CN115191975A - Integrated identity input control device applied to sphygmomanometer and use method - Google Patents

Abstract

The invention relates to an integrated identity input control device applied to a sphygmomanometer and a use method thereof, wherein the control device is fixedly connected with the sphygmomanometer, and a user can control the sphygmomanometer to complete the collection of blood pressure data through the control device; the control device comprises a processor, and an identity recognition module, an indication module, a blood pressure measurement module, a data processing module and a communication module which are respectively connected with the processor. The technical scheme of this application can accomplish unmanned on duty's blood pressure measurement, can let the patient measure the blood pressure by oneself to realize the automatic upload of data. The white overcoat effect is avoided on the basis of meeting the standard measurement process, more accurate blood pressure value is obtained, and meanwhile, the infection of medical care personnel can be effectively avoided under the epidemic situation condition. In addition, the health risks of the shelter personnel can be screened in time, the medical human resource consumption is reduced, and the high-efficiency operation of the shelter is realized by the minimum personnel investment.

Description

Integrated identity input control device applied to sphygmomanometer and use method

Technical Field

The application relates to the technical field of blood pressure measurement, in particular to an integrated identity input control device applied to a sphygmomanometer and a using method.

Background

The blood pressure measuring device in the prior art needs the cooperation of medical personnel to carry out the measurement of blood pressure to the patient, makes medical personnel expose under the risk of infection easily, further reduces medical personnel's that can work quantity.

Therefore, there is a need for a fully automatic sphygmomanometer control device that can complete blood pressure data collection without the need for medical personnel to operate.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide an integrated identity input control device which can be independently used by a patient for acquiring blood pressure data and is applied to a sphygmomanometer and a using method thereof.

In order to achieve the above object, the present invention has the following configurations:

an integrated identity input control device applied to a sphygmomanometer is characterized in that a control device is fixedly connected with the sphygmomanometer, and a user can control the sphygmomanometer to collect blood pressure data through the control device;

the control device comprises a processor, and an identity recognition module, an indication module, a blood pressure measurement module, a data processing module and a communication module which are respectively connected with the processor;

the identity recognition module is used for recognizing the identity of the user;

the indicating module is used for guiding a user to operate the control device to measure the blood pressure;

the blood pressure measuring module receives the operation of a user and controls the sphygmomanometer to measure the blood pressure of the user and acquire measured blood pressure data;

the data processing module establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data;

the communication module is connected with the cloud end and can transmit data.

In the preferred controlling means, the identity identification module can confirm user's identity through medical insurance card, ID card, hospital's bracelet two-dimensional code.

In the preferred control device, the data processing module integrates and processes the historical blood pressure data collected by the control device, generates a data report and transmits the data report to the cloud through the communication module; the data processing module can update the data report according to the blood pressure data collected in real time.

In a preferred control device, each of the blood pressure meters is provided with a different feature code for identifying the blood pressure meter, and the user information, the blood pressure meter feature code, and the blood pressure data of the user establish a mapping relationship to generate a mapping table.

In a preferred control device, the control device is fixedly connected with a sphygmomanometer in a detachable mode, and when the control device connected with the sphygmomanometer is replaced, the communication module acquires a mapping table corresponding to the characteristic code of the sphygmomanometer from a cloud end; and updating the mapping table stored in the replaced control device through the blood pressure data acquired by the sphygmomanometer in real time.

In a preferred control device, the control device further comprises a motion recognition module, and the user recognizes and judges whether the blood pressure measurement posture of the user is standard or not, and corrects the measurement posture of the user through the indication module.

The application also comprises a using method of the integrated identity input control device applied to the sphygmomanometer, wherein the control device is fixedly connected with the sphygmomanometer, and a user controls the sphygmomanometer to complete the acquisition of blood pressure data through the control device;

the using method comprises the following steps:

s1, the control device identifies the identity of a user and matches or records user information;

s2, the control device guides a user to operate the control device to measure the blood pressure;

s3, the control device receives the operation of the user and controls the sphygmomanometer to measure the blood pressure of the user and obtain measured blood pressure data;

s4, the control device establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data;

and S5, the control device is connected with the cloud end and transmits the processed data to the cloud end.

In a preferred use method of the control device, the step S1 is specifically that the control device identifies the user identity and matches or records the user information through a medical insurance card, an identification card, and a hospital bracelet two-dimensional code;

in the use method of the preferred control device, the control device integrates and processes the collected historical blood pressure data, generates a data report and transmits the data report to the cloud; the control device can update the data report according to the blood pressure data collected in real time.

In a preferred method for using the control device, each sphygmomanometer is configured with different feature codes for distinguishing and marking the sphygmomanometer, and the user information, the sphygmomanometer feature codes and the blood pressure data of a user establish a mapping relation to generate a mapping table;

the control device is detachably and fixedly connected with the sphygmomanometer, and when the control device connected with the sphygmomanometer is replaced, the control device acquires a mapping table corresponding to the feature code of the sphygmomanometer from the cloud; and updating the mapping table through the blood pressure data acquired by the sphygmomanometer in real time.

The application relates to an integrated identity input control device applied to a sphygmomanometer and a using method thereof, wherein the control device is fixedly connected with the sphygmomanometer, and a user can control the sphygmomanometer to complete the collection of blood pressure data through the control device; the control device comprises a processor, and an identity identification module, an indication module, a blood pressure measurement module, a data processing module and a communication module which are respectively connected with the processor; the identity recognition module is used for recognizing the identity of the user; the indicating module is used for guiding a user to operate the control device to measure the blood pressure; the blood pressure measuring module receives the blood pressure of the user and controls the blood pressure meter to measure the blood pressure of the user after the user operates the blood pressure measuring module, and measured blood pressure data are obtained; the data processing module establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data; the communication module is connected with the cloud end and can transmit data. The technical scheme of this application can accomplish unmanned on duty's blood pressure measurement, can let the patient measure the blood pressure by oneself to realize the automatic upload of data. The white overcoat effect is avoided on the basis of meeting the standard measurement process, more accurate blood pressure value is obtained, and meanwhile, the infection of medical care personnel can be effectively avoided under the epidemic situation condition. In addition, the health risks of shelter personnel can be screened in time, the medical human resource consumption is reduced, and the high-efficiency operation of the shelter is realized by the minimum personnel investment.

Drawings

FIG. 1 is a schematic block diagram of a preferred control device of the present application;

FIG. 2 is a schematic diagram of a preferred product structure of the control device of the present application;

FIG. 3 is a diagram of the indicating effect of the indicating device of the present application;

FIG. 4 is a schematic structural view of a shelter system for use with the present application;

fig. 5 is a step diagram of a method for using the control device of the present application.

Detailed Description

The technical solutions in the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings, and it is to be understood that the described embodiments are only some embodiments of the present disclosure, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the disclosed embodiments without making any creative effort, also belong to the protection scope of the present invention.

The application relates to an integrated identity input control device applied to a sphygmomanometer, wherein the control device is fixedly connected with the sphygmomanometer, and a user can control the sphygmomanometer to complete the collection of blood pressure data through the control device;

as shown in fig. 1, the control device includes a processor, and an identification module, an indication module, a blood pressure measurement module, a data processing module and a communication module respectively connected to the processor;

the identity recognition module is used for recognizing the identity of the user; the indicating module is used for guiding a user to operate the control device to measure the blood pressure; the blood pressure measuring module receives the blood pressure of the user and controls the blood pressure meter to measure the blood pressure of the user after the user operates the blood pressure measuring module, and measured blood pressure data are obtained; the data processing module establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data; the communication module is connected with the cloud end and can transmit data.

The control device is fixedly connected with the sphygmomanometer and is simultaneously arranged on a specially-made workbench, the fixed connection is only fixedly connected on the position and also comprises communication fixation, and one control device correspondingly controls one sphygmomanometer.

This application discern user's identity through identification module, as shown in fig. 2, identification module including be used for the response and read the induction type card reading area of ID card and social security card to and the user scans the code area of sweeping of hospital's bracelet, sweep the two-dimensional code on the code area scans the hospital's bracelet through the last setting of controlling means and accomplish identification. When the hospital bracelet gets into the shelter for the patient, shelter management system disposes distinctive sign bracelet for every patient, every bracelet has all corresponded the patient information of matching. Preferably, the control device of the present application also has direct or indirect access to the shelter management system.

The technical scheme of this application can accomplish unmanned on duty's blood pressure measurement, can let the patient measure the blood pressure by oneself to realize the automatic upload of data. The white overcoat effect is avoided on the basis of meeting the standard measurement process, more accurate blood pressure value is obtained, and meanwhile, the infection of medical care personnel can be effectively avoided under the epidemic situation condition. In addition, the health risks of the shelter personnel can be screened in time, the medical human resource consumption is reduced, and the high-efficiency operation of the shelter is realized by the minimum personnel investment.

The method comprises the steps of identifying the identity of a user through an identity identification device, acquiring user information, searching whether a storage module in a control device contains a mapping table of the user information, if not, establishing the mapping table with the user information as a search label, and if so, reading the mapping table corresponding to the user information for subsequent processing for standby.

After the identification of the user is completed, the user starts to measure the blood pressure, the indication module guides the user to operate the control device to measure the blood pressure, the indication module comprises a display device, as shown in fig. 3, the display device indicates the user to perform standard actions using the sphygmomanometer, such as inserting the upper arm into the wall of the cylinder, horizontally transferring the body, and straightening the chest and the back. After the user requires fixing the posture according to the indication of the indication module, the indication module sends a measurement starting instruction to the processor, and the processor sends the instruction to the blood pressure measurement module.

The indicating module of this application of preferred still includes the operation instruction, through show the hand arrow on display device to the cooperation is with special effect action, guides the user to click specific button and accomplishes the measurement of blood pressure. Preferably, the directional information of the user displayed on the indication module is displayed in a desensitized manner, so that the privacy of the user is protected.

The blood pressure measuring module starts to control the sphygmomanometer to measure the blood pressure of the user and acquire measured blood pressure data, the control comprises the steps of sending an instruction for starting the test to the sphygmomanometer, starting to measure the blood pressure after the sphygmomanometer acquires the instruction, and returning the blood pressure data to the control device after the measurement is finished.

Preferably, the sphygmomanometer of the present application performs blood pressure measurement by adopting an oscillometric method, and specific parameters of the control device equipped with the sphygmomanometer of the present application are shown in table one;

watch 1

And the data processing module acquires the measured blood pressure data, establishes a mapping relation between the blood pressure data and the user information, and adds the blood pressure data into a mapping table.

Preferably, the information in the mapping table includes user information, blood pressure data, and measurement time and measurement times corresponding to the blood pressure data.

The data processing module can also process the mapping table or the blood pressure data, and the processing process is carried out in the control device and does not need to be carried out by other processing systems after the data are transmitted to the cloud.

The data processing module establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data; the communication module is connected with the cloud end and can transmit data. The data processing module integrates data to form a data report, and sends the data report to the cloud, and the data report can be used for carrying out standardized processing on the blood pressure data by using a preset template or algorithm. The processed data report can comprise a blood pressure data information data table of each user, a display graph of the blood pressure data of the user in the cabin, a blood pressure measurement frequency report corresponding to the control device and the like.

In a preferred embodiment, the data processing module may update the data report based on blood pressure data collected in real time. Specifically, collected blood pressure data including blood pressure values, measurement times, measurement time and the like are integrated into a mapping table corresponding to user information, and the data report is updated through a data processing module.

Preferably, the data processing module can also judge whether the blood pressure data of the user is in a normal range according to the user information, and if the blood pressure of the user is too high or too low, the blood pressure data is directly subjected to a warning sign, and the blood pressure data and the corresponding user information are sent to a nurse station or a shelter commanding room.

Preferably, as shown in fig. 4, the communication module is connected to the cloud server for data transmission. In the project plan of the shelter, the shelter total commanding room and a plurality of nurse stations are included. The control device of this application can be connected with high in the clouds server through doctor letter SaaS platform, high in the clouds server pass through doctor letter SaaS platform and nurse station and shelter and always command the room and be connected. In other preferred embodiments, the cloud server may be further connected to the mobile terminal of the patient and a remote hospital outside the cabin.

The user information comprises a mobile terminal number of the user, the user information is stored in the cloud server after the blood pressure data is collected, and the user can check the own blood pressure data of the user after the blood pressure data is verified by the mobile terminal. Preferably, the extravehicular remote hospital which obtains the authority can also access the cloud server to check the blood pressure data. The cloud server can also directly send the abnormal data to a remote hospital outside the cabin.

In other preferred embodiments, the control device of the present application is applied in the form of a PAD and connected to a sphygmomanometer, as shown in figure 4. The control device is called as a smart blood pressure PAD, the smart blood pressure PAD is connected with a cloud server through a medical SaaS platform, and the smart blood pressure PAD comprises a shelter middle terminal (a nurse station and a command room), a hospital department outside the shelter, a community activity room, a basic medical structure, a secondary medical structure, a tertiary medical structure and the like which can be accessed to the cloud server, so that data sharing in a medical system is realized. After identifying the user information, the control device can acquire historical blood pressure data or other medical information of the user through a medical SaaS platform, and is used for integrating the data and generating a data report. The cloud server can be further connected with terminals outside a medical system, information intercommunication of whole society is achieved, and the cloud server can be connected with airports, business computers, offices and the like, and can be connected with personal terminals.

According to the method and the system, the blood pressure data are stored in the cloud server through the medical information SaaS platform and are connected with the personal terminal, the hospital end, the shelter end and other social terminals, and the intercommunication and sharing of the measurement data and the social and family ends can be realized.

Preferably, the data report and each blood pressure data can be transmitted to a cloud server for storage.

In a preferred embodiment, the shelter hospital is generally divided into a plurality of sectors, with different types of infected persons being assigned to specific sectors, for example, sectors assigned for the elderly, the young, or for the basic illness, the non-basic illness. By collecting and monitoring blood pressure of infected persons with different characteristics, a data analysis report with the collective characteristics of the patients is generated. Therefore, in this embodiment, it is necessary to integrate the blood pressure data of a specific area into the same control device for data processing.

In the configuration of the control device and the matched sphygmomanometer, generally, one control device and one matched sphygmomanometer are used for every 200 persons, and each sphygmomanometer is configured with different feature codes for distinguishing and marking the sphygmomanometer. Preferably, the mapping relation is established among the user information, the feature code of the sphygmomanometer and the blood pressure data of the user to generate the mapping table. Because sphygmomanometer and its supporting workstation are fixed to be set up in the district, because the patient in this district all can go to use this sphygmomanometer, establish corresponding relation with sphygmomanometer and district patient, more can effectual collection, whole have the specific collective blood pressure data of characteristic of patient.

In a preferred control device, the control device is fixedly connected with a sphygmomanometer in a detachable mode, and when the control device connected with the sphygmomanometer is replaced, the communication module acquires a mapping table corresponding to the characteristic code of the sphygmomanometer from a cloud end; namely, the blood pressure data measured by the sphygmomanometer and the related data report are transmitted to the control device, and the original storage content of the control device is covered. In the subsequent measurement, the blood pressure data collected by the sphygmomanometer are transmitted to the newly installed control device, and the collected blood pressure data are processed and integrated by the control device.

In a preferred embodiment, a plurality of blood pressure meters in the same area of the shelter can share one blood pressure meter feature code, and the mapping table corresponding to the blood pressure meter feature code is also shared by the control devices assembled by the blood pressure meters with the same feature code. According to the technical scheme, the fault tolerance rate of the patient is increased, when the control device and the sphygmomanometer are arranged densely, and a user uses a wrong sphygmomanometer to measure, the blood pressure data with specific collective characteristics can be obtained.

Preferably, when the user who does not belong to the area measures the blood pressure, the control device directly sends the measurement data to the corresponding control device through the cloud, and the control device integrates and processes the blood pressure data.

Preferably, to implement the above technical solution, the user information in the mapping table further includes a specific collective feature tag, so as to determine whether the user belongs to a user range of measurement and data integration of the control device.

In a preferred control device, the control device further comprises a motion recognition module, and the motion recognition module is used in cooperation with the indication module. The user identifies and judges whether the blood pressure measurement posture of the user is standard or not, and corrects the measurement posture of the user through the indicating module.

The preferred action recognition module of this application includes the camera, the camera can carry out video and record also can carry out the shooting of photo, after the user accomplished authentication, the camera was opened, carries out video and records. The control device of the application adopts the OpenPose algorithm to detect key points of a human body on the recorded video, and the OpenPose algorithm detects joint positions of the head, the neck and the shoulders of the human body as key point marks. Each keypoint is represented in the image in pixel coordinates (x, y). The main skeleton of the human body can be constructed through the key points. The main pipe framework is used for indicating the sitting posture height of a user, and when the blood pressure is measured, the user needs to straighten the body and level the heart position with the arm measuring point as much as possible.

The method and the device can be used for deducing whether the user sits straight or not by constructing the shoulder and head frameworks and setting a certain threshold distance on the basis of the shoulder line. When the shoulder height of the user is detected to be lower than the set value, the indicating module prompts the user to straighten the sitting posture, and when the shoulder height of the user is detected to be higher than the set value, the indicating module indicates the user to lower the sitting posture.

Preferably, the above detection method requires performing coordinate flattening operation on the above coordinates, taking key points of two shoulders as standard coordinate points, and establishing a plane parallel to a plane perpendicular to the direct viewing direction of the camera and passing through the standard coordinate points as a base plane. And all key points are converted to the plane to complete the plane construction of the human skeleton.

Preferably, after the height indication adjustment of the sitting posture is completed, the body needs to be inclined laterally as shown in fig. 3. This application adopts fixed aperture value and fuzzy edge to judge and detects user's position of sitting, and the camera of this application is when detecting horizontal slope position of sitting, and is fixed as big aperture with the camera, and the picture of shooing from this produces the depth of field difference. The depth of field is expressed as the pictures farther from the focus are blurred and the pictures closer to the focus are sharper. Preferably, the standard coordinate points can be selected as a focus to obtain the fuzziness of the edges of the human body pictures at two sides, and the edge fuzziness graph is judged by constructing the tortuosity of edge lines with fixed pixel degrees. The ambiguity is a step-shaped line generated when the edge is selected by using a range line of a fixed pixel, and the ambiguity is judged by calculating the difference between the step and an estimated symmetric line thereof. When the sum of the two-side tortuosity belongs to the threshold value range, the user is judged to have finished the inclined sitting posture. When the sum of the two-sided tortuosity is less than the threshold range, the user is instructed to perform a lateral tilt. When the sum of the two-sided tortuosity is greater than the threshold range, the user is instructed to go back to a positive gesture.

The height of the human body is detected through the OpenPose algorithm, the user is instructed to adopt a proper sitting posture, and the user is instructed to adjust the transverse inclination of the body by matching depth of field with fuzzy judgment. The user can complete the measurement of the blood pressure in a proper posture to obtain more accurate blood pressure data. And the posture judgment scheme only needs to use one camera, so that the test is accurate and the cost is low.

The application also comprises a using method of the integrated identity input control device applied to the sphygmomanometer, wherein the control device is fixedly connected with the sphygmomanometer, and a user controls the sphygmomanometer to complete the acquisition of blood pressure data through the control device;

as shown in fig. 5, the using method comprises the following steps:

s1, the control device identifies the identity of a user and matches or records user information;

s2, the control device guides a user to operate the control device to measure the blood pressure;

s3, the control device receives the operation of the user and controls the sphygmomanometer to measure the blood pressure of the user and obtain measured blood pressure data;

s4, the control device establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data;

and S5, the control device is connected with the cloud end and transmits the processed data to the cloud end.

In a preferred use method of the control device, the step S1 is specifically that the control device identifies the user identity and matches or records the user information through a medical insurance card, an identification card, and a hospital bracelet two-dimensional code;

in the use method of the preferred control device, the control device integrates and processes the collected historical blood pressure data, generates a data report and transmits the data report to the cloud; the control device can update the data report according to the blood pressure data collected in real time.

In a preferred method for using the control device, each sphygmomanometer is configured with different feature codes for distinguishing and marking the sphygmomanometer, and the user information, the sphygmomanometer feature codes and the blood pressure data of a user establish a mapping relation to generate a mapping table;

the control device is detachably and fixedly connected with the sphygmomanometer, and when the control device connected with the sphygmomanometer is replaced, the control device acquires a mapping table corresponding to the feature code of the sphygmomanometer from the cloud; and updating the mapping table through the blood pressure data acquired by the sphygmomanometer in real time.

As used in this application and the appended claims, the terms "comprises" and "comprising" are generally intended to cover only the explicitly recited steps or elements as not constituting an exclusive list and that the method or apparatus may include other steps or elements.

The components, relative arrangements, functions, and numerical values set forth in these embodiments do not limit the scope of the present invention unless specifically stated otherwise. Also, it is apparent that the dimensions of the various parts shown in the drawings are not drawn to scale in practice for ease of description. Techniques, methods and apparatus that are known to those of ordinary skill in the relevant art have not been described in detail for the time being, but are intended to be part of the specification as appropriate. In all examples shown and discussed herein, any particular value should be construed as exemplary only and not as a limitation. Thus, other examples of step-wise embodiments may have a different order of precedence.

The foregoing is illustrative of the present invention and is not to be construed as limiting thereof. Although a few exemplary embodiments of the present invention have been described, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to be included within the scope of this invention as defined in the claims. It is to be understood that the foregoing is illustrative of the present invention and is not to be construed as limited to the specific embodiments disclosed, and that modifications to the disclosed embodiments, as well as other embodiments, are intended to be included within the scope of the appended claims. The invention is defined by the claims and their equivalents.

Claims (10)

1. An integrated identity input control device applied to a sphygmomanometer is characterized in that the control device is fixedly connected with the sphygmomanometer, and a user can control the sphygmomanometer to complete the collection of blood pressure data through the control device;

the control device comprises a processor, and an identity identification module, an indication module, a blood pressure measurement module, a data processing module and a communication module which are respectively connected with the processor;

the identity recognition module is used for recognizing the identity of the user;

the indicating module is used for guiding a user to operate the control device to measure the blood pressure;

the blood pressure measuring module receives the operation of a user and controls the sphygmomanometer to measure the blood pressure of the user and acquire measured blood pressure data;

the data processing module establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data;

the communication module is connected with the cloud end and can perform bidirectional data transmission.

2. The control device of claim 1, wherein the identity recognition module can confirm the identity of the user through a medical insurance card, an identity card and a hospital bracelet two-dimensional code.

3. The control device of claim 1, wherein the data processing module integrates and processes historical blood pressure data collected by the control device, generates a data report and transmits the data report to a cloud through the communication module; the data processing module can update the data report according to the blood pressure data collected in real time.

4. The control device according to claim 1, wherein each of the blood pressure meters is configured with a different feature code for distinguishing the blood pressure meter from another, and the user information, the blood pressure meter feature code, and the blood pressure data of the user are mapped to create a mapping table.

5. The control device of claim 4, wherein the control device is detachably and fixedly connected with the sphygmomanometer, and when the control device connected with the sphygmomanometer is replaced, the communication module obtains the mapping table corresponding to the feature code of the sphygmomanometer from a cloud end; and updating the mapping table through the blood pressure data acquired by the sphygmomanometer in real time.

6. The control device of claim 1, further comprising a motion recognition module, wherein the user recognizes and determines whether the measurement posture of the blood pressure of the user meets the measurement standard, and corrects the measurement posture of the user through the indication module.

7. The use method of the integrated identity input control device applied to the sphygmomanometer is characterized in that the control device is fixedly connected with the sphygmomanometer, and a user controls the sphygmomanometer to complete the collection of blood pressure data through the control device;

the using method comprises the following steps:

s1, the control device identifies the identity of a user and matches or records user information;

s2, the control device guides a user to operate the control device to measure the blood pressure;

s3, the control device receives the operation of the user and controls the sphygmomanometer to measure the blood pressure of the user and obtain measured blood pressure data;

s4, the control device establishes a mapping relation between the user information and the blood pressure data of the user and processes the blood pressure data;

and S5, the control device is connected with the cloud end and transmits the processed data to the cloud end.

8. The use method of the control device according to claim 7, wherein the step S1 is to identify the user identity and match or record the user information through a medical insurance card, an identity card, and a hospital bracelet two-dimensional code.

9. The method of using the control device as claimed in claim 7, wherein the control device integrates and processes the collected historical blood pressure data, generates a data report and transmits the data report to the cloud; the control device can update the data report according to the blood pressure data collected in real time.

10. The method of claim 7, wherein each of said sphygmomanometers is configured with a different feature code for identifying the sphygmomanometers, and said user information, the sphygmomanometer feature code, and the user's blood pressure data are mapped to create a mapping table;

the control device is detachably and fixedly connected with the sphygmomanometer, and when the control device connected with the sphygmomanometer is replaced, the control device acquires a mapping table corresponding to the feature code of the sphygmomanometer from the cloud; and updating the mapping table through the blood pressure data acquired by the sphygmomanometer in real time.

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