CN108209894B - Embedded health detection method and device and self-service health detection all-in-one machine - Google Patents

Abstract

The invention is suitable for the medical electronic field, has provided a health detection method, apparatus and self-service health detection all-in-one machine based on embedded type, said method is carried out and included on the basis of the embedded system: identifying whether a person approaches or leaves through infrared detection, waking up the system when the person approaches, and controlling the system to sleep when the person leaves; after the system is awakened, identity authentication is carried out; receiving a control instruction of the upper computer after the identity authentication is legal, wherein the control instruction comprises blood pressure detection, blood oxygen detection and electrocardiogram detection; starting a power supply of a corresponding functional module according to the control instruction, wherein the functional module comprises a blood pressure detection functional module, a blood oxygen detection functional module and an electrocardio detection functional module; and the control function module executes the detection task and uploads the detection data to the upper computer. The invention adopts an embedded system to carry out health detection, realizes the integration of various detection functions, greatly improves the user experience, can realize self-service detection of users and is beneficial to the promotion of the national health management.

Description

Embedded health detection method and device and self-service health detection all-in-one machine

Technical Field

The invention belongs to the field of medical electronics, and particularly relates to an embedded health detection method and device and a self-service health detection all-in-one machine.

Background

With the more and more attention of people on chronic diseases in life, people need to pay more attention to their health conditions in life, timely know related disease information and prevent disease deterioration, timely know disease characteristics and analyze disease data by using a scientific method, manage, judge and analyze the data to achieve and inquire the recent physical index condition of an individual, achieve the purpose of knowing advance prevention in advance, and avoid unnecessary troubles brought by disease deterioration.

However, most of the existing medical detection instruments are single-function, and the power consumption is large due to the execution of software, so that a large power supply needs to be configured, the size is large, and the integration of multiple detection functions is not facilitated. If a user needs to perform disease detection of multiple functions simultaneously, the user needs to continuously change detection positions and the user experience is poor; or in the prior art, the devices with each function can be connected through the peripheral interface, however, the devices cannot be operated in one system through the peripheral connection, the self-service operation of a user cannot be realized, and the device cannot be applied to basic medical places such as community health management centers and the like which urgently need self-service health detection, and is not beneficial to the promotion of the national health management.

Disclosure of Invention

The embodiment of the invention aims to provide an embedded health detection method, and aims to solve the problem that the prior art cannot integrate a plurality of detection functions and realize self-service health detection.

The embodiment of the invention is realized in such a way that an embedded health detection method is executed based on an embedded system, and comprises the following steps:

identifying whether a person approaches or leaves through infrared detection, waking up the system when the person approaches, and controlling the system to sleep when the person leaves;

after the system is awakened, identity authentication is carried out;

receiving a control instruction of an upper computer after the identity authentication is legal, wherein the control instruction comprises blood pressure detection, blood oxygen detection and electrocardiogram detection;

starting a power supply of a corresponding functional module according to the control instruction, wherein the functional module comprises a blood pressure detection functional module, a blood oxygen detection functional module and an electrocardio detection functional module;

and controlling the functional module to execute a detection task and uploading detection data to an upper computer.

Another objective of an embodiment of the present invention is to provide an embedded health detection device, which includes:

the infrared identification unit is used for identifying whether a person approaches or leaves through infrared detection, waking up the system when the person approaches, and controlling the system to sleep when the person leaves;

the identity authentication unit is used for performing identity authentication after the system is awakened;

the receiving unit is used for receiving a control instruction of the upper computer after the identity authentication is legal, wherein the control instruction comprises blood pressure detection, blood oxygen detection and electrocardiogram detection;

the function starting unit is used for starting a power supply of a function module according to the control instruction, and the function module comprises a blood pressure detection function module, a blood oxygen detection function module and an electrocardio detection function module;

and the detection control unit is used for controlling the functional module to execute a detection task and uploading detection data to the upper computer.

Another objective of the embodiments of the present invention is to provide a self-service health detection all-in-one machine, which includes a plurality of detection probes for performing blood pressure detection, blood oxygen detection and electrocardiographic detection on a user, a power supply, an input unit, a display unit, an audio output unit, an illumination unit, and the embedded health detection device.

The embodiment of the invention adopts the embedded system to execute the steps, and the embedded system has low power consumption, so that a battery with small capacity can meet the embedded power consumption requirement, the equipment has small volume, thereby effectively integrating various detection functions, leading a user to complete various detections by one piece of equipment, greatly improving the user experience, and the embedded system can quickly respond to external events, has strong specificity, good real-time performance and high reliability, reduces the operation difficulty, and leads the user not to need the guidance of professional personnel, thereby realizing the self-service detection of the user.

Drawings

Fig. 1 is a flowchart of an embedded health detection method according to an embodiment of the present invention;

fig. 2 is a flowchart of step S102 in the embedded health detection method according to the embodiment of the present invention;

fig. 3 is a flowchart of step S105 in the embedded health detection method according to the embodiment of the present invention;

FIG. 4 is a block diagram of an embedded health detection device according to an embodiment of the present invention

FIG. 5 is a preferred block diagram of an embedded health detection device according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. In addition, the technical features involved in the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

The embodiment of the invention adopts the embedded system for health detection, has low power consumption, is beneficial to integration, thereby realizing integration of various detection functions, greatly improving user experience, realizing self-service detection of users, being widely applicable to basic medical places such as community health management centers and the like which urgently need self-service health detection, and being beneficial to promotion of national health management.

Fig. 1 shows a flow structure of an embedded health detection method according to a first embodiment of the present invention, and for convenience of description, only the relevant parts of the present invention are shown.

As an embodiment of the present invention, the embedded health detection method is executed based on an embedded system, and includes the following steps:

s101, identifying whether a person approaches or leaves through infrared detection, waking up a system when the person approaches, and controlling the system to sleep when the person leaves;

further, after the infrared detection identifies that a person approaches, a power supply and a display interface of the lighting lamp are started; after the infrared detection identifies that a person leaves, the power supply and the display interface of the illuminating lamp are turned off, and the brightness of the illuminating lamp can be adjusted through the light ray control module.

In the embodiment of the invention, human body information is detected through infrared detection, if a person comes, the power supply of the illuminating lamp at the top of the control equipment is turned on, the display interface is controlled to be lightened, and the welcome detection mark or operation prompt is displayed through the display interface. And when the user is detected to leave, the power supply and the display interface of the equipment illuminating lamp are turned off, and the user enters a sleep state.

Of course, if the system fails, the display can be used for displaying.

Step S102, identity authentication is carried out after the system is awakened;

step S103, receiving a control instruction of the upper computer after the identity authentication is legal, wherein the control instruction comprises blood pressure detection, blood oxygen detection and electrocardiogram detection;

step S104, starting a power supply of a corresponding functional module according to the control instruction, wherein the functional module comprises a blood pressure detection functional module, a blood oxygen detection functional module and an electrocardio detection functional module;

and step S105, controlling the functional module to execute a detection task and uploading detection data to an upper computer.

Specifically, with reference to fig. 2, the step of step S102 includes:

step S201, prompting a user to input identity information, wherein the identity information comprises at least one of identity card information, social security card information and registered account information;

step S202, verifying whether the identity information is legal or not, and outputting a verification result;

if yes, executing step S203 to prompt checking and save user information;

if not, executing step S204, quitting the verification, and returning to the step of prompting the user to input the identity information.

Further, the user can be prompted to input identity information through the display interface and/or the voice unit, and the verification result can be output through the display interface and/or the voice unit.

In the embodiment of the invention, the verification identity information can be verified by inserting a card or inputting a registered account number and a password, the user is prompted to insert the card (an identity card or a social security card) when the system has no fault, when the user inserts the identity card, the system judges the legality of the identity information of the user, if the identity information of the user is illegal, the user can be prompted to 'invalid card' by voice, meanwhile, the 'invalid card' can be displayed by animation and/or characters, a magnetic card is popped up to prompt to fetch the card and return to a card reading interface, and if the identity information of the user is illegal for three times, the card is popped up to prompt to fetch the. If the user information is legal, the user can modify the user information and store the correct user information if the user information is incorrect.

It should be noted that, here, the prompt may be separately prompted by voice, may be separately prompted by display, and may also be prompted by voice and display at the same time.

If the user identity information is legal and the user information is correct, entering a main interface, displaying the main interface to enter a test or inquiring information, and connecting to a related website to provide services such as expert online consultation and the like.

For steps S103 and S104, the control instruction of the upper computer includes but is not limited to blood pressure detection, blood oxygen detection, and electrocardiographic detection, and may further include height detection, body temperature detection, weight detection, body composition detection, and the like, and the corresponding functional modules may also include a height detection functional module, a body temperature detection functional module, a weight detection functional module, a body composition detection functional module, and the like. The system and the upper computer are communicated through an RS232 interface, and after the system is started, each module is reset for self-checking. And the system selects and starts the power supply of the corresponding functional module according to the control instruction and executes the corresponding function. The two detection functions can be performed after one detection function is performed, so that the measurement is convenient for a user.

Specifically, in conjunction with fig. 3, the step of step S105 includes:

step S301, prompting a user to place a part to be detected at a corresponding detection position;

step S302, detecting the part to be detected to generate detection data;

step S303, verifying whether the detection data is accurate;

if not, returning to execute the step S302;

if yes, go to step S304 to ask the user whether to need to re-measure;

if yes, returning to execute the step S302;

if not, executing step S305, saving the detection data, and uploading the detection data to the upper computer.

In the embodiment of the invention, taking height detection as an example for explanation, when a control command of the height detection sent by an upper computer is received, a power supply of a height detection function module is turned on, success or failure is returned to the upper computer, the height detection function module starts detection, whether the height detection is to be carried out is selected through a 'confirm/skip' option of an input part, if the 'confirm' is clicked, a single chip microcomputer controls corresponding measuring equipment to work after receiving the command, the upper computer prompts 'please stand at a position marked on a floor', the equipment (system) uploads measuring data to the upper computer in real time, and a display interface displays the detecting data.

After the measurement is finished, the correctness of the detected data needs to be judged, the specific method can be realized by acquiring data processing in a certain time period, firstly rejecting data with large errors, then taking an average value, and then comparing the average value with an empirical value, so as to judge the correctness of the measured data, wherein the data processing can be realized by upper computer software.

If the detected data is correct, the user may question the accuracy of the data, so the display interface displays yes/no retest, if the user selects retest, the step of entering height measurement determination is clicked, the height detection is executed, if the user selects no retest, the detected data is stored and uploaded to the upper computer, and the upper computer can also count and evaluate various detected data, such as high-risk and normal detection.

At this point, the next measurement function may continue to be performed and the display interface displays "go to weight measurement determination/skip" to continue weight detection. If the measurement results are not correct, prompting the user that the measured data is wrong and please remeasure/skip, and remeasurement returns to the interface to click to enter height measurement determination, and then the steps are sequentially carried out.

When a control command of weight detection sent by an upper computer is received, a power supply of a weight detection functional module is turned on, success or failure is returned to the upper computer, the weight detection functional module starts detection, the upper computer prompts 'please stand at a position marked on a floor, the body is kept upright, and data are stable', a device (system) uploads measurement data to the upper computer in real time, a display interface displays the detection data, after judgment of correctness of the detection data is carried out, if a user selects no retesting, the detection data are stored and uploaded to the upper computer, and then the next measurement is continued, and if the retesting data are abnormal for three times, the user is prompted to 'fail' the height measurement device, and please skip the measurement.

Similarly, when a control command of the electrocardio detection sent by the upper computer is received, the power supply of the electrocardio detection function module is turned on, success or failure is returned to the upper computer, the electrocardio detection function module starts to detect, click ' determination of entering of electrocardio measurement ' is confirmed ', the upper computer prompts ' please hold the handles tightly by the hands, good contact between the hands and the electrode plates is ensured, 40S is kept ', the screen 40S counts down, the equipment uploads the data to the upper computer, the upper computer displays the detection data in real time, the data correctness is judged by the upper computer after the measurement is completed, the user freely selects to re-measure, and if the measurement is not performed again, the next project measurement is entered.

For blood oxygen detection, when a control command of sending the blood oxygen detection by the upper computer is received, the power supply of the blood oxygen detection functional module is turned on, and success or failure is returned to the upper computer. The host computer voice prompt 'please press the fingers' and the screen counts down for 5s, and no detection then prompts: please clip the finger and count down; and starting measurement after detecting that the finger clamps are placed, uploading data to an upper computer in real time by the equipment, displaying the measured data in real time by the upper computer, finishing measurement and judging the correctness of the data. And (3) the data is incorrect, the upper computer prompts that whether measurement is wrong or not is retested, if so, the step enters the step of blood oxygen measurement, then the step is sequentially carried out, if not, the step enters other project tests, and if the data is correct, the measurement data is stored.

For body temperature detection, when a control command that the upper computer sends body temperature detection is received, the power supply of the body temperature detection functional module is turned on, and success or failure is returned to the upper computer. The upper computer voice prompts 'please sit right in front of the screen until the data is stable', the body temperature detection functional module starts to detect the body temperature, the upper computer displays the measurement data in real time, the data correctness is judged after the measurement is finished, and if the user chooses not to repeat the measurement, the detection data is stored and uploaded to the upper computer to continue to enter the next measurement.

The embodiment of the invention can also carry out fat measurement, when a control instruction of fat detection sent by the upper computer is received, the human body composition measurement is clicked, the upper computer prompts' please hold the handles tightly by both hands, the contact between both hands and electrode plates is ensured to be good, the control panel uploads real-time acquired impedance data to the upper computer, the time schedule is displayed on the screen of the upper computer, the data correctness is judged by the upper computer after the measurement is finished, the user freely selects to re-measure, and if the user selects not to re-measure, the detection data is stored and uploaded to the upper computer, and then the next measurement is continued.

The embodiment of the invention adopts the embedded system to execute the steps, and the embedded system has low power consumption, so that a battery with small capacity can meet the embedded power consumption requirement, the equipment has small volume, thereby effectively integrating various detection functions, leading a user to complete various detections by one piece of equipment, greatly improving the user experience, and the embedded system can quickly respond to external events, has strong specificity, good real-time performance and high reliability, reduces the operation difficulty, and leads the user not to need the guidance of professional personnel, thereby realizing the self-service detection of the user.

Fig. 4 shows a structure of an embedded health detection device provided by an embodiment of the present invention, and for convenience of explanation, only the parts related to the present invention are shown.

As an embodiment of the present invention, the embedded health detection apparatus includes:

the infrared identification unit 11 is used for identifying whether a person approaches or leaves through infrared detection, waking up the system when the person approaches, and controlling the system to sleep when the person leaves;

an identity authentication unit 12, configured to perform identity authentication after waking up the system;

the receiving unit 13 is used for receiving a control instruction of the upper computer after the identity authentication is legal, wherein the control instruction comprises blood pressure detection, blood oxygen detection and electrocardiogram detection;

the function starting unit 14 is used for starting a power supply of a function module according to the control instruction, and the function module comprises a blood pressure detection function module, a blood oxygen detection function module and an electrocardio detection function module;

and the detection control unit 15 is used for controlling the functional module to execute a detection task and uploading detection data to the upper computer.

Further, the embedded health detection device can also comprise a lighting lamp power supply and a display interface;

the lighting lamp power supply and the display interface are turned on after the infrared detection identifies that a person approaches, and turned off after the infrared detection identifies that the person leaves.

Fig. 5 shows a preferred structure of the embedded health detection device provided by the embodiment of the present invention, and for convenience of illustration, only the parts related to the present invention are shown.

As a preferred embodiment of the present invention, the authentication unit 12 includes:

the information input prompting module 121 is configured to prompt a user to input identity information, where the identity information includes at least one of identity card information, social security card information, and registered account information;

and the identity authentication module 122 is used for verifying whether the identity information is legal or not, outputting an authentication result, prompting to check and store the user information when the identity information is legal, quitting the authentication when the identity information is illegal, and returning to the step of prompting the user to input the identity information.

Further, the detection control unit 15 includes:

the detection prompting module 151 is used for prompting a user to place the part to be detected at the corresponding detection position;

a detection module 152, configured to detect a to-be-detected portion and generate detection data;

the data verification module 153 is used for verifying whether the detected data is accurate, returning to the detection module for re-detection if the detected data is not accurate, inquiring whether the user needs to re-measure if the detected data is accurate, and returning to the detection module for re-detection if the user needs to re-measure;

and the storage module 154 is used for storing the detection data when the user does not need to measure again and uploading the detection data to the upper computer.

In the embodiment of the present invention, the embedded health detection device is a corresponding device based on the embedded health detection method, and the working principle and the method thereof are partially the same, and are not described in detail here.

The embodiment of the invention adopts the embedded system to execute the steps, and the embedded system has low power consumption, so that a battery with small capacity can meet the embedded power consumption requirement, the equipment has small volume, thereby effectively integrating various detection functions, leading a user to complete various detections by one piece of equipment, greatly improving the user experience, and the embedded system can quickly respond to external events, has strong specificity, good real-time performance and high reliability, reduces the operation difficulty, and leads the user not to need the guidance of professional personnel, thereby realizing the self-service detection of the user.

Another objective of the embodiments of the present invention is to provide a self-service health detection all-in-one machine, which includes a plurality of detection probes for performing blood pressure detection, blood oxygen detection and electrocardiographic detection on a user, a power supply, an input unit, a display unit, an audio output unit, an illumination unit, and an embedded health detection device in any of the above embodiments.

In the embodiment of the invention, the power supply can adopt an external input 12V/5V two-way power supply, and the power supply of other peripheral equipment is managed by centralized distribution of the control board, for example, the control board supplies power to an external DC12V fan.

Certainly, the self-service health detection all-in-one machine can also comprise an expansion interface, and a user expands some additional functions to realize more comprehensive health detection service.

The embodiment of the invention adopts the embedded system to execute the steps, and the embedded system has low power consumption, so that a battery with small capacity can meet the embedded power consumption requirement, the equipment has small volume, thereby effectively integrating various detection functions, leading a user to complete various detections by one piece of equipment, greatly improving the user experience, and the embedded system can quickly respond to external events, has strong specificity, good real-time performance and high reliability, reduces the operation difficulty, and leads the user not to need the guidance of professional personnel, thereby realizing the self-service detection of the user.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. An embedded health detection method is characterized in that the method is executed based on an embedded system and comprises the following steps:

identifying whether a person approaches or leaves through infrared detection, waking up a system when the person approaches, starting an illuminating lamp power supply and a display interface, controlling the system to sleep when the person leaves, and turning off the illuminating lamp power supply and the display interface;

after the system is awakened, identity authentication is carried out;

receiving a control instruction of an upper computer after the identity authentication is legal, wherein the control instruction comprises blood pressure detection, blood oxygen detection and electrocardiogram detection;

starting a power supply of a corresponding functional module according to the control instruction, wherein the functional module comprises a blood pressure detection functional module, a blood oxygen detection functional module and an electrocardio detection functional module;

the method comprises the steps that a functional module is controlled to execute a detection task, detection data are uploaded to an upper computer, wherein the correctness of the detection data needs to be judged after the measurement is finished, specifically, the upper computer extracts data with obvious errors by collecting data processing in a certain time period, then an average value is compared with an empirical value to judge the correctness of the detection data, if the detection data are correct, a display interface displays and inquires a user whether to retest, and retest is carried out or uploading data are stored based on a user selection result;

the method comprises the following steps of controlling the functional module to execute a detection task and uploading detection data to an upper computer, wherein the steps of controlling the functional module to execute the detection task and uploading the detection data to the upper computer specifically comprise the following steps: prompting a user to place the part to be detected at the corresponding detection position;

detecting the part to be detected to generate detection data;

verifying whether the detection data is accurate;

if not, returning to the step of executing the detection of the part to be detected and generating detection data;

if yes, inquiring whether the user needs to measure again;

if so, returning to the step of executing the detection of the part to be detected and generating detection data;

if not, the detection data are stored and uploaded to an upper computer.

2. The method of claim 1, wherein the power supply and display interface of the illumination lamp are turned on after the infrared detection identifies the presence of a person;

and after the infrared detection identifies that the person leaves, the power supply of the lighting lamp and the display interface are turned off.

3. The method according to claim 1, wherein the step of authenticating is specifically:

prompting a user to input identity information, wherein the identity information comprises at least one of identity card information, social security card information and registered account information;

verifying whether the identity information is legal or not, and outputting a verification result;

if yes, prompting to check and store user information;

if not, quitting the verification and returning to the step of prompting the user to input the identity information.

4. The method of claim 3, wherein the user is prompted to input the identity information through a display interface and/or a voice unit, and the verification result is output through the display interface and/or the voice unit.

5. An embedded health detection device, the device comprising:

the infrared identification unit is used for identifying whether a person approaches or leaves through infrared detection, waking up the system when the person approaches, starting a lighting lamp power supply and a display interface, controlling the system to sleep when the person leaves, and turning off the lighting lamp power supply and the display interface;

the identity authentication unit is used for performing identity authentication after the system is awakened;

the receiving unit is used for receiving a control instruction of the upper computer after the identity authentication is legal, wherein the control instruction comprises blood pressure detection, blood oxygen detection and electrocardiogram detection;

the function starting unit is used for starting a power supply of a function module according to the control instruction, and the function module comprises a blood pressure detection function module, a blood oxygen detection function module and an electrocardio detection function module;

the detection control unit is used for controlling the functional module to execute a detection task and uploading detection data to the upper computer, wherein the correctness of the detection data needs to be judged after the measurement is finished, specifically, the upper computer extracts data with obvious errors by collecting data processing in a certain time period, then an average value is taken to be compared with an empirical value to judge the correctness of the detection data, if the detection data is correct, the display interface displays and inquires whether a user retests the data, and retest or save the uploaded data based on a user selection result;

wherein the detection control unit includes:

the detection prompting module is used for prompting a user to place the part to be detected at the corresponding detection position;

the detection module is used for detecting the part to be detected and generating detection data;

the data verification module is used for verifying whether the detection data are accurate or not, returning to the detection module for re-detection if the detection data are not accurate, inquiring whether the user needs to re-measure if the detection data are accurate, and returning to the detection module for re-detection if the user needs to re-measure;

and the storage module is used for storing the detection data when the user does not need to measure again and uploading the detection data to the upper computer.

6. The apparatus of claim 5, further comprising an illumination lamp power supply and a display interface;

the lighting lamp power supply and the display interface are turned on after the infrared detection identifies that a person approaches, and are turned off after the infrared detection identifies that the person leaves.

7. The apparatus of claim 5, wherein the identity verification unit comprises:

the information input prompting module is used for prompting a user to input identity information, and the identity information comprises at least one of identity card information, social security card information and registered account information;

and the identity authentication module is used for verifying whether the identity information is legal or not, outputting an authentication result, prompting to check and store the user information when the identity information is legal, quitting the authentication when the identity information is illegal, and returning to the step of prompting the user to input the identity information.

8. A self-service health detection all-in-one machine is characterized by comprising a plurality of detection probes for carrying out blood pressure detection, blood oxygen detection and electrocardio detection on a user, and further comprising a power supply, an input part, a display part, an audio output part, an illumination part and the embedded health detection device according to any one of claims 5 to 7.

Images