health detection method.

Background technique

With the rapid development of smart TVs, smart remote controls are also rapidly gaining popularity. The smart remote control can integrate various types of functional modules, so that it can cooperate with smart TVs to better serve home users. For example, the smart remote control can integrate a voice recognition module, so that the user can perform voice input through the smart remote control; the smart remote control can integrate a touch module, so that the user can complete the handwriting input through the smart remote control. However, since there are usually elderly or sub-health users in the family, the existing smart remote control does not include a health detection module, and cannot quickly and conveniently provide a health detection function for the elderly or sub-health users.

SUMMARY OF THE INVENTION

The present application provides an electronic device, a control device, a display device, and a health detection method to realize a health detection function.

Some embodiments of the present application provide an electronic device, including:

Touch module, health sensing module and processing module;

the processing module is respectively connected with the touch module and the health sensing module;

The touch module sends a touch signal to the processing module when detecting a user's touch;

After receiving the touch signal, the processing module sends a turn-on signal to the health sensing module according to the touch signal;

After receiving the turn-on signal, the health sensing module collects the illumination value reflected by the capillaries of the user, and sends the illumination value reflected by the capillaries of the user to the processing module;

The processing module generates the vital sign data of the user according to the light value reflected by the capillaries of the user.

In some embodiments, the health sensing module includes: a power switching circuit and a light collection circuit;

The power switching circuit is respectively connected with the processing module and the illumination collection circuit;

After receiving the turn-on signal, the power switching circuit supplies power to the illumination collection circuit, so that the illumination collection circuit collects the illumination value reflected by the capillaries of the user.

In some embodiments, the power switching circuit includes a first processor;

the first pin of the first processor is connected to the processing module;

After receiving the turn-on signal through the first pin of the first processor, the first processor outputs a switching signal through the second pin of the first processor, and the switching signal is used to The power switching circuit is switched to a first power supply line, and the first power supply line is used to supply power to the light collection circuit.

In some embodiments, a diode is provided in the first power supply line for isolating and protecting the light collection circuit.

In some embodiments, the light collection circuit includes: a second processor, a light-emitting component and a photosensitive component;

The first pin and the second pin of the second processor are connected to the light-emitting component, and form an electrical circuit with the light-emitting component, so that the light-emitting component illuminates the capillaries of the user;

The third pin and the fourth pin of the second processor are connected to the photosensitive component, and form an electrical circuit with the photosensitive component; the photosensitive component transmits the light signal reflected by the capillaries of the user Converting into electrical energy, forming a voltage signal, and sending the voltage signal to the second processor through the third pin and the fourth pin of the second processor, the voltage signal is used to characterize the user The light value reflected by the capillaries.

In some embodiments, the photosensitive component includes a photosensitive cell and a conversion resistor;

The photosensitive cell and the conversion resistor are connected in parallel with the first pin and the second pin of the second processor, respectively.

In some embodiments, the illumination collection circuit further includes: a sampling control circuit;

The sampling control circuit is respectively connected with the light-emitting component and the processing module, and the sampling control circuit is used for sending the current value of the light-emitting component to the processing module; when the current value of the light-emitting component is less than When the threshold value is reached, the switch component in the sampling control unit is turned on under the control of the processing module to amplify the working voltage of the light-emitting component.

In some embodiments, the sampling control circuit further includes a sampling resistor, and the switch component includes a field effect transistor;

The gate of the field effect transistor is connected to the processing module, and is used for receiving the turn-on signal sent by the processing module;

The drain of the field effect transistor is connected to the light emitting component, and is used for amplifying the working voltage of the light emitting component after the field effect transistor is turned on;

The source of the field effect transistor is connected to one end of the sampling resistor, and the other end of the sampling resistor is grounded.

In some embodiments, the touch module includes a third processor, a signal output terminal, a signal input terminal and a touch soft board;

The first pin of the third processor is connected to the signal input end, and the signal input end is connected to the touch soft board, and the touch soft board passes the signal input end to the touch board after detecting the user's contact. the processor sends an input signal;

The second pin of the third processor is connected to the signal output end, and the signal output end is connected to the processing module. After receiving the input signal, the third processor passes the signal The output terminal sends a touch signal to the processing module.

In some embodiments, the touch module further includes a first capacitor;

The first end of the first capacitor is connected to the third pin of the third processor, the second end of the first capacitor is connected to the fourth pin of the third processor, and the third The third pin of the processor is connected to the power supply, and the fourth pin of the third processor is grounded;

The power supply of the electronic device supplies power to the third processor through the third pin of the third processor.

a processing module, a touch module and a health sensing module, the processing modules are respectively connected with the touch module and the health sensing module;

the touch module, configured to generate a touch signal when the user touches, and send the touch signal to the processing module;

the processing module, configured to start the health sensing module according to the touch signal;

The health sensing module is configured to illuminate the capillaries of the user, collect the illumination value reflected by the capillaries of the user, and send the illumination value reflected by the capillaries of the user to the processing module;

The processing module is further configured to determine the vital sign data of the user according to the light value reflected by the capillaries of the user.

In some embodiments, the health sensing module includes: a sensor controller, a light-emitting component and a photosensitive component;

The sensor controller is respectively connected with the light-emitting component, the photosensitive component and the processing module;

the sensor controller, configured to receive a start-up instruction sent by the processing module, and control the light-emitting component to illuminate the capillaries of the user;

The photosensitive component is configured to collect the light value reflected by the capillaries of the user, and send the light value reflected by the capillaries of the user to the sensor controller.

In some embodiments, the sensor controller includes a sampling control unit;

the sampling control unit is connected with the light-emitting assembly and the processor;

the sampling control unit, configured to send the current value of the light-emitting component to the processor;

The processor is further configured to send a turn-on signal to the sampling control unit when the current value of the light-emitting component is less than a threshold value, where the turn-on signal is used to turn on the switch component in the sampling control unit to amplify the The operating voltage of the light-emitting assembly.

In some embodiments, the photosensitive component includes a conversion unit and a photosensitive power supply unit;

Both the conversion unit and the photosensitive power supply unit are connected to the sensor controller;

The photosensitive power supply unit is used to convert the light signal reflected by the capillary of the user into electrical energy, and supply power to the conversion unit;

The conversion unit is used for generating a voltage signal when powered by the photosensitive battery, and transmitting the voltage signal to the sensor controller, where the voltage signal is used to represent the light value reflected by the capillary blood vessels of the user.

In some embodiments, the light emitting assembly comprises a light emitting diode;

The light emitting diodes are used to emit one or more types of light signals to the capillaries of the user.

In some embodiments, the touch module includes a signal output end, a processor and a signal input end;

The processor is respectively connected with the signal output end and the signal input end, and the signal output end is connected with the processing module;

The signal input terminal is used for sending an input signal to the processor after detecting the user's contact;

The processor is configured to send the touch signal to the processing module through the signal input terminal after receiving the input signal.

In some embodiments, the electronic device further includes: a power supply reset module;

The power supply reset module is respectively connected with the processing module and the health sensing module in the health sensing module;

The processor is configured to send a power-on instruction to the power supply reset module according to the touch signal;

The power supply reset module is configured to power on and reset the health sensing module after receiving the power-on instruction.

In some embodiments, the electronic device further includes: an external reference power supply;

the external reference power supply is connected to the processing module;

The external reference power supply is used to power the processing module and provide a voltage reference source.

In some embodiments, the electronic device further includes: a communication module;

the communication module is connected to the processing module;

The processing module is further configured to receive the control instruction sent by the display device through the communication module and send the vital sign data of the user to the display device.

a communication module for communicating with the display device;

a health sensing module, used for illuminating the capillaries of the user, and collecting the illumination value reflected by the capillaries of the user;

a controller, the controller is respectively connected with the health sensing module and the communication module, and the controller is configured to:

receiving, through the communication module, a control instruction sent by the display device, where the control instruction is used to instruct the electronic device to perform health detection;

Start the health sensing module according to the control instruction;

acquiring the light value reflected by the capillaries of the user collected by the health sensing module;

determining the vital sign data of the user according to the light value reflected by the capillaries of the user;

The vital sign data of the user is sent to the display device through the communication module.

a touch module for generating a touch signal when the user touches;

The health sensing module is used to detect the health of users;

The controller is configured as:

Determine the effective touch duration of the user according to the touch signal;

According to the effective touch duration of the user, a turn-on signal is sent to the health sensing module, where the turn-on signal is used to instruct the health sensing module to start health detection.

In some embodiments, the controller is specifically configured to:

If the effective touch duration of the user is greater than or equal to a duration threshold, the activation signal is sent to the health sensing module.

In some embodiments, the controller is specifically configured to:

If the effective touch duration of the user is less than the duration threshold, it is determined that the user's touch is a false touch.

a touch module for generating a touch signal when the user touches;

The health sensing module is used to detect the health of users;

The controller is configured as:

When the touch module generates a touch signal, the health sensing module is controlled to perform fit detection on the user's touch.

In some embodiments, the controller is specifically configured to:

acquiring the light value and ambient light value reflected by the capillary blood vessels of the user collected by the health sensing module;

According to the light value reflected by the capillaries of the user and the ambient light value, the touch detection of the user is performed;

If it is detected that the user's touch fits, a first feedback signal is sent to the health sensing module, where the first feedback signal is used to instruct the health sensing module to continue the health detection.

In some embodiments, the controller is further configured to:

If it is detected that the user's touch does not fit, a second feedback signal is sent to the health sensing module, where the second feedback signal is used to instruct the health sensing module to stop performing the health detection.

In some embodiments, the controller is specifically configured to:

If the difference between the light value reflected by the capillaries of the user and the ambient light value is within the first threshold range, the light value reflected by the capillaries of the user is within the second threshold range, and the ambient light value is within Within the third threshold range, it is determined that the user's touch fits.

In some embodiments, the controller is further configured to:

If it is detected that the user's touch is attached, first indication information is sent to the display device, where the first indication information is used to instruct to open the health detection application in the display device.

In some embodiments, the controller is further configured to:

receiving second indication information sent by the display device, where the second indication information is used to indicate that the health detection is completed;

turning off the power supply of the health sensing module;

Send third indication information to the touch module, where the third indication information is used to instruct the touch module to perform low-power scanning.

Some embodiments of the present application provide a health detection method, including:

Receive the touch signal sent by the touch module when the user touches;

determining the effective touch duration of the user according to the touch signal;

In some embodiments, the sending an on signal to the health sensing module according to the effective touch duration of the user includes:

In some embodiments, the controlling the health sensing module to perform fit detection on the user's touch includes:

In some embodiments, the controlling the health sensing module to perform fit detection on the user's touch further includes:

In some embodiments, the fitting detection of the user's touch according to the light value reflected by the capillaries of the user and the ambient light value includes:

In some embodiments, the method further includes:

turning off the power supply of the health sensing module;

Some embodiments of the present application provide a control device, including:

a controller, the controller is connected to the health sensing module, the controller is configured to:

receiving the light value reflected by the capillaries of the user sent by the health sensing module;

The vital sign data of the user is sent to a display device.

In some embodiments, the vital sign data includes real-time display data packets and raw data packets;

The real-time display data package is used to draw a vital sign curve and display it on the user interface of the display device;

The original data package is used to generate the health report of the user after being forwarded to the server by the display device.

determining the vital sign data of the user according to the light value reflected by the capillaries of the user, where the vital sign data includes a real-time display data packet and an original data packet;

Send the real-time display data package to the display device, and the real-time display data package is used to draw a vital sign curve and display it on the user interface of the display device;

generating a health detection report of the user according to the original data packet;

Send the user's health detection report to the display device.

sending the real-time display data package to a display device, where the real-time display data package is used to draw a vital sign curve and display it on a user interface of the display device;

Sending the original data packet to the server, where the original data packet is used to generate a health report for the user.

In some embodiments, the real-time display data packet includes real-time heartbeat data, and the vital sign curve includes a real-time heartbeat curve;

The controller is specifically configured to:

According to the collection period of the illumination value, a heartbeat analysis algorithm is used to calculate the real-time heartbeat data corresponding to the illumination value reflected by the capillaries of the user.

In some embodiments, the real-time display data package further includes health analysis data; the health analysis data includes at least one of the following: heart rate value, blood oxygen value, microcirculation value, systolic blood pressure value and diastolic blood pressure value.

In some embodiments, the real-time display data package further includes health analysis data;

The controller is specifically configured to:

generating a light value curve corresponding to the light value reflected by the capillaries of the user according to the reporting period of the real-time display data packet;

According to the light value curve, the health analysis data of the user in the reporting period is determined.

Some embodiments of the present application provide a display device, including:

monitor;

a controller connected to the display, the controller configured to:

Receive the real-time display data package and the original data package sent by the remote control device, the real-time display data package includes the user's vital sign data, the real-time display data package is used to draw the vital sign curve, and the original data package is used to generate all the data. the user's health report;

Drawing the user's vital sign curve according to the real-time display data package;

displaying the user's vital sign curve on the user interface of the display device;

Send the original data packet to the server.

Some embodiments of the present application provide a server, including:

memory;

a controller, the controller being a processor connected to the memory, the controller being configured to:

receiving an original data packet sent by the display device, where the original data packet includes the original vital sign data of the user collected by the control device;

Send the user's health detection report to the display device.

Determine the vital sign data of the user according to the light value reflected by the capillaries of the user;

The vital sign data of the user is sent to a display device.

Description of drawings

FIG. 1 is a schematic diagram of an operation scenario between a display device and a control device according to some embodiments of the present application;

FIG. 2 is a block diagram of a hardware configuration of a control device 100 according to some embodiments of the present application;

FIG. 3 is a block diagram of a hardware configuration of a display device 200 according to some embodiments of the present application;

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

FIG. 5 is a display diagram of an icon control interface of an application in a display device 200 according to some embodiments of the present application;

FIG. 6 is a system architecture diagram of a health detection according to some embodiments of the present application;

7a-7d are schematic interface diagrams of a display device according to some embodiments of the present application;

8 is a schematic structural diagram of a remote control device according to some embodiments of the present application;

FIG. 9 is a schematic structural diagram of a health sensing module according to some embodiments of the present application;

10 is a schematic layout diagram of a detection area of a remote control device according to some embodiments of the present application;

11 is a schematic diagram of a structural stack of a detection area according to some embodiments of the present application;

12 is a schematic layout diagram of a detection area of another remote control device according to some embodiments of the present application;

13 is a schematic diagram of a structure stacking of another detection area according to some embodiments of the present application;

14 is a schematic diagram of the location of a detection area according to some embodiments of the present application;

15a is a circuit diagram of a health sensing module according to some embodiments of the present application;

15b is a circuit diagram of another health sensing module according to some embodiments of the present application;

16a is a schematic circuit diagram of a controller in a health sensing module according to some embodiments of the present application;

16b is a schematic circuit diagram of a software debugging unit according to some embodiments of the present application;

16c is a schematic circuit diagram of a power supply reset unit according to some embodiments of the present application;

17 is a schematic circuit diagram of an external reference power supply in a health sensing module according to some embodiments of the present application;

18 is a schematic circuit diagram of an external communication interface in a health sensing module according to some embodiments of the present application;

19 is a schematic diagram of an interface displayed in real time by a display device according to some embodiments of the present application;

20a-20b are schematic diagrams of interfaces for displaying health detection results on a display device according to some embodiments of the present application;

21a is a schematic circuit diagram of a touch module according to some embodiments of the present application;

21b is a schematic circuit diagram of another touch module according to some embodiments of the present application;

22 is a schematic interface diagram of a health management application according to some embodiments of the present application;

FIG. 23 is a startup page of an application according to some embodiments of the present application;

24 is a user agreement presentation page of an application according to some embodiments of the present application;

FIG. 25 is an application home page of an application according to some embodiments of the present application;

26 is a profile information input interface according to some embodiments of the present application;

27 is a file management interface according to some embodiments of the present application;

28 is a schematic diagram of an interaction process between a display device and a remote control according to some embodiments of the present application;

FIG. 29 is an operation guidance interface according to some embodiments of the present application;

30 is a detection result interface according to some embodiments of the present application;

FIG. 31 is another detection result interface according to some embodiments of the present application.

Detailed ways

In order to make the objectives, implementations and advantages of the present application clearer, the exemplary embodiments of the present application will be described clearly and completely below with reference to the accompanying drawings in the exemplary embodiments of the present application. Obviously, the exemplary embodiments described It is only a part of the embodiments of the present application, but not all of the embodiments.

Based on the exemplary embodiments described in this application, all other embodiments obtained by those of ordinary skill in the art without creative efforts shall fall within the protection scope of the appended claims of this application. Furthermore, although the disclosures in this application have been presented in terms of illustrative example or instances, it should be understood that various aspects of this disclosure may also constitute a complete embodiment in isolation. It should be noted that the brief description of the terms in the present application is only for the convenience of understanding the embodiments described below, rather than intended to limit the embodiments of the present application. Unless otherwise specified, these terms are to be understood according to their ordinary and ordinary meanings.

FIG. 1 is a schematic diagram of an operation scenario between a display device and a control device according to some embodiments of the present application. As shown in FIG. 1 , a user can operate the display device 200 through a mobile terminal 300 and the control device 100 . The control apparatus 100 may be a remote control, and the communication between the remote control and the display device includes infrared protocol communication, Bluetooth protocol communication, and wireless or other wired ways to control the display device 200 . The user can control the display device 200 by inputting user instructions through keys on the remote control, voice input, control panel input, and the like. In some embodiments, mobile terminals, tablet computers, computers, notebook computers, and other smart devices may also be used to control the display device 200 .

In some embodiments, the mobile terminal 300 may install a software application with the display device 200 to implement connection communication through a network communication protocol, so as to achieve the purpose of one-to-one control operation and data communication. The audio and video content displayed on the mobile terminal 300 may also be transmitted to the display device 200 to realize a synchronous display function. The display device 200 also performs data communication with the server 400 through various communication methods. The display device 200 may be allowed to communicate via local area network (LAN), wireless local area network (WLAN), and other networks. The server 400 may provide various contents and interactions to the display device 200 . The display device 200 may be a liquid crystal display, an OLED display, or a projection display device. The display device 200 may additionally provide an intelligent network television function that provides a computer-supported function in addition to the function of broadcasting and receiving television.

FIG. 2 exemplarily shows a configuration block diagram of the control apparatus 100 according to 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 device 100 can receive the user's input operation instruction, and convert the operation instruction into an instruction that the display device 200 can recognize and respond to, and play an intermediary role between the user and the display device 200 . The communication interface 130 is used for external communication, and includes at least one of a WIFI chip, a Bluetooth module, NFC or an alternative module. The user input/output interface 140 includes at least one of a microphone, a touchpad, a sensor, a key or an alternative module.

FIG. 3 is a block diagram showing a hardware configuration of the display apparatus 200 according to an exemplary embodiment. As shown in FIG. 3 , the display device 200 includes a tuner 210 , a communicator 220 , a detector 230 , an external device interface 240 , a controller 250 , a display 260 , an audio output interface 270 , a memory, a power supply, and a user interface 280 . at least one. The controller includes a central processing unit, a video processing unit, an audio processing unit, a graphics processing unit, a RAM, a ROM, and a first interface to an nth interface for input/output. The display 260 may be at least one of a liquid crystal display, an OLED display, a touch display, and a projection display, and may also be a projection device and a projection screen. The tuner-demodulator 210 receives broadcast television signals through wired or wireless reception, and demodulates audio and video signals, such as EPG data signals, from a plurality of wireless or wired broadcast television signals. The detector 230 is used to collect external environment or external interaction signals. The controller 250 and the tuner 210 may be located in different separate devices, that is, the tuner 210 may also be located in an external device of the main device where the controller 250 is located, such as an external set-top box.

In some embodiments, the controller 250, through various software control programs stored on the memory, controls the operation of the display device and responds to user operations. The controller 250 controls the overall operation of the display apparatus 200 . A user may input a user command on 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 a user command by inputting a specific sound or gesture, and the user input interface recognizes the sound or gesture through a sensor to receive the user input command.

In some embodiments, a "user interface" is a medium interface for interaction and information exchange between an application program or an operating system and a user, which enables conversion between an internal form of information and a form acceptable to the user. The commonly used form of user interface is Graphical User Interface (GUI), which refers to a user interface related to computer operations displayed in a graphical manner. It can be an icon, window, control and other interface elements displayed on the display screen of the electronic device, wherein the control can include icons, buttons, menus, tabs, text boxes, dialog boxes, status bars, navigation bars, Widgets, etc. at least one of the visual interface elements.

FIG. 4 is a schematic diagram of software configuration in the display device 200 according to some embodiments of the present application. As shown in FIG. 4 , the system is divided into four layers. , the Application Framework layer (referred to as the "framework layer"), the Android runtime (Android runtime) and the system library layer (referred to as the "system runtime layer"), and the kernel layer. The kernel layer contains at least one of the following drivers: audio driver, display driver, Bluetooth driver, camera driver, WIFI driver, USB driver, HDMI driver, sensor driver (such as fingerprint sensor, temperature sensor, pressure sensor, etc.), and power supply drive etc.

FIG. 5 is a schematic diagram showing an icon control interface of an application in a display device 200 according to some embodiments of the present application. As shown in FIG. 5 , the application layer includes at least one application that can display a corresponding icon control on the display, such as: Live TV application icon control, video on demand application icon control, media center application icon control, application center icon control, game application icon control, etc. Live TV app that can provide live TV from different sources. Video-on-demand application that can provide video from different storage sources. Unlike live TV applications, video-on-demand provides a display of video from certain storage sources. A media center application that can provide a variety of multimedia content playback applications. The application center can provide storage of various applications.

With the rapid development of smart TVs, smart remote controls are also rapidly gaining popularity. The smart remote control can integrate various types of functional modules, so that it can cooperate with smart TVs to better serve home users. For example, a smart remote control can integrate a voice recognition module, so that the user can perform voice input through the smart remote control; the smart remote control can integrate a touch module, so that the user can complete handwriting input through the smart remote control. Based on this, some embodiments of the present application provide a remote control device and a display device to quickly and conveniently provide a user with a health detection function. In this application, a health sensing module is set on the smart remote control to collect the user's vital sign data, so as to obtain the user's health detection result according to the user's vital sign data analysis. In this way, the remote control device can quickly and conveniently provide the user with health detection. The above-mentioned remote control device may be one of the control devices shown in FIG. 1 to FIG. 5 .

FIG. 6 is a system architecture diagram of a health detection according to some embodiments of the present application. As shown in FIG. 6 , the health detection system provided by the embodiment of the present application includes a remote control device, a display device, and a server, and the display device interacts with the remote control device and the server respectively.

In the embodiment of the present application, a health sensing module is added to the remote control device. When the user performs health detection, the remote control device can collect the user's vital sign data according to the control instructions in the control flow transmitted by the display device, and analyze the collected data. The user's vital sign data is processed, and the processed user's vital sign data is sent to the display device.

In some embodiments, vital sign data may include heart rate, blood pressure, blood oxygen, and the like. It should be noted that the vital sign data involved in the embodiment of the present application does not constitute a limitation, and specific settings may be made according to the actual situation, for example, the pulse may also be included. It should be understood that the embodiments of the present application do not limit how to perform data transmission between the remote control device and the display device. For example, it may include but not be limited to using Bluetooth (bluetooth, BLE) communication, infrared communication, WiFi communication, and the like. Exemplarily, as shown in FIG. 6 , the remote control device can perform data transmission with the display device through BLE. It should be understood that data transmission between the remote control device and the display device may be performed through data streams and/or control streams. Exemplarily, continuing to refer to FIG. 6 , the remote control device and the display device send control flows to each other. For example, the remote control device may send a control flow including a power-on command to the display device, and the display device may send a control flow including a power-saving mode command to the remote control device. ; The remote control device and the display device can also send data streams to each other.

In some embodiments, the data stream sent by the remote control device to the display device may include the user's vital sign data, and the control stream sent between the remote control device and the display device includes various control information. The control information may include control information for the display device to instruct the remote control device to perform health detection, control information for the remote control device to instruct the display device to open a health management application, and the like. In addition, the control information may also include control information such as volume adjustment, program adjustment, determination, and return. Exemplarily, if the user needs to open the health management application, by pressing the button of the remote control device, the control information instructing the display device to open the health management application can be sent to the display device through the control flow. Then, the display device opens the health management application according to the control information for opening the health management application, and sends the control information for health detection to the remote control device through the control flow. After receiving the control information for health detection, the remote control device turns on the health sensing module, and reminds the user to perform health detection by flickering, sounding, etc. Subsequently, after the user completes the health check, the remote control device sends the user's vital sign data to the display device through a data stream.

It should be noted that the remote control device can send the user's vital sign data to the display device in real time, and can also send the user's vital sign data to the display device at regular intervals, which is not limited in this embodiment of the present application. Exemplarily, when the user holds the remote control device to trigger automatic detection of the remote control device, after the remote control device collects the user's vital sign data, it is first stored in the cache module, and can be displayed to the display device at regular intervals (for example, ten minutes). The device sends the user's vital signs data once. Exemplarily, if the user actively sends an instruction to the remote control device through the display device to detect his own vital sign data through the remote control device, the remote control device can send the user's vital sign data to the display device in real time during the detection process. In addition, the embodiments of the present application do not limit how the remote control device processes the user's vital sign data. In some embodiments, the remote control device can remove invalid data in the user's vital sign data. In other embodiments, the remote control device Abnormal data may also be identified in the user's vital sign data. In some embodiments, the remote control device may not process the user's vital sign data, and send all detection data to the display device.

In some embodiments, the data collected by the remote control device is first stored in the storage module, and the display device can actively send an instruction to acquire the data collected by the remote control device. After the remote control device receives the instruction, the data stored in the storage module is sent to the display device. equipment.

In this embodiment of the present application, a health management application may be installed in the display device. Through the health management application, the display device can send a control instruction to the remote control device to instruct the remote control device to perform health detection. Through the health management application, the display device can also receive the user's vital sign data sent by the remote control device, and send the user's vital sign data to the server corresponding to the health management application. Meanwhile, after the server completes the analysis of the user's vital sign data and sends the user's health detection result to the display device, the display device can also display the user's health detection result through the health management application.

In some embodiments, the display device may transmit the received vital sign data of the user to the server in real time. In other embodiments, the display device may continuously store the user's vital sign data sent by the remote control device, when the stored user's vital sign data exceeds a data volume threshold and/or when the stored user's vital sign data exceeds a time threshold , the display device sends the stored vital sign data of the user to the display device. It should be understood that the embodiments of the present application do not limit how data transmission is performed between the display device, the remote control device, and the server. Exemplarily, the display device has a Bluetooth host function and a wireless fidelity (Wireless Fidelity, WiFi) function. Through the Bluetooth host function, the data transmission between the display device and the remote control device can be realized. Through the WiFi function, the display device can be connected to the network, and data transmission can be performed with the server through the network.

In some optional embodiments, the display device may also not need to interact with the server. Exemplarily, after the display device receives the vital sign data sent by the remote control device, the display device may act as a server to directly analyze the user's vital sign data to obtain the user's health detection result. In some other optional embodiments, the display device may also display the vital sign data of a part of the user in real time for display, and then send the vital sign data of another part of the user to the server. Exemplarily, the display device can display the user's blood oxygen and heart rate data in real time, and send the original user's vital sign data to the server, and the server processes the original user's vital sign data to obtain the user's complete health detection result. After that, it is sent to the display device for display.

In some embodiments, the display device receives the data sent by the remote control device to form backup data, one copy of the data is used for real-time display, and the other copy of the data is sent to the server for data analysis, so that the display and data analysis can be performed simultaneously. After the data is collected, a health detection report is obtained and sent back to the display device for display.

In some embodiments, the server may not wait for all data to be collected before forming the health detection report, but may form a preliminary report by using a part of the data, and then use a part of the data to optimize the preliminary report. In this way, if the remote control device is still sending data in real time and displaying it on the display device after the health inspection report is completed, the health inspection report can be stored in the server, and the health inspection report will be displayed after the real-time data display is completed.

In other embodiments, if the remote control device is directly connected to the Internet, the remote control device can send the user's vital sign data to the display device and the server at the same time, so that the display device does not need to forward the user's vital sign data to the server. After receiving the user's vital sign data sent by the remote control device, the server can directly process the user's vital sign data, generate a health detection report, and then send the health detection report to the display device for display.

In some embodiments, during the real-time data display process, if a preliminary report has been formed, a mark may be formed on the user interface to prompt the user to click to view the report. Exemplarily, Fig. 7a is a schematic interface diagram of a display device according to some embodiments of the present application. As shown in Fig. 7a, when the display device displays the user's vital sign data in real time, if the display device receives the initially generated health information sent by the server If the test report is detected, the "Report Generated" button can be displayed on the interface. If the user clicks the "Report has been generated" button, the display device can display the initially generated health detection report. It should be understood that the embodiments of the present application do not limit how the server processes the user's vital sign data. In some embodiments, the server may compare the user's vital sign data with standard vital sign data to determine whether there is a certain item Vital signs data do not match health representations. In other embodiments, the server may further analyze the user's vital sign data in combination with the user's historical vital sign data to obtain the user's physical health trend.

In some embodiments, the user's health detection report may be stored on a display device or a server, so that the user can view a certain health detection report. Of course, the user can also view the health detection reports of other users to understand the user's health status. It should be understood that the display device in the embodiment of the present application may display the health detection result of the user in various ways. Exemplarily, FIG. 7b is a schematic interface diagram of a display device according to some embodiments of the present application. As shown in FIG. 7b, the display device may display the user's health detection result in a table, in which the user's abnormality is displayed. The vital sign data is compared with the standard vital sign data; exemplarily, FIG. 7c is a schematic interface diagram of a display device according to some embodiments of the present application. As shown in FIG. 7c, the display device can display the user in the form of a line graph 7d is a schematic interface diagram of a display device according to some embodiments of the present application, as shown in FIG. 7d The display device displays the user's health detection results in the form of a human body map, and the human body map uses a specific color to mark parts that may have potential health risks in the human body map.

Based on the above description, the following describes how the remote control device collects the user's vital sign data by describing the hardware structure of the remote control device. FIG. 8 is a schematic structural diagram of a remote control device according to some embodiments of the present application. As shown in FIG. 8 , the remote control device includes a processing module, a touch module, a health sensing module and a power supply module. The touch module is used for electrostatic touch detection on the user, so as to send a trigger signal to the processing module, and the processing module is used to determine whether to send a start instruction to the health sensing module to instruct the health sensing module to start according to the trigger signal sent by the touch module. Health detection (eg determined by MCU and BT). The health sensing module is used to illuminate the capillaries of the user after receiving the activation instruction, receive the light signal reflected by the capillaries, and analyze the light signal reflected by the capillaries, so as to obtain the vital sign data of the user. The power module is used to supply power to each module in the remote control device, and adjust the power supply voltage of each module in real time.

FIG. 9 is a schematic structural diagram of a health sensing module according to some embodiments of the present application. As shown in FIG. 9 , the health sensing module includes a sensor controller, a light-emitting component, a photosensitive component, and the like. The power module supplies power to the sensor controller, the light-emitting component and the photosensitive component respectively. Among them, the sensor controller includes a sensor chip, which is used to control the light-emitting component to emit light, analyze the reflected light signal collected by the light-sensitive component, and convert the light signal collected by the light-sensitive component into the user's vital sign data. It should be understood that the embodiments of the present application do not limit the type of the sensor controller, which may be specifically set according to actual conditions. In the embodiment of the present application, the light-emitting component includes at least two light-emitting diodes (Light Emitting Diode, LED), and the at least two LEDs can emit light of at least two wavelengths under the control of the sensor chip, thereby illuminating the light in the user's skin. capillaries. It should be understood that the embodiments of the present application do not limit the wavelengths of light emitted by at least two LEDs. For example, taking LED1 and LED2 as examples, LED1 can emit light with a wavelength of 560 nanometers (nm), and LED2 can emit light with a wavelength of 560 nanometers (nm). 905nm light. It should be understood that the light-emitting assembly in the embodiment of the present application emits light of at least two wavelengths, so that the light of at least two wavelengths can be compared with ambient light to detect the fit of the finger, that is, the dual light effect recognition technology is adopted. Using at least two wavelengths of light can greatly improve the detection accuracy of finger fit detection compared to using a single wavelength of light.

In the embodiments of the present application, the photosensitive components are used to collect light signals reflected by capillaries. In some embodiments, the photosensitive components can also collect ambient light signals. It should be understood that the embodiments of the present application do not limit the types of photosensitive components, and examples thereof may be photodiodes (photodiode, PD), silicon photovoltaic cells, and the like. Exemplarily, since the PD has unidirectional conductivity, its electrical properties will change when the light intensity is different, so that the light signal reflected by the capillary and the ambient light signal can be collected.

In this embodiment of the present application, after the user instructs the remote control device to perform health detection, if it is detected that the user's skin is close to the health sensing module, the sensor chip can control at least two LEDs to emit light of at least two wavelengths. After illuminating the capillaries in the user's skin, the light of at least two wavelengths is reflected by the capillaries respectively. Then, the light signal reflected by the capillaries and the ambient light signal are collected by the photosensitive components, and then the light signal reflected by the capillary and the ambient light signal are analyzed by the sensor chip to obtain the user's vital sign data.

This embodiment of the present application does not limit how to obtain the user's vital sign data from the signal. Exemplarily, the absorption of light by connecting tissues such as muscles and bones is basically unchanged. Absorption also changes with flow. Therefore, the light signals reflected by capillaries can be divided into DC signals and AC signals. By extracting the AC signal from the light signal reflected by the capillaries, the flow characteristics of the blood can be analyzed from the AC signal, and then the user's vital sign data can be analyzed. It should be understood that the sensor chip, the at least two LEDs and the photosensitive components in the remote control device are all powered by the power supply module. The embodiments of the present application do not limit the voltage intensity of the at least two LEDs when they emit light, and can be adjusted by the power module according to the ambient light signal and the light signal reflected by the capillaries.

In some embodiments, a detection area may be set on the remote control device, and a health detection module and a touch module may be arranged in the detection area at the same time. A schematic diagram of the layout of the detection areas of the two remote control devices is provided below. FIG. 10 is a schematic layout diagram of a detection area of a remote control device according to some embodiments of the present application. As shown in FIG. 10 , the detection area is provided with at least one electrostatic touch area, light-emitting component emission area, and photosensitive component receiving area, and at least one electrostatic touch area, light-emitting component emission area, and photosensitive component receiving area are all set in the on the substrate. The emission area of the light-emitting component is arranged above the receiving area of the photosensitive component, and the emission area of the light-emitting component and the receiving area of the photosensitive component are respectively surrounded by four electrostatic touch areas. Among them, the electrostatic touch area is used to determine whether the user touches effectively by analyzing the electrostatic intensity and the effective time of electrostatic touch when the user touches the electrostatic touch area; the emission area of the light-emitting component is used to emit light signals to the capillaries of the user; the photosensitive component receives Light signals reflected by regional capillaries as well as ambient light signals. It should be noted that the embodiments of the application do not limit the number of electrostatic touch areas. By setting electrostatic touch areas around the detection area, the probability of being detected when a user touches can be improved. In practical applications, the number of electrical touch areas can be increased or decreased according to the actual situation. It should be understood that the embodiments of the present application do not limit the size of the electrostatic touch area, the emission area of the light-emitting component, and the receiving area of the photosensitive component. Exemplarily, the electrostatic touch areas on the left and right sides can be set to be symmetrical and have the same size; The electrostatic touch area on the side can be set to be symmetrical and of the same size.

FIG. 11 is a schematic diagram of a structural stack of a detection area according to some embodiments of the present application. Fig. 11 is a stack of structures corresponding to the detection area shown in Fig. 10. As shown in Fig. 11, the health detection module can be arranged between two plastic shells, a surface glass can be arranged above the health detection module, and two substrates can be used to The surface glass is isolated from the health detection module. It should be understood that the schematic diagram of the structure stacking of the detection regions shown in FIG. 11 is only an example, and the stacking manner of the detection regions may be adjusted according to specific conditions in practical applications, which is not limited by the embodiment.

In some embodiments, the emission area of the light emitting component in the health detection module can emit light. When the user touches the cover glass of the detection area to block the light emitted by the emission area of the light emitting component, the light emitted by the emission area of the light emitting component will be reflected to the The photosensitive component receiving area is collected by the photosensitive component receiving area. It should be understood that the embodiments of the present application do not limit the type of light emitted by the emission area of the light emitting component, for example, it may be red light, blue light, infrared light, and the like. In some embodiments, the light emitting assembly emission area may include two LEDs, thereby emitting red light and infrared light simultaneously. It should be understood that the embodiments of the present application do not limit the photosensitive components in the photosensitive component receiving area, and examples thereof may include photodiodes (photodiode, PD), silicon photovoltaic cells, and the like. It should be understood that the embodiments of the present application do not limit the type of the substrate. Exemplarily, the substrate may be a printed circuit board (Printed Circuit Board, PCB), a flexible circuit board (Flexible Printed Circuit, FPC) and the like.

FIG. 12 is a schematic layout diagram of a detection area of another remote control device according to some embodiments of the present application. As shown in FIG. 12 , the detection area is provided with an electrostatic touch area, a light-emitting component emitting area, and a photosensitive component receiving area. A light-emitting component emission area is arranged above the photosensitive component receiving area, and an electrostatic touch area is arranged below the photosensitive component receiving area. In the embodiment of the present application, for the detection area shown in FIG. 12 , since the electrostatic touch area is arranged below the emission area of the light-emitting component and the receiving area of the photosensitive component, it can reduce the user's mistaken contact with the electrostatic touch area during the case process. It should be understood that the layout of the detection area shown in FIG. 12 is only an example, and does not constitute a limitation of the present application. In some embodiments, the detection area may simultaneously include multiple electrostatic touch areas, multiple light-emitting component emission areas and Multiple photosensitive component receiving areas. In other embodiments, the emitting area of the light-emitting component may also be arranged below the receiving area of the photosensitive component, and the electrostatic touch area may be arranged above the receiving area of the photosensitive component.

FIG. 13 is a schematic diagram of a structural stack of another detection area according to some embodiments of the present application. Fig. 13 is a stack of structures corresponding to the detection area shown in Fig. 12. As shown in Fig. 13, the health detection module can be arranged between two plastic shells, and the health detection module and the plastic shell can be basically isolated by using two pieces. A surface glass may be provided above the detection module. In the embodiment of the present application, since the health sensing module and the surface glass are closely attached, the light of the light-emitting component can be prevented from directly leaking into the receiving area of the photosensitive component. At the same time, since the electrostatic touch area, plastic casing and surface glass are closely attached, the sensitivity and consistency of electrostatic induction can be ensured. It should be understood that the schematic diagram of the structure stacking of the detection regions shown in FIG. 13 is only an example, and the stacking manner of the detection regions may be adjusted according to specific conditions in practical applications, which is not limited by the embodiment. It should be noted that the working principle of the detection area shown in FIG. 12 is similar to the working principle of the detection area shown in FIG. 10 , and will not be described again. It should be noted that the embodiment of the present application does not limit the position of the user's contact detection area, which may be, for example, areas such as the pulp of the user's finger, the user's wrist, and the like.

It should be understood that the detection area can be set in any area of the remote control device. In some embodiments, the detection area can be set on the front of the remote control device. In other embodiments, the detection area can be set on the back of the remote control device. In some embodiments, the detection area may be provided on the side of the remote control device. Exemplarily, FIG. 14 is a schematic diagram of the location of a detection area according to some embodiments of the present application. As shown in FIG. 14 , the detection area may be set on the front of the remote control device and below the buttons. Since the position usually coincides with the area where the user holds the remote control device, it is more convenient for the user to carry out the health measurement when the user holds the remote control device.

FIG. 15a is a circuit diagram of a health sensing module according to some embodiments of the present application. As shown in Figure 15a, the circuit diagram of the health sensing module includes a processor, a light-emitting component, a photosensitive component, and a sampling control component. The processor is respectively connected with the light-emitting component, the photosensitive component, and the sampling control component. The sampling control component is also connected with the light-emitting component and the sampling control component. Photosensitive component connection. The processor is used to control the light-emitting component, the photosensitive component and the sampling control component, the light-emitting component is used to emit light signals to the capillaries, and the photosensitive component is used to receive the light signals emitted by the capillaries and ambient light signals. The sampling control component is used to collect the voltage of the light-emitting component and the photosensitive component, and control the light-emitting intensity of the light-emitting component according to the collected voltage.

Fig. 15b is a circuit diagram of another health sensing module according to some embodiments of the present application. Based on Fig. 15a, Fig. 15b is an exemplary circuit diagram. As shown in FIG. 15b, the processor may include a sensor chip U4, the photosensitive component may include a conversion resistor R2 and a silicon photocell X, the light-emitting component may include LED1, LED2, and LED3, and the sampling control component may include a field effect transistor (Metal-Oxide-Semiconductor). Field-Effect Transistor, MOS) tube and sampling resistor R10. Among them, the

pins

1 and 5 of the sensor chip U4 are connected to the conversion resistor R2 and the silicon photocell X at the same time, the

pins

2 and 6 of the sensor chip U4 are connected to the LED1, the

pins

3 and 4 of the sensor chip U4 are connected to the LED2, and the sensor chip U4 is connected to the LED2.

Pins

7 and 8 of U4 are connected to LED3, and one end of the MOS tube is connected to

pins

4, 6, 7, and 8 of sensor U4 and the sampling resistor R10.

Among them, the sampling resistor R10 samples the currents of LED1, LED2 and LED3 and transmits it to the external control device (such as the controller in the health sensing module). When the currents of LED1, LED2 and LED3 sampled by the sampling resistor R10 are less than the threshold, the external The control device can send a turn-on signal to the gate of the MOS tube, thereby turning on the MOS tube, and amplifying the voltages of LED1, LED2 and LED3 through the MOS tube to increase the light intensity of LED1, LED2 and LED3, so that LED1, LED2 and LED3 are in a suitable brightness. The light of LED1, LED2 and LED3 illuminates the capillaries of the user, and the light signals are reflected to the silicon photocell X through the capillaries. Then, the silicon photocell X converts the light signal reflected by the capillary into a current signal and outputs it to the conversion resistor R2, and then the current signal is converted into a voltage signal by the conversion resistor R2. Finally, the conversion resistor R2 outputs the converted voltage signal to the sensor chip U4.

It should be understood that the embodiments of the present application do not limit the number of LEDs in the light emitting module, and multiple different types of LEDs can be used to achieve dual light effect recognition when detecting a user's touch, thereby improving detection accuracy. It should be understood that the embodiment of the present application does not limit the sampling manner of the sampling resistor R10 , and precision resistance sampling may be used. It should be understood that the embodiments of the present application do not limit the three types of LEDs, and examples may include red LEDs, blue LEDs, and infrared LEDs.

It should be noted that the above-mentioned FIG. 15b is only a circuit diagram of an available health sensing module, and does not constitute a limitation of the present application. In specific applications, the circuit diagram of the health sensing module can be adjusted accordingly according to the actual situation. Exemplarily, the circuit of the sensor chip shown in FIG. 15b includes three types of LEDs, and in specific applications, it can be adjusted to two types of LEDs, and can also be adjusted to four types of LEDs. Exemplarily, the photosensitive component in the circuit of the sensor chip shown in FIG. 15b is a silicon photovoltaic cell X, and in a specific application, the silicon photovoltaic cell X can be adjusted to a PD. Among them, the PD usually works in the reverse bias state, which can obtain a wider linear output and a higher response frequency. The stronger the illumination, the stronger the photocurrent. Silicon photovoltaic cells mainly work without bias voltage, and convert optical signals into electrical signals under illumination. The larger the illuminated junction area, the larger the photocurrent. Therefore, the response speed is faster when using PD, and the junction area receiving light is larger when using silicon photovoltaic cells.

In some embodiments, the health sensing module may further include a controller to control the operation of the above-mentioned sensor chip, and convert the voltage signal obtained by the sensor chip U4 into the user's vital sign data. FIG. 16a is a schematic circuit diagram of a controller in a health sensing module according to some embodiments of the present application. As shown in Figure 16a, the controller of the health sensing module is respectively connected with the power supply reset component, the external communication interface, the external reference power supply, and the software debugging component. Among them, the software debugging component is used to debug the software program in the controller in the health sensing module; the external reference power supply is used to provide internal power supply and reference source for the controller in the health sensing module; the external communication interface is used to realize the health transmission The communication between the sensor module and external devices; the power supply reset component is used to power-on reset the controller in the health sensor module.

In some embodiments, the controller of the health sensing module may also be connected with the light emitting component, the photosensitive component and the sampling control component in Fig. 15a. The controller of the health sensing module can receive the light signal reflected by the capillary blood collected by the photosensitive component and the voltage signal converted from the ambient light signal. At the same time, the controller of the health sensing module can also collect current information of the light-emitting component, and send a turn-on signal to the sampling control component when the current signal is less than the threshold to turn on the MOS tube in the sampling control component.

On the basis of Fig. 16a, the following example provides a connection mode of the pins of the controller in the health sensing module. Exemplarily, pins 9 and 10 of the controller in the health sensing module are connected to a software debugging unit (ECK, EDIO), so as to debug the software program in the controller in the health sensing module through the software debugging unit. The pins 12, 17-19 of the controller in the health sensing module are connected to the external reference power supply (VDDA, VA1V2) to provide internal power supply and reference source for the controller in the health sensing module through the external reference power supply. The pins 1, 21 and 26 of the controller in the health sensing module are respectively connected with LED1 (G_ON), LED2 (R_ON) and LED3 (IR_ON) in the sensor chip circuit, so as to collect the voltage signals of LED1, LED2 and LED3; health The pins 13 and 14 of the controller in the sensing module are connected to both ends (AJO0, AJO1) of the conversion resistor R2 in the sensor chip circuit, so as to collect the voltage signal converted by the conversion resistor R2; the controller in the health sensing module The pins 11 and 16 of the sensor chip are connected to the MOS tubes (OP_OUT, AJO3) in the sensor chip circuit. Subsequently, after the controller in the health sensing module collects the above-mentioned signal, the above-mentioned signal may be internally amplified, and then converted into a digital signal. Pins 23-25 and 32 of the controller in the health sensing module are respectively connected with external communication interfaces (STA, UTX, URX, RESETn), so as to communicate with external devices through the external communication interfaces.

In some embodiments, after the processor of the health sensing module receives a start-up instruction sent by the processing module of the remote control device through the external communication interface, the processor of the health sensing module can turn on the power module to supply power to the sensor chip, thereby performing Health check. Subsequently, after the sensor chip completes the health detection and the processor of the health sensing module collects the voltage signal converted by the conversion resistor R2, the voltage signal can be internally amplified, and then converted into a digital signal to obtain the user's vital signs. data.

This embodiment of the present application does not limit the structure of the software debugging unit. By way of example, FIG. 16b is a schematic circuit diagram of a software debugging unit according to some embodiments of the present application. The software debugging unit shown in Figure 16b may include grounding resistors R7 and R8, so as to suppress external interference and reduce power consumption. Through TP3 and TP4, it can be connected with external devices, and then the software debugging of the controller of the health sensor module can be performed. The resistance values of the grounding resistors R7 and R8 can be specifically set according to the actual situation, for example, they can be 100kΩ. It should be noted that FIG. 16b is a schematic circuit diagram of an available software debugging unit, which does not constitute a limitation on the software debugging unit.

This embodiment of the present application does not limit the structure of the power supply reset unit. For example, FIG. 16c is a schematic circuit diagram of a power supply reset unit according to some embodiments of the present application. The power supply reset unit shown in FIG. 16c may include resistors and capacitors. For example, the power supply reset unit may include capacitors C1, C2, C3 and a resistor R1. Among them, the resistor R1 and the capacitor C3 form a Resistor-Capacitance circuit (RC) to power on the reset controller in the health sensing module, and the capacitors C2 and C3 are used for filtering. It should be noted that the embodiments of the present application do not limit the parameters of the capacitors C1 , C2 , C3 and the resistor R1 of the power module, which can be set in actual conditions. Exemplarily, C1, C2, and C3 may all be 0.1uF/10V, and R1 may be 10kΩ. In addition, the embodiments of the present application do not limit the external reference power supply and the external communication interface in the health sensing module. The following exemplarily takes FIG. 17 and FIG. 18 as examples to describe the external reference power supply and the external communication interface.

FIG. 17 is a schematic circuit diagram of an external reference power supply in a health sensing module according to some embodiments of the present application. As shown in Figure 17, the pin 1 (OUT) of the chip U5 of the external reference power is connected to the pin 19 of the processor in the health sensing module; the pin 2 (GND) of the chip U5 of the external reference power is grounded and at the same time It is connected to one end of capacitor C6, and the other end of capacitor C6 is connected to pin 19 of the processor in the health sensing module; pins 3 (EN) and 4 (IN) of the chip U5 of the external reference power supply are respectively connected to the health sensor. The pin 12 of the processor in the module is connected; the pin 5 (TP) of the chip U5 of the external reference power supply is grounded. When pin 4 of the chip U5 of the external reference power supply receives the instruction information sent by the controller in the health sensing module, pin 1 of the chip U5 of the external reference power supply can instruct the external reference power supply to send to the The controller provides internal power and reference sources.

FIG. 18 is a schematic circuit diagram of an external communication interface in a health sensing module according to some embodiments of the present application. As shown in Figure 18, pins 1, 7, and 8 of the chip J2 of the external communication interface are grounded. Pin 2 (STA) of chip J2 of the external communication interface is connected to pin 26 of the controller in the health sensing module; pin 3 (UTX) of chip J2 of the external communication interface is connected to the controller in the health sensing module pin 23 of the external communication interface chip J2 (URX) is connected to pin 24 of the controller in the health sensing module; pins 2, 3 and 4 of the chip J2 of the external communication interface can be Receive data sent by the controller in the health sensing module, and send the received data to an external device. The pin 5 (RESETn) of the chip J2 of the external communication interface is connected to the pin 32 of the controller in the health sensing module, and is used for receiving a reset instruction sent by the controller in the health sensing module. Pin 6 (RESETn) of the chip J2 of the external communication interface is connected to the power supply. It should be noted that the circuit diagrams of the controller, the external reference power supply, and the external communication interface in the health sensing module provided by the embodiments of the present application do not constitute limitations to the present application, and can be specifically set according to actual scenarios in application.

In addition, it should be understood that the embodiments of the present application do not limit when to supply power to the controller in the health sensing module. In some embodiments, in order to achieve the low power consumption requirement of the health sensing module, after the user touches the touch module, the touch module determines whether the user's touch is valid. If the user's touch duration exceeds the threshold, the touch module may determine that the user's touch is valid, and may instruct to supply power to the controller in the health sensing module. If the user's touch duration does not exceed the threshold, the touch module may determine that the user's touch is invalid, and then does not instruct to supply power to the controller in the health sensing module. It should be understood that this embodiment of the present application also does not limit when the power supply to the controller in the health sensing module is stopped. In some embodiments, power may be stopped to the controller in the health sensing module after the health detection is completed. In some embodiments, if it is detected that the user's finger does not fit the detection module, the power supply to the controller in the health sensing module may also be stopped. In some embodiments, if it is detected that the user stops touching the touch module for a long time during the health detection process, the power supply to the controller in the health sensing module may also be stopped.

On the basis of the above health sensing module, in some embodiments, the controller in the health sensing module can convert the voltage signal into the user's vital signs after collecting the voltage signal corresponding to the light received by the photosensitive component. data. Subsequently, the user's vital sign data can be separated into original data packets and real-time display data packets, and the original data packets and real-time display data packets are sent to the display device. After receiving the original data packet and the real-time display data packet, the display device can display the data in the real-time display data packet, and send the data in the original data packet to the server for further processing and analysis. It should be understood that the original data package stores the collected original user's vital sign data, and the real-time display data package stores the preliminarily processed user's vital sign data.

It should be understood that the embodiments of the present application do not limit how to convert the voltage signal corresponding to the light received by the photosensitive component into the user's vital sign data, which may be determined according to the type of vital sign data to be acquired. For example, the voltage signal can be converted into heartbeat data by a heartbeat analysis algorithm. Exemplarily, if the health sensing module includes red LEDs and infrared LEDs, and the data collection frequency of the controller in the health sensing module is 100 Hz, voltage signals in three states are collected in each collected data period, including: State 1 red LED is on, state 2 infrared LED is on, state 3 red LED and infrared LED are all off. In each data collection period, work in state 1 for 3 seconds, in state 3 for 2 seconds, in state 2 for 3 seconds, in state 3 for 2 seconds, and in each work state, the controller in the health sensing module The voltage signal corresponding to the light received by the photosensitive component will be collected once. Then, through the heartbeat analysis algorithm, the voltage signals collected in every two collected data cycles are processed and synthesized into one heartbeat data point. Subsequently, the heartbeat data point can be stored in the original data packet.

It should be understood that the embodiments of the present application do not limit the preliminary processing of the user's vital sign data. In some embodiments, analysis may be performed according to a certain vital sign data of the user within a period of time to obtain other vital signs related to it. Physical data. Exemplarily, if the original vital sign data of the user is a heartbeat data point, the controller in the health sensing module can generate a heartbeat curve from the heartbeat data points in a sending cycle, and then parse out the heartbeat curve from the heartbeat curve. The user's heart rate value, blood oxygen value, microcirculation value, systolic blood pressure value and diastolic blood pressure value. Finally, the user's heartbeat data, heart rate value, blood oxygen value, microcirculation value, systolic blood pressure value and diastolic blood pressure value are stored in the real-time display data package.

In some embodiments, after the controller in the health sensing module separates the user's vital sign data into real-time display data packets and original data packets, the real-time display data packets and original data packets can be sent to the processing module of the remote control device , the real-time display data packet and the original data packet are sent to the display device by the processing module of the remote control device. In other embodiments, after the controller in the health sensing module separates the user's vital sign data into real-time display data packets and original data packets, the controller in the health sensing module can also directly use an external device connected to the controller in the health sensing module. The communication interface sends real-time display data packets and original data packets to the display device.

In some embodiments, before sending the real-time display data packets and the original data packets, the controller in the health sensing module may further compress the real-time display data packets and the original data packets to improve transmission efficiency. Exemplarily, the vital sign data of the user in the original data packet within 1.28 seconds may be compressed into 168 bytes (byte), and then the original data packet is sent. It should be understood that the embodiment of the present application does not limit the sending period of the real-time display data packet and the original data packet. For example, the sending period may be 1 second, 1.28 seconds, 1.8 seconds, or the like.

In this embodiment of the present application, after receiving the real-time display data packet and the original data packet, the display device may forward the original data packet to the processor for further processing. at the same time. Data in real-time display packets can be displayed. Exemplarily, FIG. 19 is a schematic diagram of a real-time display interface of a display device according to some embodiments of the present application. As shown in FIG. 19 , if the real-time display data packet includes the user's heartbeat data, heart rate value and blood oxygen value. Then, the display device can display the user's heartbeat waveform according to the heartbeat data, and at the same time refresh the user's heart rate value and blood oxygen value on the display interface. In addition, when displaying the real-time display data packets, the display device can also display the time required to collect the remaining vital sign data and count down. At the same time, the display device may also display prompt information on the display interface, for example, prompting the user "detecting, please keep your finger lightly on the detection area".

Subsequently, after receiving the original data packet sent by the display device, the server may analyze and process the original data in the original data packet to obtain a complete health detection result of the user. Then, the server sends the complete health detection result of the user to the display device for display by the display device. The health detection result may be a user's health detection report. Exemplarily, FIGS. 20a-20b are schematic interface diagrams of a display device displaying health detection results according to some embodiments of the present application. As shown in FIG. 20a, the display device can display a user's health detection report, the user's health detection report. The above may include various vital signs of the user, the user's health status, and health advice for the user.

In some embodiments, if the user clicks the "General Inspection Suggestion" button in the health inspection report, the display device may jump from the interface shown in FIG. 20a to the interface shown in FIG. 20b. The interface shown in Figure 20b includes report parsing and health recommendations. Health recommendations can be generated based on user information and health detection results. In this way, health recommendation can use big data to associate users' personal preferences with health information, so that health data collection and health analysis, doctor services, content services, shopping services, etc. can be completed at home through display devices, effectively expanding display devices. scenes to be used.

In some embodiments, the user clicks on each health recommendation card, and the display device will jump to the corresponding application. The embodiments of the present application do not limit how to jump to the corresponding application. Exemplarily, the jumping method of object notation (JavaScript Object Notation, JSON) may be used, and JSON uses a text format that is completely independent of the programming language to store and Representing data, the level is concise and clear, easy for humans to read and write, and easy for machines to parse and generate, effectively improving network transmission efficiency. Specifically, the display device can parse the jump parameters in JSON (a light-weight, interpreted or just-in-time compiled programming language with function priority) according to the jump rules. For example, the display device parses the value corresponding to the package name in JSON to determine the application package name to jump to, and determines the class name to jump to according to the value corresponding to the class name. The type of jump is determined according to the startup type.

In some embodiments, the user can click the "change batch" button, so that the display device reselection randomly selects several health recommendations from the health recommendations issued by the server, and displays them. This embodiment of the present application does not limit how to make random health recommendations. Exemplarily, the random method principle can be used to randomly arrange (shuffel) elements in a collection algorithm (Collections) to shuffle the health recommendations issued by the server, and then select from them. Several health recommendations.

In addition, the embodiments of the present application do not limit the structures of the original data packet and the real-time display data packet. By way of example, an available real-time display data packet format and an original data packet format are provided below. Table 1 is a format of a real-time display data packet according to some embodiments of the present application, and Table 2 is a format of an original data packet according to some embodiments of the present application.

Table 1

Table 2

On the basis of the above embodiments, the following describes the touch module in the remote control device.

Fig. 21a is a schematic circuit diagram of a touch module according to some embodiments of the present application. As shown in Fig. 21a, the touch module includes a processor, a signal input end, a signal output end, and the signal output end and the power supply reset of the health sensing module unit connection. The signal input terminal is used to send a signal to the processor after detecting the user's touch. After the processor receives the signal input from the signal input terminal, it determines whether the user touches effectively. If so, it outputs an instruction to the power supply reset unit through the signal output terminal. signal to instruct the power supply reset unit to supply power to the controller of the health sensing module.

Based on the schematic circuit diagram of the touch module shown in FIG. 21a, a specific circuit diagram of the touch module is exemplarily provided below. FIG. 21 b is a schematic circuit diagram of another touch module according to some embodiments of the present application. As shown in FIG. 21 b , the processor of the touch module is a chip N3 as an example. The pin 1 (VDD) of the chip N3 of the touch module is respectively connected with the power supply VBAT and the first end of the capacitor C28; the pin 2 (VSS) of the chip N3 of the touch module is respectively connected with the second end of the capacitor C28 and grounded; The pin 3 (PA0) of the chip N3 of the touch module is connected to the resistors R11 and R17 respectively, the resistor R11 is connected to the signal output terminal P2_5, and the resistor R11 is connected to the power supply VDD_IO; the pin 4 (PA2) of the chip N3 of the touch module is connected to the resistor R18 is connected, and the resistor R18 is connected to the power supply VDD_IO; the pin 5 (PA6) of the chip N3 of the touch module is connected to the resistor R19, and the resistor R19 is connected to the signal input terminal PA1. Through this structure, the user touches the soft board (such as the FPC line) with his finger, so that the input terminal PA1 sends a signal to the chip N3, and after the chip N3 processes the signal, it sends an instruction to the processing module of the remote control device through the signal output terminal P2_5. Thereby, the processing module of the remote control device is instructed to turn on the power supply of the health module and start the function of the health module.

Based on the touch module shown in FIGS. 21a-21b, the following describes the process of triggering the health detection by the remote control device through the touch module.

In some embodiments, after it is detected that the user's skin contacts the detection area of the remote control device, the remote control device performs fit detection on the contact of the human body. If the fit detection is qualified, the remote control device sends an application startup instruction to the display device, where the application startup instruction is used to instruct the display device to start the health management application. In addition, the remote control device detects and performs health detection, acquires the user's vital sign data, and sends the user's vital sign data to the display device. Finally, the display device displays the user's vital sign data, and sends the user's vital sign data to the server. The server processes the user's vital sign data, generates a health detection report, and sends the health detection report to the display device, and the display device displays the health detection report.

On the basis of the above embodiment, the health detection method specifically includes:

S201. The processing module monitors the trigger signal sent by the touch module, where the trigger signal is triggered after the user's skin contacts the detection area of the remote control device.

In the embodiment of the present application, when the user needs to perform health monitoring, the touch module can cause capacitive sensing of the touch module by touching the detection area on the remote control device, so that the touch module sends a trigger signal to the processing module.

It should be noted that the embodiments of the present application do not limit how the user touches the detection area. In some embodiments, the user may use a finger to touch the detection area, and in other embodiments, the user may use a wrist to touch the detection area.

Two ways to prevent the trigger signal from being triggered by mistake are provided below.

In the first method, the detection area can be set in a concave shape, and a special-shaped design is adopted. As shown in Figure 14, the detection area where the health sensing module is located adopts a special-shaped design, which is different in size and shape from other buttons on the remote control device. At the same time, it can be set to a concave shape. It should be understood that the embodiments of the present application do not limit the types of special-shaped designs. Exemplarily, if the buttons on the remote control device are circular, the detection area can be set to be square; if the buttons on the remote control device are square, the detection area Can be set to a circle.

In this way, due to the special-shaped design, the user can intuitively determine the area of the detection area on the remote control device, and can effectively perform test positioning. At the same time, due to the recessed design, the accidental contact of the user with the detection area can be reduced, thereby reducing the possibility of falsely triggering the trigger signal.

It should be noted that the embodiment of the present application does not limit the depth of the depression in the detection area, which may be specifically set according to the actual situation, for example, the depression may be 0.25 mm.

In the second method, the detection area can be set below the health sensing module, thereby reducing false triggering by the user during the keystroke process.

S202. If the duration of the trigger signal sent by the touch module exceeds the threshold, the processing module sends a start instruction to the health sensing module, where the start instruction is used to instruct the power supply module to start the health sensing module.

In the embodiment of the present application, by determining whether the duration of the trigger signal sent by the touch module exceeds the threshold, it can be determined whether it is a false trigger or no touch; if the duration of the trigger signal sent by the touch module does not exceed the threshold, it can be determined as a false trigger Or no touch, if the duration of the trigger signal sent by the touch module exceeds the threshold, it can be determined that the touch is a valid touch.

It should be noted that the embodiments of the present application do not limit the threshold, for example, 3 seconds, 5 seconds, and the like. Exemplarily, if the threshold may be 3 seconds, the processing module may compare the duration of the trigger signal sent by the touch module with 3 seconds.

S203, the health sensing module performs fit detection on the contact of the human body.

In some embodiments, after the health sensing module is powered on, it is first necessary to perform a fit detection on the contact of the human body, so as to determine whether the contact of the human body completely covers the detection area, or whether there are other items (for example, metal objects) mistakenly detected area. Exemplarily, if the user touches the detection area with a finger, the health sensing module can detect whether the user's finger completely covers the detection area, or whether other objects touch the detection area by mistake. Exemplarily, if the user touches the detection area through the wrist, the health sensing module can detect whether the user's wrist completely covers the detection area, or whether other objects touch the detection area by mistake.

It should be understood that the embodiments of the present application limit how to perform the fitting detection, which may be specifically set according to the actual situation. The examples of this application provide four methods of fitting detection.

In the first way, the health sensing module can turn off all LEDs to detect whether the ambient light is within a preset range.

In the second method, the health sensing module can turn on a specific LED, and set the specific LED as a preset detection brightness, so as to detect whether the light emitted by the specific LED under the detection brightness is within a preset range.

Exemplarily, the red LED can be turned on, and when the output brightness is set to 2 blocks, whether the light emitted by the red LED is within a preset range. Exemplarily, the infrared light LED can be turned on, and when the output brightness is set to 2 blocks, whether the light emitted by the infrared light LED is within a preset range.

In a third manner, it is compared whether the difference between the ambient light and the at least two kinds of LED light is within a preset range.

It should be noted that one of the above methods can be used when performing the fitting detection. When the method is satisfied, it is determined that the user's contact meets the fitting requirements; the above multiple methods can be used at the same time. Make sure that the user's contact meets the fit requirements.

Turns off all LEDs to detect whether the brightness of the ambient light is within a preset range.

S204, the health sensing module sends a first response to the processing module, where the first response includes a fitting detection result.

S205, the processing module judges whether the fitting requirement is met according to the fitting detection result.

If no, go to step S206, if yes, go to step S207.

S206, the processing module sends a shutdown instruction to the health sensing module.

S207: The processing module sends an application startup instruction to the display device, where the application startup instruction is used to instruct the display device to start the health management application.

It should be understood that the embodiments of the present application do not limit when the display device displays the health management application. In some embodiments, after the display device receives the application startup instruction, it may first start the health management application but not display it on the interface of the display device. It is only prepared in the background, and the health management application is displayed only after the subsequent display device stably receives the vital sign data sent by the remote control device. In other embodiments, after receiving the application startup instruction, the display device may immediately start the health management application and display data.

S208. The display device sends a second response to the processing module, where the second response is used to instruct the display device to successfully open the health management application and instruct the remote control device to perform health detection.

S209: The processing module sends an acquisition instruction to the health sensing module, where the acquisition instruction is used to request acquisition of the vital sign data of the user.

S210 , the health sensing module performs health detection, and acquires vital sign data of the user.

It should be noted that, after acquiring the vital sign data of the user, the health sensing module in the embodiment of the present application may also add abnormal information during the health detection process to the vital sign data. This embodiment of the present application does not limit the abnormal information, which may include, for example, information such as the user's finger leaving the detection area.

It should be understood that, in this step, the manner in which the health sensing module performs health detection is the same as that in the foregoing embodiment, and details are not described herein again.

S211. The health sensing module sends the user's vital sign data to the processing module.

S212, the processing module sends the user's vital sign data to the display device. S213. The display device sends a first stop instruction to the processing module, where the first stop instruction is used to instruct to stop performing health detection.

It should be noted that this embodiment of the present application does not limit the display device to send the first stop instruction to the processing module. In some embodiments, after the display device starts the health management application, a fixed detection duration can be set. When the detection duration is reached Afterwards, the display device may send the first stop instruction to the processing module.

S214. The health sensing module sends a third response to the processing module.

This embodiment of the present application does not limit the content of the third response. In some embodiments, the third response may be used to indicate that the health detection is successful. In some embodiments, the third response may be used to indicate that the health check is complete. In some embodiments, this third response may be used to characterize a health check dropout.

S215. The processing module sends a second stop instruction to the health sensing module, where the second stop instruction is used to instruct the health sensing module to stop collecting the user's vital sign data.

S216 , the processing module controls the power supply module to stop supplying power to the health sensing module, and controls the touch module to perform a low-power scan mode.

Compared with the related art, the embodiment of the present application can reduce the false touch of the user for touch detection, and at the same time, the fit detection is performed when the user effectively touches, so that the health sensing module is frequently woken up due to false touches, thereby reducing the number of false touches. The power consumption of the remote control device increases the interval for battery replacement of the remote control device.

On the basis of the above embodiment, the following describes the processing procedure after the health management application is abnormally prompted.

First, two methods for handling abnormal prompts caused by the user removing the detected finger during the health detection process are provided.

In the first solution, after receiving an abnormal prompt caused by the user removing the detected finger, the detection can be continued according to the interval time of the finger being removed. Yet another health detection method of some embodiments of the present application includes:

S401. The display device receives first abnormality prompt information of the remote control device, where the first abnormality prompt information is used to instruct the user to remove the finger from the detection area.

S402. The display device determines the first valid data packet before the user removes the finger from the detection area.

It should be understood that the first valid data packet may include real-time display data packets and original data packets.

S403. The display device determines whether the first valid data packet exceeds a data threshold.

If yes, execute S406, if not, execute S404.

S404. In the first time period after receiving the first abnormal prompt information, display whether the device has received the second valid data packet of the remote control device, and the second valid data packet is the data packet generated by the user moving the finger to the detection area again .

If it is S405, execute it, if not, execute S407.

S405. The display device determines whether the sum of the numbers of the first valid data packets and the second valid data packets exceeds a data threshold.

If yes, execute S406, if not, execute S404.

S406. The display device sends third information to the remote control device, where the third information is used to instruct the remote control device to turn off the infrared data acquisition sensor.

S407, the display device displays an abnormal data interface.

FIG. 22 is a schematic interface diagram of a health management application according to some embodiments of the present application. As shown in FIG. 22 , prompt information may be included in the data abnormality interface, thereby recommending the user to re-check. When the user clicks the "Cancel" button, the home page of the health management application (the page for establishing a health file) can be fed back, and when the user clicks the "Re-check" button, a health check can be performed again.

In the second solution, after receiving an abnormal prompt caused by the user removing the detected finger, the user can move the finger back into the detection area to continue the detection within the total duration of the health detection. Another health detection method applying some embodiments includes:

S501. The display device receives first abnormality prompt information of the remote control device, where the first abnormality prompt information is used to instruct the user to remove the finger from the detection area.

S502. The display device determines the first valid data packet before the user removes the finger from the detection area.

S503. The display device determines whether the first valid data packet exceeds a data threshold.

If yes, execute S506, if not, execute S504.

S504, in the total duration of health detection, whether the display device receives the second effective data packet of the remote control device, the second effective data packet is the data packet that the user moves the finger to the detection area again.

If it is S505, execute it, if not, execute S507.

S505. The display device determines whether the sum of the numbers of the first valid data packets and the second valid data packets exceeds a data threshold.

If yes, execute S506, if not, execute S504.

S506. The display device sends third information to the remote control device, where the third information is used to instruct the remote control device to turn off the infrared data acquisition sensor.

S507, the display device displays an abnormal data interface.

Secondly, the present application provides a processing method for abnormal shutdown of a health management application during a health detection process.

Yet another health detection method of some embodiments of the present application includes:

S601. The display device sends first information to the remote control device every second time period, where the first information is used to instruct the remote control device to turn on the infrared data acquisition sensor.

S602, the remote control device turns on the infrared data acquisition sensor.

S603. If the remote control device has not received the first information in N consecutive second time periods, turn off the infrared data acquisition sensor.

In this way, it can be avoided that the remote control device continues to perform health detection when the health management application is closed abnormally, thereby saving the power of the remote control device.

Thirdly, the present application provides two processing methods after the health check is turned on by mistake due to the user's accidental touch.

In the first method, after the user touches and turns on the health check by mistake, if the user finds out in time, the remote control device can send instruction information to the display device to instruct to exit the health check. After receiving the indication information, the display device can send third information to the remote control device, where the third information is used to instruct the remote control device to turn off the infrared data acquisition sensor. In addition, a shortcut button can also be set on the remote control device to turn off the infrared data acquisition sensor with one click.

In the second method, after the user touches and turns on the health check by mistake, if it is detected that the time when the human body moves away from the detection area exceeds the threshold value, the remote control device can automatically send an indication message to the display device to instruct to exit the health check. Subsequently, the display sends third information to the remote control device, where the third information is used to instruct the remote control device to turn off the infrared data acquisition sensor.

Finally, the present application provides two processing methods for the interruption of data transmission between the remote control device and the display device during the health detection process.

In the first method, if the data transmission between the remote control device and the display device is interrupted during the health detection process, the “data transmission abnormality” prompt can be displayed on the display device, and a timer (for example, 10 seconds) can be performed. When the time exceeds the time threshold and the data transmission is not resumed, the display device prompts the user to perform data detection again.

In the first method, if the data transmission between the remote control device and the display device is interrupted during the health check, the remaining time required to complete the health check can be determined. If the remaining time required to complete the health check is greater than the time threshold, a "data transmission abnormality" prompt can be displayed on the display device, and the user is prompted to perform the health check again. If the remaining time required to complete the health check is less than or equal to the time threshold, the user can be prompted on the display device to continue the health check, and the detected data is temporarily stored in the remote control device, and data transmission between the remote control device and the display device is resumed After that, the temporarily stored data is sent to the display device.

In some embodiments, without the remote control paired with the display device, a specific infrared code is emitted if the remote control detects continued user contact with the touch area. After the display device receives the specific infrared code, it starts the "Health Manager" application, displays the interface of the "Health Manager" application, and displays a pairing prompt, so as to remind the user to operate the display device to pair with the remote control through the pairing prompt. For example, by popping up a Toast prompt on the interface of the "Health Manager" application, the user is reminded to operate pairing.

In other embodiments, the user may also input a preset voice password to input a control instruction for starting the "Health Manager" application. For example, the user uses the near-field voice function or far-field voice function of the display device to speak a preset voice password, such as "health check" or "start health housekeeper", and the display device recognizes the voice password input by the user and determines the corresponding voice password. to start the Health Manager application.

In other embodiments, the user may also operate the display device to display the application center interface, and then start the "Health Manager" application by clicking the application icon of the "Health Manager" application displayed in the application center interface.

It should be noted that, for a terminal device with a built-in health data collection module, such as a display device with a touch area mentioned in the foregoing embodiment, or a portable terminal device supporting a fingerprint recognition function, its health detection function is also based on the installed health. The implementation of the application related to the detection function, such as the above-mentioned "Health Manager" application. In some embodiments, when such a display device or a portable terminal device detects that the user has been in contact with the touch area for a preset time, it will pull up the "Health Manager" application to display the interface of the application. In one example, the display device has a built-in health data collection module and a touch area on the rear case. When the user covers the touch area of the rear case with a finger for 3s, the display device will start the "Health Manager" application, and jump from the current display interface to the interface of the "Health Manager" application. In another example, the user's mobile phone has a built-in health data collection module and has a fingerprint identification area. When the user covers the finger on the fingerprint recognition area for 3s, the mobile phone will start the "Health Manager" application and display the interface of the "Health Manager" application.

In some embodiments, FIG. 23 is a startup page of an application according to some embodiments of the present application. As shown in FIG. 23 , after the “Health Manager” application is successfully started, in some embodiments, the application may be displayed on the startup page Introduction to related functions. In some embodiments, when the display duration of the startup page reaches a predetermined duration, the startup page is cancelled and the application home page is entered. For example, at the beginning of displaying the splash page, a countdown is displayed in the upper left corner of the splash page. When the countdown is over, cancel the startup page and enter the application home page. In some embodiments, after the "Health Manager" application is successfully launched, the user agreement presentation page is first displayed. For example, in the case that the "Health Manager" application is successfully launched for the first time, the user agreement display page is displayed first. The user agreement display page can display the application usage agreement or regulations, such as disclaimers. The user can agree or reject the displayed agreement content by operating the relevant controls on the user agreement display page. If the user inputs an operation of agreeing to the content of the agreement, the display device revokes the user agreement display page, and enters the startup page or directly enters the application home page. If the user inputs an operation of rejecting the content of the agreement, the display device closes the "Health Manager" application, cancels the user agreement display page, and returns to the interface before launching the "Health Manager" application.

FIG. 24 is a user agreement display page of an application according to some embodiments of the present application. As shown in FIG. 24 , the user agreement display page includes a protocol content display area and a control display area, and the protocol content display area is used to display the application usage agreement Or the specified content, the control display area is used to display user-operable controls, such as "agree" control and "reject" control. The user can select and confirm the "Agree" control to input the operation of agreeing to the content of the agreement, and can select and confirm the "Cancel" control to input the operation of rejecting the content of the agreement.

In other embodiments, the display device may display the user agreement display area on the upper layer of the startup page, and display the user agreement content and related controls in the user agreement display area, thereby simultaneously displaying the startup page and the user agreement content.

FIG. 25 is an application homepage of an application according to some embodiments of the present application. The application homepage is mainly used to guide a user to perform health detection or establish a health file in a tourist mode. As shown in FIG. 25 , the home page of the application includes a control “Start Creation” for triggering the establishment of a health profile and a control “Experience now” for triggering immediate health detection in tourist mode. When the home page of the application is displayed, the user can enter the profile information input interface by operating the "Start Creation" control, enter the user's characteristic information in the profile information input interface, and can also enter the health check instruction in the profile management interface to instruct the display device to Designate the user to perform health detection Alternatively, the user may input a health detection instruction by operating the "experience immediately" control to instruct the display device to immediately perform health detection on it.

FIG. 26 is a profile information input interface according to some embodiments of the present application, which may specifically be an interface entered by a user after operating the "start creation" control in the homepage of the application. As shown in FIG. 26 , the file information input interface includes a plurality of input items, such as avatar, nickname, gender, age, height, and weight. Users can upload avatar files, create user nicknames, and select gender, age, height and weight in this interface. After the input is completed, you can instruct the display device to save the entered user feature information by operating the "Confirm" control, and enter the file management interface, or operate the "Cancel" control to return to the application home page.

FIG. 27 is a file management interface according to some embodiments of the present application, which may specifically be an interface entered by a user after operating the "confirm" control in the file information input interface. As shown in Figure 27, the file management interface displays the created file cards, each file card corresponds to a set of operation controls, which are the control "immediate physical examination" used to trigger the health check and the control used to view the previous health check results. "Medical report". The user can select the control on the corresponding file card to operate according to the detection object to input the health detection instruction. For example, when it is necessary to perform a health check on "grandma", operate the "immediate physical examination" control on the file card of "grandmother". In addition, a tourist card is also displayed in the file management interface, so the user can operate the "immediate physical examination" control on the tourist card to input a health inspection instruction for testing in tourist mode. In addition, the file management interface also displays a control "Add member +" for creating new member file information. When the user operates this control, he will re-enter the file information input interface, and the user can enter new members in the file information input interface. file information.

FIG. 28 is a schematic diagram of an interaction process between a display device and a remote control according to some embodiments of the present application. Referring to FIG. 28 , in some embodiments, when the display device receives an input health detection instruction, an operation guidance interface is displayed, and an operation instruction interface is displayed to the remote control at the same time. The controller sends data collection instructions to instruct the remote control to start collecting user health data.

FIG. 29 is an operation guidance interface according to some embodiments of the present application. As shown in FIG. 29 , operation guidance information is displayed on the operation guidance interface. The health data collection module can successfully collect user health data.

In some embodiments, the remote controller starts the health data collection module after receiving the data collection instruction sent by the display device. After the health data collection module is successfully started, the remote control sends a notification message indicating that the health data collection module is started successfully to the display device. As shown in FIG. 28 , in a specific implementation, the remote controller responds to the received data collection instruction and communicates through the serial port to turn on the switch of the health data collection module. After the switch of the health data collection module is turned on, the health data collection module notifies the remote control through serial communication. Furthermore, the remote controller can determine whether the health data collection module is successfully started according to whether the notification of the health data collection module is received. When it is determined that the health data collection module is successfully started, a notification message indicating that the health data collection module is started successfully is sent to the display device. After the display device sends the data collection instruction to the remote controller, the timing operation is performed. If a notification message indicating that the health data collection module is successfully started is received within a preset time period, a detection interface is displayed, and the detection interface is used to display the detection progress and/or real-time user health data. If the notification message indicating the successful startup of the health data collection module is not received within the preset time period, a fault prompt will be displayed on the operation guidance interface.

In other embodiments, after receiving the data collection instruction sent by the display device, the remote control starts the health data collection 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 is in contact with the touch area, and it is determined that the health data collection module is successfully activated, the remote control sends a notification message to the display device indicating the start of data collection. After the display device sends the data collection instruction to the remote controller, it performs a timing operation to record the waiting time. If the notification message sent by the remote controller indicating the start of data collection is received within the preset waiting time (that is, before the waiting time reaches the preset waiting time), a detection interface is displayed, which is used to display the detection progress and/or the real-time user health data. If the notification message sent by the remote control to start collecting data is not received within the preset waiting time, a timeout prompt will be displayed on the operation guidance interface.

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

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

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

It can be seen from the above embodiments that based on the interactive control and cooperation between the remote control and the display device, the user can start the health detection function of the display device through a simple operation, and collect the user's health data, so that the user can perform health detection anytime, anywhere, Strong experience.

It should be noted that, for a terminal device with a built-in health data collection module, the terminal device controller turns on the switch of the health data collection module through the serial port in response to the health detection instruction input by the user. After the health data collection module is successfully opened, it will notify the terminal device controller through the serial port, and the terminal device controller will control to display the operation guidance interface on the screen. When the terminal device controller detects the user's contact within the preset waiting time period, a detection interface is displayed, and at this time, the health data collection module starts to collect user health data. During the data collection process, the health data collection module transmits the collected user health data to the terminal device controller. After the data collection is completed, the terminal device controller sends the collected user health data to the server, so as to analyze the user health data through the server, and return the health detection result to the terminal device.

In some embodiments, in order to ensure the user experience of the health detection process and save the user's time, the time for collecting data can be pre-limited, that is, the remote control is limited to complete the collection and transmission of the user's health data within the predetermined time, and the display device is limited to The user's health data is received within the preset receiving time.

In some embodiments, when the display device receives a notification message sent by the remote controller and instructs to start collecting data, a timing operation is performed to record the duration of data reception. In some embodiments, the timing operation for recording the data reception duration is referred to as the second timing operation.

During the data collection process, the remote control encapsulates the user health data collected by the health data collection module into data packets in real time and sends them to the display device until the collection is completed. For the convenience of distinction and description, this application refers to a data packet encapsulating the user's health data as a health data packet.

In some embodiments, after the display device receives the health detection result and the set of recommendation information returned by the server, the display device enters the detection result interface from the detection interface, and displays the health detection result and at least one recommended content collectively on the detection result interface. Exemplarily, the health test result may be displayed in the first content area of the test result interface, and the display information of at least one recommended information, ie the title, picture, etc. of the recommended content, may be displayed in the second content area of the test 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 selected from the recommended information set is displayed in each tab respectively. Exemplarily, a preset number of tabs may be displayed in the second content area, and a preset number of recommended contents randomly selected from the recommendation information set may be displayed in each of the tabs respectively.

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

FIG. 30 is a detection result interface according to some embodiments of the present application. As shown in Figure 30, the first content area on the upper side of the test result interface displays the specific content of the health test result, including the user's heart rate variability index, an introduction to the concept of heart rate variability, a description of the user's symptoms, and the cause of the symptoms. , and user suggestions. There are four recommended content tabs displayed in the second content area on the lower side of the test result interface, and their titles are "Healthy Fat-Reducing Meal", "AI Fitness", "Cardiovascular Recipe", and "Health Class". Users can click on any of the tabs to view recommended content under that heading.

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, respectively, which will not be described in detail in this application.

In some embodiments, the recommendation information includes a priority identifier of the recommended content, and the priority identifier of each recommended content is determined by the server according to a content tag of the recommended content or a user interest degree corresponding to the content source, the content tag The corresponding user interest degree is determined according to the user's click behavior on the content with the content tag, and the user interest degree corresponding to the content source is determined according to the user's usage of the content source. When the detection result interface is displayed, a preset number of tabs are displayed in the second content area, and a preset number of recommended contents with the highest priority in the recommended information set are displayed in each of the tabs respectively.

In some embodiments, a control for updating the 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 can instruct the display device to replace the currently displayed recommended content by operating the control. In response to the confirmation operation of the control, the display device displays a preset number of the recommended contents with the highest priority among the remaining recommended contents on each tab, wherein the remaining recommended contents refer to those not displayed in the recommended contents set. recommended content.

FIG. 31 is another detection result interface according to some embodiments of the present application, which is specifically an interface displayed after the user operates the “change batch” control in the interface shown in FIG. 30 . Different from FIG. 30 , in FIG. 31 , the recommended contents displayed in the second content area on the lower side of the detection result interface are: "Yoga", "Keep", "Healthy and Light", and "Fitness Suit".

It is worth noting that, in the above embodiment, each tab in the detection result interface can acquire focus, and the user can move the focus position by operating the control device to select any tab. When the focus falls on a tab, the user can enter a confirmation operation to open the corresponding recommended content. Based on this, when the display device receives the selection operation of the target recommended content input by the user, it obtains the jump parameters corresponding to the target recommended content; starts the target jump application according to the jump parameters, and displays the target jump interface.

Specifically, the jump parameters include a target jump application identifier and a target jump page identifier. The target jump application identifier may specifically be an application package name, which is used to enable the display device to determine the target jump application. The target jump page identifier is specifically Can be a class name, which is used to make the display device determine the target jump page. In addition, the jump parameter can also include the jump type.

Exemplarily, when the user opens the "AI fitness" tab in Fig. 30, the interface shown in Fig. 20 jumps to the application home page of the "AI fitness" application.

It can be seen from the above embodiments that the technical solution provided by this application not only provides users with health detection results, but also pushes appropriate recommended content for users according to their personalized health detection results, user interests and user characteristics, enriching the user experience. Interface content to meet the potential needs of users and improve user experience.

Some embodiments of the present application provide a display device, including: a display; a controller, where the controller is connected to the display, and the controller is configured to: receive real-time display data packets and original data packets sent by a remote control device, The real-time display data package includes the user's vital sign data, the real-time display data package is used to draw the vital sign curve, and the original data package is used to generate the user's health report; drawing according to the real-time display data package The user's vital sign curve; the user's vital sign curve is displayed on the user interface of the display device, and the original data packet is sent to the server. For details, please refer to the above introduction.

Some embodiments of the present application provide a server, including: a memory; a controller, where the controller is connected to a processor connected to the memory, the controller is configured to: receive an original data packet sent by a display device, the original The data package includes the original vital sign data of the user collected by the control device; the user's health detection report is generated according to the original data package; and the user's health detection report is sent to the display device. For details, please refer to the above introduction.

Some embodiments of the present application provide a health detection method, including: receiving a light value reflected by the capillaries of the user sent by the health sensing module; and determining the life of the user according to the light value reflected by the capillaries of the user vital sign data; sending the user's vital sign data to a display device. For details, please refer to the above introduction.

For the convenience of explanation, the above description has been made in conjunction with specific embodiments. However, the above discussion in some embodiments is not intended to be exhaustive or to limit implementations to the specific forms disclosed above. Numerous modifications and variations are possible in light of the above teachings. The above embodiments have been chosen and described to better explain the principles and practical applications, so as to enable those skilled in the art to better utilize the embodiments and various modified embodiments suitable for specific use considerations.

Claims

An electronic device, comprising: a touch module, a health sensing module and a processing module;

the processing module is respectively connected with the touch module and the health sensing module;

The touch module sends a touch signal to the processing module when detecting a user's touch;

After receiving the touch signal, the processing module sends a turn-on signal to the health sensing module according to the touch signal;

After receiving the turn-on signal, the health sensing module collects the illumination value reflected by the capillaries of the user, and sends the illumination value reflected by the capillaries of the user to the processing module;

The processing module generates the vital sign data of the user according to the light value reflected by the capillaries of the user.
The electronic device according to claim 1, wherein the health sensing module comprises: a power switching circuit and a light collection circuit;

The power switching circuit is respectively connected with the processing module and the illumination collection circuit;

After receiving the turn-on signal, the power switching circuit supplies power to the illumination collection circuit, so that the illumination collection circuit collects the illumination value reflected by the capillaries of the user.
The electronic device of claim 2, the power switching circuit comprising a first processor;

the first pin of the first processor is connected to the processing module;

After receiving the turn-on signal through the first pin of the first processor, the first processor outputs a switching signal through the second pin of the first processor, and the switching signal is used to The power switching circuit is switched to a first power supply line, and the first power supply line is used to supply power to the light collection circuit.
The electronic device according to claim 3, wherein a diode is provided in the first power supply circuit for isolating and protecting the light collection circuit.
The electronic device according to claim 2, wherein the light collection circuit comprises: a second processor, a light-emitting component and a photosensitive component;

The first pin and the second pin of the second processor are connected to the light-emitting component, and form an electrical circuit with the light-emitting component, so that the light-emitting component illuminates the capillaries of the user;

The third pin and the fourth pin of the second processor are connected to the photosensitive component, and form an electrical circuit with the photosensitive component; the photosensitive component transmits the light signal reflected by the capillaries of the user Converting into electrical energy, forming a voltage signal, and sending the voltage signal to the second processor through the third pin and the fourth pin of the second processor, the voltage signal is used to characterize the user The light value reflected by the capillaries.
The electronic device according to claim 5, wherein the photosensitive component comprises a photosensitive cell and a conversion resistor;

The photosensitive cell and the conversion resistor are connected in parallel with the first pin and the second pin of the second processor, respectively.
The electronic device according to claim 5, the illumination collection circuit further comprising: a sampling control circuit;

The sampling control circuit is respectively connected with the light-emitting component and the processing module, and the sampling control circuit is used for sending the current value of the light-emitting component to the processing module; when the current value of the light-emitting component is less than When the threshold value is reached, the switch component in the sampling control unit is turned on under the control of the processing module to amplify the working voltage of the light-emitting component.
The electronic device according to claim 7, wherein the sampling control circuit further comprises a sampling resistor, and the switch component comprises a field effect transistor;

The gate of the field effect transistor is connected to the processing module, and is used for receiving the turn-on signal sent by the processing module;

The drain of the field effect transistor is connected to the light emitting component, and is used for amplifying the working voltage of the light emitting component after the field effect transistor is turned on;

The source of the field effect transistor is connected to one end of the sampling resistor, and the other end of the sampling resistor is grounded.
The electronic device according to claim 1, wherein the touch module comprises a third processor, a signal output terminal, a signal input terminal and a touch soft board;

The first pin of the third processor is connected to the signal input end, and the signal input end is connected to the touch soft board, and the touch soft board passes the signal input end to the touch board after detecting the user's contact. the processor sends an input signal;

The second pin of the third processor is connected to the signal output end, and the signal output end is connected to the processing module. After receiving the input signal, the third processor passes the signal The output terminal sends a touch signal to the processing module.
The electronic device according to claim 9, wherein the touch module further comprises a first capacitor;

The first end of the first capacitor is connected to the third pin of the third processor, the second end of the first capacitor is connected to the fourth pin of the third processor, and the third The third pin of the processor is connected to the power supply, and the fourth pin of the third processor is grounded;

The power supply of the electronic device supplies power to the third processor through the third pin of the third processor.
A display device, comprising:

display screen;

remote control equipment;

a controller, configured to receive the first instruction information sent by the remote control device, open health application software, and present a user interface corresponding to the health application software on the display screen;

Receive the user's vital sign data collected by the remote control device, and draw a curve corresponding to the user's vital sign data on the user interface corresponding to the health application software.
The display device of claim 11, wherein the controller is further configured to:

The second instruction information sent by the remote control device is received, and a health detection report is presented on the user interface corresponding to the health application software; wherein the second instruction information is used to indicate the end of the detection period.
The display device according to claim 12, wherein the controller is further configured to: receive the user's vital sign data collected by the remote control device:

The user's vital sign data is divided into a first part and a second part, the first part is used to draw a curve corresponding to the user's vital sign data, and the second part is used to generate a health detection report.
The display device according to claim 12, wherein the controller is further configured to: receive the user's vital sign data collected by the remote control device:

uploading the user's vital sign data to the server;

After receiving the second instruction information, download the health detection report from the server.
A health detection method comprising:

When the touch module generates a touch signal, the health sensing module is controlled to perform fit detection on the user's touch.
The method according to claim 15, wherein the controlling the health sensing module to perform fit detection on the user's touch, comprising:

acquiring the light value and ambient light value reflected by the capillary blood vessels of the user collected by the health sensing module;

According to the light value reflected by the capillaries of the user and the ambient light value, the touch detection of the user is performed;

If it is detected that the user's touch fits, a first feedback signal is sent to the health sensing module, where the first feedback signal is used to instruct the health sensing module to continue the health detection.
A control device comprising:

a health sensing module, used for illuminating the capillaries of the user, and collecting the illumination value reflected by the capillaries of the user;

a controller, the controller is connected to the health sensing module, the controller is configured to:

receiving the light value reflected by the capillaries of the user sent by the health sensing module;

determining the vital sign data of the user according to the light value reflected by the capillaries of the user, where the vital sign data includes a real-time display data packet and an original data packet;

sending the real-time display data package to a display device, where the real-time display data package is used to draw a vital sign curve and display it on a user interface of the display device;

Sending the original data packet to the server, where the original data packet is used to generate a health report for the user.