CN113598740A - Display control method and device for sphygmomanometer - Google Patents

Abstract

The invention discloses a display control method and a display control device for a sphygmomanometer, wherein the display control method comprises the following steps: step S1, setting a monitoring account number for the target object; step S2, setting a blood pressure display mode according to the blood pressure characteristics of the target object; and step S3, displaying the blood pressure monitoring result to the target object according to the blood pressure display mode selected by the target object. The invention sets a unique monitoring account for each target object, binds and stores the blood pressure measurement data of each time to the corresponding monitoring account, can avoid the confusion of the data of the target objects caused by the cross use of the sphygmomanometer, ensures the orderliness of the data, can simultaneously carry out the characteristic analysis of the blood pressure trend by utilizing the blood pressure measurement data recorded accumulatively, respectively obtains the current blood pressure trend, the whole blood pressure trend and the abnormal blood pressure trend of the target user, is beneficial to the target user to know the own blood pressure trend, and carries out work and rest adjustment through the blood pressure trend so as to maintain the health of the own blood pressure.

Description

Display control method and device for sphygmomanometer

Technical Field

The invention relates to the technical field of blood pressure display, in particular to a display control method and device of a sphygmomanometer.

Background

The main principle of the sphygmomanometer is a process of measuring the blood flow pressure during a period when the pressure is applied by pressurizing air to press a local artery and the pulsation of the local artery is stopped. The measurement principle of the sphygmomanometer can be divided into an auscultation method and an oscillography method.

The auscultatory method is also called Korotkoff sound method, and is also classified into artificial Korotkoff sound method and electronic Korotkoff sound method. The artificial Korotkoff sound method is a method which is commonly seen by doctors and nurses and is used for measuring blood pressure by using a pressure gauge and a stethoscope; the electronic Korotkoff's sound rule is a Korotkoff's sound measuring method using electronic technology to replace doctors and nurses. The principle is that a cuff is wound around the upper arm, and the pressure of the cuff acts on the brachial artery. The cuff air is adjusted to change the pressure and the sound of the pulsation is heard by the stethoscope, so as to obtain the systolic pressure and the diastolic pressure. The oscillography, also called the oscillation method, is a relatively advanced electronic measuring method developed in the 90 s of the 20 th century, and the principle thereof is that the inflation quantity of a cuff wound on an upper arm is automatically adjusted, the pressure is changed, blood flow has certain oscillation waves through blood vessels, the blood flow is received by a pressure sensor and is gradually deflated, the pressure and the fluctuation detected by the pressure sensor are changed along with the change of the oscillation waves, the moment with the maximum fluctuation is selected as a reference point, on the basis of the reference point, the fluctuation point with a certain value is searched forward to be the systolic pressure, the fluctuation point with a certain value is searched backward to be the diastolic pressure, and the value is set differently by different manufacturers. The diastolic pressure and the systolic pressure are quantized into digital forms to be displayed to a user, so that the user can know the condition of the blood pressure.

In the prior art, most of the currently used blood pressure meters are general blood pressure meters which can be used by all people, but the functions are simple and similar. If an individual user is a sphygmomanometer, the individual user's blood pressure and heart rate may be recorded. If a plurality of users do not know who the blood pressure and heart rate are recorded, and the blood pressure and heart rate data are only stored and displayed once, the trend of the blood pressure and heart rate of each user is difficult to analyze and obtain.

Disclosure of Invention

The invention aims to provide a display control method and a display control device for a sphygmomanometer, which aim to solve the technical problem that blood pressure and heart rhythm data are only stored and displayed once in the prior art, and the trend of the blood pressure and the heart rhythm of each user is difficult to analyze and obtain.

In order to solve the technical problems, the invention specifically provides the following technical scheme:

a digital display control method for blood pressure meters comprises the following steps:

step S1, setting a monitoring account for the target object, and binding the blood pressure measurement data of each time into the monitoring account according to the measurement time sequence to be used as a blood pressure monitoring data chain;

step S2, respectively extracting blood pressure characteristics representing the blood pressure trend of the target object from a blood pressure monitoring data chain, and setting a blood pressure display mode according to the blood pressure characteristics of the target object;

and step S3, displaying the blood pressure monitoring result to the target object according to the blood pressure display mode selected by the target object.

As a preferable scheme of the present invention, the target object uniquely corresponds to the monitoring account.

As a preferred embodiment of the present invention, in step S2, a specific method for extracting blood pressure features representing a blood pressure trend of the target object in the blood pressure monitoring data chain includes:

step S201, extracting blood pressure measurement data corresponding to the maximum time sequence from the blood pressure monitoring data chain, wherein the blood pressure measurement data corresponding to the maximum time sequence is characterized by the current blood pressure characteristic of the current blood pressure trend of the target object;

step S202, extracting blood pressure measurement data corresponding to all time sequences from the blood pressure monitoring data chain, wherein the blood pressure measurement data corresponding to all time sequences are characterized by the integral blood pressure characteristics of the integral blood pressure trend of the target object;

and S203, performing similarity analysis on the blood pressure measurement data corresponding to all the time sequences to obtain blood pressure measurement data corresponding to abnormal time sequences, wherein the blood pressure measurement data corresponding to the abnormal time sequences represent blood pressure abnormal characteristics of the abnormal trend of the blood pressure of the target object.

As a preferable embodiment of the present invention, in step S203, the specific method for analyzing the similarity includes:

sequentially calculating the similarity of the blood pressure measurement data on the adjacent time sequences in the blood pressure measurement data corresponding to all the time sequences to form a fluctuation data chain, wherein the calculation formula of the similarity is as follows:

wherein, I is characterized by the similarity of blood pressure measurement data on adjacent time sequences, x_k，x_k+1Characterization ofBlood pressure measurement data at adjacent time sequences k and (k + 1);

calibrating all fluctuation nodes on a fluctuation data chain, and selecting blood pressure measurement data positioned at time sequences at two sides of all fluctuation nodes to reserve the blood pressure measurement data forming abnormal time sequences;

the fluctuation node refers to a data node with the numerical value difference of adjacent nodes on the fluctuation data chain exceeding a similarity threshold.

As a preferable aspect of the present invention, in step S2, the specific method for setting the blood pressure display mode according to the blood pressure characteristics of the target object includes:

setting the current blood pressure characteristic of the current blood pressure trend of the target object as a current trend display mode, wherein the display result of the current trend display mode is that the blood pressure measurement data corresponding to the maximum time sequence is displayed on a display device;

setting the integral blood pressure characteristics of the integral blood pressure trend of the target object as an integral trend display mode, wherein the display result of the integral trend display mode is that an integral trend evolution curved surface formed by blood pressure measurement data corresponding to all time sequences is displayed on a display device;

and setting the blood pressure abnormal characteristics of the blood pressure abnormal trend of the target object as an abnormal trend display mode, wherein the display result of the abnormal trend display mode is that an abnormal trend evolution curved surface formed by the blood pressure measurement data corresponding to all abnormal time sequences is displayed on a display device.

As a preferred scheme of the present invention, the step S2 further includes a specific method for constructing an overall trend evolution curved surface and an abnormal trend evolution curved surface, including:

constructing a multi-dimensional coordinate system, and performing point-by-point fitting on the blood pressure measurement data corresponding to all time sequences in the multi-dimensional coordinate system to obtain an overall trend evolution curved surface;

constructing a multi-dimensional coordinate system, and performing point-by-point fitting on the blood pressure measurement data corresponding to all abnormal time sequences in the multi-dimensional coordinate system to obtain an abnormal trend evolution curved surface;

and the coordinate axes of the multi-dimensional coordinate system respectively correspond to at least one of time sequence and all data types in the blood pressure measurement data.

As a preferable aspect of the present invention, in step S3, the specific method for presenting the blood pressure monitoring result to the target object according to the blood pressure display mode selected by the target object includes:

the target object selects a current trend display mode, the display device displays the blood pressure measurement data corresponding to the maximum time sequence, and displays a current trend judgment result of the target object, specifically:

if the blood pressure measurement data corresponding to the maximum time sequence of the target object exceeds a single blood pressure threshold value, the current trend judgment result is that the blood pressure of the target object is in a sub-health state;

if the blood pressure measurement data corresponding to the maximum time sequence of the target object does not exceed the single blood pressure threshold, the current trend judgment result is that the blood pressure of the target object is in a healthy state;

the target object selects an overall trend display mode, the display device displays an overall trend evolution curved surface and displays an overall trend judgment result of the target object, specifically:

if the similarity between the overall trend evolution curved surface and the standard evolution curved surface is high, the overall trend judgment result is that the target object blood pressure is in a long-term health state;

if the similarity between the overall trend evolution curved surface and the standard evolution curved surface is low, the overall trend judgment result is that the target object blood pressure is in a fluctuation sub-health state;

the target object selects an abnormal trend display mode, the display device displays an abnormal trend evolution curved surface and displays an abnormal trend judgment result of the target object, specifically:

if the similarity between the abnormal trend evolution curved surface and the standard evolution curved surface is low, judging that the abnormal trend judgment result is that the blood pressure of the target object is in a long-term sub-health state;

and if the similarity between the abnormal trend evolution curved surface and the standard evolution curved surface is high, judging that the target object blood pressure is in a fluctuating sub-health state according to an abnormal trend judgment result.

As a preferred scheme of the present invention, the similarity between the overall trend evolution curved surface, the abnormal trend evolution curved surface and the standard evolution curved surface is mathematically quantified by using the euclidean distances of points on all the curved surfaces.

As a preferable aspect of the present invention, in step S1, each blood pressure measurement data of the target subject bound to the blood pressure monitoring data chain may be obtained by taking a stable single item by performing multiple measurements by the target subject at each blood pressure measurement.

As a preferable aspect of the present invention, there is provided a display device according to the sphygmomanometer display control method, comprising: the system comprises a display screen, a central control unit, an authentication unit and a storage unit;

the display screen is used for displaying a blood pressure monitoring result to the target object;

the authentication unit is used for inputting a monitoring account number into the target object before blood pressure measurement for identity authentication, so that blood pressure measurement data of the target object can be accurately bound to the monitoring account number;

the storage unit is used for storing the monitoring account number and the blood pressure monitoring data chain of the target object and providing readable and writable permission to the outside;

and the central control unit is used for processing the blood pressure monitoring data chain and finishing the instruction and data interaction with the display screen, the authentication unit and the storage unit according to the intention of a target object.

Compared with the prior art, the invention has the following beneficial effects:

the invention sets a unique monitoring account for each target object, binds and stores the blood pressure measurement data of each time to the corresponding monitoring account, can avoid the confusion of the data of the target objects caused by the cross use of the sphygmomanometer, ensures the orderliness of the data, can simultaneously carry out the characteristic analysis of the blood pressure trend by utilizing the blood pressure measurement data recorded accumulatively, respectively obtains the current blood pressure trend, the whole blood pressure trend and the abnormal blood pressure trend of the target user, is beneficial to the target user to know the own blood pressure trend, and carries out work and rest adjustment through the blood pressure trend so as to maintain the health of the own blood pressure.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

FIG. 1 is a flow chart of a digital display control method for blood pressure counts according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a similarity analysis provided in accordance with an embodiment of the present invention;

fig. 3 is a block diagram of a display device according to an embodiment of the present invention.

The reference numerals in the drawings denote the following, respectively:

1-a display screen; 2-a central control unit; 3-an authentication unit; 4-a storage unit; 5-fluctuating data chain.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-3, the present invention provides a digital display control method for blood pressure count, comprising the following steps:

step S1, setting a monitoring account for the target object, and binding the blood pressure measurement data of each time into the monitoring account according to the measurement time sequence to be used as a blood pressure monitoring data chain;

in order to keep the ordered and effective matching of the target object and the blood pressure measurement data, the target object uniquely corresponds to a monitoring account, the monitoring account can be a biological account such as a fingerprint, a face and the like, or a character-type account such as a target object name, a target object code and the like, before each blood pressure measurement of the target object, the account of the target object is input, then blood pressure measurement data is obtained after the blood pressure measurement is carried out, and the blood pressure measurement data is stored in the detection account.

In step S1, each blood pressure measurement data of the target object bound to the blood pressure monitoring data chain may be obtained by performing multiple measurements on the target object during each blood pressure measurement to obtain a stable single item, which may avoid the occurrence of an erroneous measurement value stored in the monitoring account, avoid the occurrence of erroneous data in the blood pressure monitoring data chain, and finally avoid the occurrence of an error in the blood pressure trend analyzed from the blood pressure monitoring data chain.

Step S2, respectively extracting blood pressure characteristics representing the blood pressure trend of the target object from the blood pressure monitoring data chain, and setting a blood pressure display mode according to the blood pressure characteristics of the target object;

in step S2, a specific method for extracting blood pressure features representing the blood pressure trend of the target object in the blood pressure monitoring data chain is as follows:

step S201, extracting blood pressure measurement data corresponding to the maximum time sequence from a blood pressure monitoring data chain, wherein the blood pressure measurement data corresponding to the maximum time sequence is characterized by the current blood pressure characteristic of the current trend of the blood pressure of the target object;

step S202, extracting blood pressure measurement data corresponding to all time sequences from a blood pressure monitoring data chain, wherein the blood pressure measurement data corresponding to all time sequences are characterized by the integral blood pressure characteristics of the integral blood pressure trend of the target object;

and S203, performing similarity analysis on the blood pressure measurement data corresponding to all the time sequences to obtain blood pressure measurement data corresponding to abnormal time sequences, wherein the blood pressure measurement data corresponding to the abnormal time sequences represent blood pressure abnormal characteristics of the abnormal trend of the blood pressure of the target object.

The blood pressure measurement data corresponding to the maximum time sequence in the blood pressure monitoring data chain refers to blood pressure data measured by a target object at the current time, and can be used for the target object to know the blood pressure data at the current time, the blood pressure measurement data corresponding to all the time sequences in the blood pressure monitoring data chain comprise feature data of blood pressure overall features representing the blood pressure change of the target object, the whole blood pressure change trend can be analyzed from the whole blood pressure features, the blood pressure measurement data corresponding to abnormal time sequences are analyzed by utilizing the blood pressure measurement data corresponding to all the time sequences to obtain the blood pressure measurement data corresponding to the abnormal time sequences, the blood pressure measurement data corresponding to the abnormal time sequences comprise feature data of blood pressure abnormal features representing the blood pressure change of the target object, and the blood pressure abnormal change trend can be analyzed from the blood pressure abnormal features.

As shown in fig. 2, in step S203, the specific method of similarity analysis includes:

sequentially calculating the similarity of the blood pressure measurement data on the adjacent time sequences in the blood pressure measurement data corresponding to all the time sequences to form a fluctuation data chain, wherein the calculation formula of the similarity is as follows:

wherein, I is characterized by the similarity of blood pressure measurement data on adjacent time sequences, x_k，x_k+1Characterized as blood pressure measurement data at adjacent time sequences k and (k + 1);

the similarity measurement method adopts Euclidean distance, and also can adopt similarity measurement standards with the same functions such as Manhattan distance, Euclidean distance, Chebyshev distance, cosine similarity, Pearson correlation coefficient and the like, and the similarity measurement method is not limited by the selection of the embodiment and is subject to user-defined selection.

Calibrating all fluctuation nodes on a fluctuation data chain, and selecting blood pressure measurement data positioned at time sequences at two sides of all fluctuation nodes to reserve the blood pressure measurement data forming abnormal time sequences;

the fluctuation node refers to a data node with the numerical value difference of adjacent nodes on the fluctuation data chain exceeding a similarity threshold.

The similarity table represents the similarity degree between the blood pressure measurement data on the adjacent time sequences, the higher the numerical value, the higher the similarity degree, the stable maintenance of the blood pressure measurement data of the target object on the adjacent time sequences is indicated, therefore, the similarity degree between the running static image frames of the adjacent equipment forms a fluctuation data chain, the blood pressure measurement data on the adjacent time sequences corresponding to all the data nodes on the gentle curve in the fluctuation data chain has the consistent similarity degree, the blood pressure measurement data of a certain time sequence corresponding to all the data nodes on the gentle curve can be randomly selected to represent the blood pressure measurement data of the whole gentle curve, on one hand, the common characteristic of the blood pressure measurement data on the whole gentle curve is kept, on the other hand, the dimension reduction of the blood pressure measurement data can be realized, the blood pressure measurement data on the adjacent time sequences corresponding to the jumping node on the fluctuation data chain has the inconsistent similarity degree, namely, the blood pressure measurement data on the adjacent time sequences are changed violently, the abnormal blood pressure data of the target object is used as the blood pressure measurement data of the abnormal time sequence, so that all the abnormal blood pressure measurement data of the target object are reflected and can be used for analyzing the abnormal change trend of the blood pressure of the target object.

In step S2, the specific method for setting the blood pressure display mode according to the blood pressure characteristics of the target object includes:

setting the current blood pressure characteristic of the current blood pressure trend of the target object as a current trend display mode, wherein the display result of the current trend display mode is that the blood pressure measurement data corresponding to the maximum time sequence is displayed on a display device;

setting the integral blood pressure characteristics of the integral blood pressure trend of the target object as an integral trend display mode, wherein the display result of the integral trend display mode is that an integral trend evolution curved surface formed by blood pressure measurement data corresponding to all time sequences is displayed on a display device;

and setting the blood pressure abnormal characteristics of the blood pressure abnormal trend of the target object as an abnormal trend display mode, wherein the display result of the abnormal trend display mode is that an abnormal trend evolution curved surface formed by the blood pressure measurement data corresponding to all abnormal time sequences is displayed on a display device.

The method comprises the steps of setting a plurality of display modes for a target object, meeting different blood pressure measurement requirements, selecting a current trend display mode only by knowing current measurement data, selecting an overall trend display mode if the overall trend of the blood pressure of the target object needs to be known, and selecting an abnormal trend display mode if the abnormal change data of the blood pressure of the target object only needs to be known.

The step S2 further includes a specific method for constructing the overall trend evolution surface and the abnormal trend evolution surface, including:

constructing a multi-dimensional coordinate system, and performing point-by-point fitting on blood pressure measurement data corresponding to all time sequences in the multi-dimensional coordinate system to obtain an overall trend evolution curved surface;

constructing a multi-dimensional coordinate system, and performing point-by-point fitting on blood pressure measurement data corresponding to all abnormal time sequences in the multi-dimensional coordinate system to obtain an abnormal trend evolution curved surface;

the coordinate axes of the multidimensional coordinate system respectively correspond to at least one of time sequence and all data types in the blood pressure measurement data.

The integral trend evolution surface is used for quantitatively representing integral evolution characteristics of target object blood pressure, the abnormal trend evolution surface is used for quantitatively representing abnormal evolution characteristics of the target object blood pressure, the abnormal trend evolution surface comprises a plurality of target object blood pressure key abnormal data, the abnormal evolution characteristics of the target object are fitted according to the plurality of target object blood pressure key abnormal data, the abnormal evolution process of the target object can be completely represented, redundant data are not generated, the target object can visually know the time sequence of the self blood pressure abnormality and the degree exceeding a threshold value, and the target object can be helped to analyze formation factors of abnormal evolution, so that auxiliary measurement is provided for local blood pressure control; the whole trend evolution curved surface has enough data for fitting the whole evolution trend representing the blood pressure of the target object, can comprehensively inform the evolution trend of the blood pressure of the target object, neglects extreme values, integrally knows the evolution trend of the blood pressure, can analyze the blood pressure control condition of the target object for a long time, and provides auxiliary measurement for the whole blood pressure control scheme.

And step S3, displaying the blood pressure monitoring result to the target object according to the blood pressure display mode selected by the target object.

In step S3, the specific method for displaying the blood pressure monitoring result to the target object according to the blood pressure display mode selected by the target object includes:

the target object selects a current trend display mode, blood pressure measurement data corresponding to the maximum time sequence are displayed on the display device, and a current trend judgment result of the target object is displayed, specifically:

if the blood pressure measurement data corresponding to the maximum time sequence of the target object exceeds a single blood pressure threshold value, the current trend judgment result is that the blood pressure of the target object is in a sub-health state;

if the blood pressure measurement data corresponding to the maximum time sequence of the target object does not exceed the single blood pressure threshold, the current trend judgment result is that the blood pressure of the target object is in a healthy state;

the target object selects an overall trend display mode, an overall trend evolution curved surface is displayed on the display device, and an overall trend judgment result of the target object is displayed, specifically:

if the similarity between the overall trend evolution curved surface and the standard evolution curved surface is high, the overall trend judgment result is that the target object blood pressure is in a long-term health state;

if the similarity between the overall trend evolution curved surface and the standard evolution curved surface is low, the overall trend judgment result is that the target object blood pressure is in a fluctuation sub-health state;

the target object selects an abnormal trend display mode, an abnormal trend evolution curved surface is displayed on the display device, and an abnormal trend judgment result of the target object is displayed, specifically:

if the similarity between the abnormal trend evolution curved surface and the standard evolution curved surface is low, judging that the target object blood pressure is in a long-term sub-health state according to the abnormal trend judgment result;

and if the similarity between the abnormal trend evolution curved surface and the standard evolution curved surface is high, judging that the target object blood pressure is in a fluctuating sub-health state according to the abnormal trend judgment result.

And the similarity of the whole trend evolution curved surface, the abnormal trend evolution curved surface and the standard evolution curved surface is mathematically quantized by utilizing the Euclidean distances of points on all the curved surfaces.

On the basis of visually displaying the blood pressure evolution trend of the target object by the graph, text description is carried out, the whole trend evolution curved surface, the abnormal trend evolution curved surface and the standard evolution curved surface are compared in similarity, and the state of the blood pressure of the target object is judged, the target object can directly know the self blood pressure condition through text display, and can also know the self blood pressure condition through an observation curved surface, so that the use of various people can be facilitated.

As shown in fig. 3, based on the above-described sphygmomanometer display control method, the present invention provides a display device including: the system comprises a display screen 1, a central control unit 2, an authentication unit 3 and a storage unit 4;

the display screen 1 is used for displaying a blood pressure monitoring result to a target object;

the authentication unit 3 is used for inputting a monitoring account number into the target object before blood pressure measurement to perform identity authentication, so that blood pressure measurement data of the target object can be accurately bound to the monitoring account number;

the storage unit 4 is used for storing the monitoring account number and the blood pressure monitoring data chain of the target object and providing readable and writable permission to the outside;

and the central control unit 2 is used for processing the blood pressure monitoring data chain and finishing the instruction and data interaction with the display screen, the authentication unit and the storage unit according to the intention of the target object.

The invention sets a unique monitoring account for each target object, binds and stores the blood pressure measurement data of each time to the corresponding monitoring account, can avoid the confusion of the data of the target objects caused by the cross use of the sphygmomanometer, ensures the orderliness of the data, can simultaneously carry out the characteristic analysis of the blood pressure trend by utilizing the blood pressure measurement data recorded accumulatively, respectively obtains the current blood pressure trend, the whole blood pressure trend and the abnormal blood pressure trend of the target user, is beneficial to the target user to know the own blood pressure trend, and carries out work and rest adjustment through the blood pressure trend so as to maintain the health of the own blood pressure.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims (10)

1. A digital display control method for blood pressure meters is characterized by comprising the following steps:

step S1, setting a monitoring account for the target object, and binding the blood pressure measurement data of each time into the monitoring account according to the measurement time sequence to be used as a blood pressure monitoring data chain;

step S2, respectively extracting blood pressure characteristics representing the blood pressure trend of the target object from a blood pressure monitoring data chain, and setting a blood pressure display mode according to the blood pressure characteristics of the target object;

and step S3, displaying the blood pressure monitoring result to the target object according to the blood pressure display mode selected by the target object.

2. The display control method of a sphygmomanometer according to claim 1, wherein: the target object uniquely corresponds to the monitoring account.

3. The display control method of a sphygmomanometer according to claim 2, wherein: in step S2, a specific method for extracting blood pressure features representing a blood pressure trend of the target object in the blood pressure monitoring data chain is as follows:

step S201, extracting blood pressure measurement data corresponding to the maximum time sequence from the blood pressure monitoring data chain, wherein the blood pressure measurement data corresponding to the maximum time sequence is characterized by the current blood pressure characteristic of the current blood pressure trend of the target object;

step S202, extracting blood pressure measurement data corresponding to all time sequences from the blood pressure monitoring data chain, wherein the blood pressure measurement data corresponding to all time sequences are characterized by the integral blood pressure characteristics of the integral blood pressure trend of the target object;

and S203, performing similarity analysis on the blood pressure measurement data corresponding to all the time sequences to obtain blood pressure measurement data corresponding to abnormal time sequences, wherein the blood pressure measurement data corresponding to the abnormal time sequences represent blood pressure abnormal characteristics of the abnormal trend of the blood pressure of the target object.

4. A sphygmomanometer display control method according to claim 3, characterized in that: in step S203, the specific method for analyzing the similarity includes:

sequentially calculating the similarity of the blood pressure measurement data on the adjacent time sequences in the blood pressure measurement data corresponding to all the time sequences to form a fluctuation data chain, wherein the calculation formula of the similarity is as follows:

wherein, I is characterized by the similarity of blood pressure measurement data on adjacent time sequences, x_k，x_k+1Characterized as blood pressure measurement data at adjacent time sequences k and (k + 1);

calibrating all fluctuation nodes on a fluctuation data chain, and selecting blood pressure measurement data positioned at time sequences at two sides of all fluctuation nodes to reserve the blood pressure measurement data forming abnormal time sequences;

the fluctuation node refers to a data node with the numerical value difference of adjacent nodes on the fluctuation data chain exceeding a similarity threshold.

5. The display control method of a sphygmomanometer according to claim 4, wherein: in step S2, the specific method for setting the blood pressure display mode according to the blood pressure characteristics of the target object includes:

setting the current blood pressure characteristic of the current blood pressure trend of the target object as a current trend display mode, wherein the display result of the current trend display mode is that the blood pressure measurement data corresponding to the maximum time sequence is displayed on a display device;

setting the integral blood pressure characteristics of the integral blood pressure trend of the target object as an integral trend display mode, wherein the display result of the integral trend display mode is that an integral trend evolution curved surface formed by blood pressure measurement data corresponding to all time sequences is displayed on a display device;

and setting the blood pressure abnormal characteristics of the blood pressure abnormal trend of the target object as an abnormal trend display mode, wherein the display result of the abnormal trend display mode is that an abnormal trend evolution curved surface formed by the blood pressure measurement data corresponding to all abnormal time sequences is displayed on a display device.

6. The display control method of a sphygmomanometer according to claim 5, wherein: the step S2 further includes a specific method for constructing the overall trend evolution surface and the abnormal trend evolution surface, including:

constructing a multi-dimensional coordinate system, and performing point-by-point fitting on the blood pressure measurement data corresponding to all time sequences in the multi-dimensional coordinate system to obtain an overall trend evolution curved surface;

constructing a multi-dimensional coordinate system, and performing point-by-point fitting on the blood pressure measurement data corresponding to all abnormal time sequences in the multi-dimensional coordinate system to obtain an abnormal trend evolution curved surface;

and the coordinate axes of the multi-dimensional coordinate system respectively correspond to at least one of time sequence and all data types in the blood pressure measurement data.

7. The method for controlling display of a blood pressure monitor according to claim 6, wherein in step S3, the specific method for displaying the blood pressure monitoring result to the target subject according to the blood pressure display mode selected by the target subject includes:

the target object selects a current trend display mode, the display device displays the blood pressure measurement data corresponding to the maximum time sequence, and displays a current trend judgment result of the target object, specifically:

if the blood pressure measurement data corresponding to the maximum time sequence of the target object exceeds a single blood pressure threshold value, the current trend judgment result is that the blood pressure of the target object is in a sub-health state;

if the blood pressure measurement data corresponding to the maximum time sequence of the target object does not exceed the single blood pressure threshold, the current trend judgment result is that the blood pressure of the target object is in a healthy state;

the target object selects an overall trend display mode, the display device displays an overall trend evolution curved surface and displays an overall trend judgment result of the target object, specifically:

if the similarity between the overall trend evolution curved surface and the standard evolution curved surface is high, the overall trend judgment result is that the target object blood pressure is in a long-term health state;

if the similarity between the overall trend evolution curved surface and the standard evolution curved surface is low, the overall trend judgment result is that the target object blood pressure is in a fluctuation sub-health state;

the target object selects an abnormal trend display mode, the display device displays an abnormal trend evolution curved surface and displays an abnormal trend judgment result of the target object, specifically:

if the similarity between the abnormal trend evolution curved surface and the standard evolution curved surface is low, judging that the abnormal trend judgment result is that the blood pressure of the target object is in a long-term sub-health state;

and if the similarity between the abnormal trend evolution curved surface and the standard evolution curved surface is high, judging that the target object blood pressure is in a fluctuating sub-health state according to an abnormal trend judgment result.

8. The sphygmomanometer display control method according to claim 7, wherein the overall trend evolution surface, the abnormal trend evolution surface and the standard evolution surface are similar in degree by mathematical quantization using Euclidean distances of points on all surfaces.

9. The method as claimed in claim 8, wherein in step S1, each blood pressure measurement data of the target subject bound to the blood pressure monitoring data chain is obtained by taking a stable single item by performing a plurality of measurements by the target subject at each blood pressure measurement.

10. A display device of the sphygmomanometer display control method according to any one of claims 1 to 9, comprising: the system comprises a display screen (1), a central control unit (2), an authentication unit (3) and a storage unit (4);

the display screen (1) is used for displaying a blood pressure monitoring result to a target object;

the authentication unit (3) is used for inputting a monitoring account number into the target object before blood pressure measurement to perform identity authentication, so that blood pressure measurement data of the target object can be accurately bound to the monitoring account number;

the storage unit (4) is used for storing the monitoring account number and the blood pressure monitoring data chain of the target object and providing readable and writable permission to the outside;

and the central control unit (2) is used for processing the blood pressure monitoring data chain and finishing the instruction and data interaction with the display screen, the authentication unit and the storage unit according to the intention of a target object.

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