CN110393506B - Blood pressure monitoring device and blood pressure data processing system - Google Patents

Abstract

The invention discloses blood pressure monitoring equipment and a blood pressure data processing system. The blood pressure monitoring device is used for executing a blood pressure data processing method, and the method comprises the following steps: receiving a blood pressure measurement starting instruction, and detecting whether the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection; when the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection, the blood pressure monitoring equipment starts blood pressure measurement, and records and stores blood pressure measurement data measured by the blood pressure monitoring equipment in a blood pressure measurement period; synchronously sending the blood pressure measurement data to a cloud server, and receiving a data analysis table returned after the cloud server performs data analysis on the blood pressure measurement data; and determining the blood pressure measurement result according to the normal amplitude value and the corrected amplitude value included in the data analysis table, and displaying the blood pressure measurement result on the blood pressure monitoring equipment. The invention improves the accuracy of the blood pressure measurement data and ensures the timeliness of the blood pressure measurement result.

Description

Blood pressure monitoring device and blood pressure data processing system

Technical Field

The invention relates to the field of data processing, in particular to blood pressure monitoring equipment and a blood pressure data processing system.

Background

At present, the electronic blood pressure meter generally enters a family, and a user can use the electronic blood pressure meter to measure and know own blood pressure data and own blood pressure condition.

The electronic sphygmomanometer can realize the function of blood pressure measurement and depends on fixed hardware and a measurement algorithm. The general electronic sphygmomanometer measures blood pressure data by adopting an oscillometric method, and the principle of the oscillometric method for measuring the blood pressure data comprises the following steps: the inflation quantity of a cuff wound on an upper arm is automatically adjusted to change the pressure, the pressure sensor receives oscillation waves generated when blood flows through blood vessels, in the deflation process, the pressure and the fluctuation detected by the pressure sensor are changed along with the change of the oscillation waves, the time with the maximum fluctuation is selected as a reference point, on the basis of the reference point, the fluctuation point of a certain value is searched forwards as the systolic pressure, and the fluctuation point of a certain value is searched backwards as the diastolic pressure. The oscillography is adopted to measure the blood pressure data, so that certain blood pressure data errors exist, the blood pressure data are inaccurate, and finally the problem that the blood pressure measurement result output by the electronic sphygmomanometer is unreliable occurs.

Disclosure of Invention

The embodiment of the invention provides a blood pressure monitoring device and a blood pressure data processing system, which improve the data processing efficiency and the accuracy of blood pressure measurement data; meanwhile, the blood pressure measuring result can be effectively fed back in time, and the timeliness of the blood pressure measuring result is ensured.

A blood pressure monitoring device for performing the above blood pressure data processing method, the method comprising:

receiving a blood pressure measurement starting instruction, and detecting whether the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection; the receiving of the blood pressure measurement starting instruction comprises: receiving a blood pressure measurement starting instruction sent by a mobile terminal connected with the blood pressure monitoring equipment in a preset communication connection mode;

when the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection, the blood pressure monitoring equipment starts blood pressure measurement, and blood pressure measurement data measured by the blood pressure monitoring equipment in a blood pressure measurement period is recorded and stored in real time; the blood pressure measurement data comprises a plurality of pulse waves, amplitude values of the pulse waves, a first change rate of a compression phase and a second change rate of a decompression phase;

synchronously sending the blood pressure measurement data measured in the blood pressure measurement period to the cloud server, and receiving a data analysis table returned after the cloud server performs data analysis on the blood pressure measurement data; the data analysis table comprises a normal amplitude value corresponding to a normal pulse wave, a corrected amplitude value corresponding to an abnormal pulse wave after correction according to a correction model and a correction factor; the correction factor is the absolute value of the difference between the amplitude value before correction and the amplitude value after correction; the modification model comprises a modification function; the correction function calculates the pulse frequency according to the time interval between two pulse waves and then generates the correction function according to the pulse frequency, the first change rate of the pressurization stage and the second change rate of the decompression stage; the data analysis table is generated according to a normal amplitude value corresponding to a normal pulse wave, a correction amplitude value corresponding to an abnormal pulse wave, a pulse frequency and a correction factor;

and determining a blood pressure measurement result according to the normal amplitude value and the corrected amplitude value included in the data analysis table, and displaying the blood pressure measurement result on the blood pressure monitoring equipment.

A blood pressure data processing system comprises a cloud server, a mobile terminal and the blood pressure monitoring equipment; the blood pressure monitoring equipment is in communication connection with the cloud server and the mobile terminal.

According to the blood pressure monitoring device and the blood pressure data processing system, when a blood pressure measuring instruction is received and the network connection state between the blood pressure monitoring device and the cloud server is normal, the blood pressure measuring data are measured through the blood pressure monitoring device, the blood pressure measuring data are synchronously sent to the cloud server, the blood pressure measuring data are analyzed by the receiving cloud server and then returned to a data analysis table, finally, the blood pressure measuring result is determined according to the normal amplitude value and the corrected amplitude value which are included in the data analysis table, and the blood pressure measuring result is displayed on the blood pressure monitoring device. According to the blood pressure data processing method provided by the invention, data transmission and data interaction between the blood pressure monitoring equipment and the cloud server are realized, the blood pressure measurement data are analyzed through the cloud server, the data processing efficiency is improved, and the accuracy of the blood pressure measurement data is improved; meanwhile, the blood pressure measurement result can be effectively fed back in time, and the timeliness of the blood pressure measurement result is ensured; in addition, the running speed of the blood pressure monitoring device can be increased.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments of the present invention will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without inventive labor.

FIG. 1 is a schematic diagram of an application environment of a blood pressure data processing method according to an embodiment of the present invention;

FIG. 2 is a flow chart of a method for processing blood pressure data according to an embodiment of the present invention;

FIG. 3 is a flowchart of step S10 of a blood pressure data processing method according to an embodiment of the present invention;

fig. 4 is a flowchart of step S10 of the blood pressure data processing method according to another embodiment of the present invention.

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 some, not all, embodiments of the present invention. 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.

The blood pressure data processing method provided by the invention can be applied to an application environment shown in fig. 1, wherein the blood pressure monitoring device is communicated with the cloud server through a network, and the blood pressure monitoring device is communicated with the mobile terminal through the network. The cloud server can be realized by an independent cloud server or a cloud server cluster consisting of a plurality of cloud servers; the mobile terminal includes, but is not limited to, a smart phone, a tablet computer, and a portable wearable device.

In an embodiment, as shown in fig. 2, a blood pressure data processing method is provided, which is described by taking the blood pressure monitoring device in fig. 1 as an example, and includes the following steps:

and S10, receiving a blood pressure measurement starting instruction, and detecting whether the network connection state between the blood pressure monitoring device and the cloud server is normal connection.

Specifically, the blood pressure monitoring device may be provided with a measurement button bound to the blood pressure measurement start instruction, and when the user wants to measure the blood pressure, the user may press the measurement button, so that the blood pressure measurement start instruction may be triggered, and before starting the blood pressure measurement, whether the network connection state between the blood pressure monitoring device and the cloud server is normal or not may be automatically detected. When the network connection state between the blood pressure monitoring device and the cloud server is normal connection, the blood pressure monitoring device may perform data transmission and data interaction with the server, and enter step S20; when the network connection state between the blood pressure monitoring device and the cloud server is abnormal connection, failure of blood pressure measurement is prompted, and at the moment, a user needs to analyze and solve the fault of the abnormal connection, so that the network connection state between the blood pressure monitoring device and the cloud server is recovered to be normal connection from the abnormal connection.

S20, when the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection, the blood pressure monitoring equipment starts blood pressure measurement, and records and stores blood pressure measurement data measured by the blood pressure monitoring equipment in a blood pressure measurement period in real time; the blood pressure measurement data includes a plurality of pulse waves and amplitude values of the pulse waves.

In this embodiment, the blood pressure measurement cycle refers to the time from the start of pressurization to the end of depressurization of the blood pressure monitoring device; the blood pressure measurement data includes, but is not limited to, a plurality of pulse waves, a time interval between two pulse waves, an amplitude value of each pulse wave, a first rate of change of the compression phase and a second rate of change of the decompression phase, and the like.

Specifically, when the blood pressure monitoring device is started, the blood pressure monitoring device can be connected with the cloud server through a network (preferably a wireless network), the network connection state is displayed on the blood pressure monitoring device, after a blood pressure measurement starting instruction is received, when the network connection state is normal connection, the blood pressure monitoring device starts blood pressure measurement, and blood pressure measurement data measured by the blood pressure monitoring device in a blood pressure measurement period are recorded and stored in real time.

S30, synchronously sending the blood pressure measurement data measured in the blood pressure measurement period to the cloud server, and receiving a data analysis table returned after the cloud server performs data analysis on the blood pressure measurement data; the data analysis table comprises a normal amplitude value corresponding to a normal pulse wave and a corrected amplitude value corresponding to an abnormal pulse wave after correction according to the correction model.

In this embodiment, the data analysis table includes, but is not limited to, the number of pulses, a normal amplitude value corresponding to a pulse wave determined to be normal among all pulse waves sequentially measured within one blood pressure measurement period, a corrected amplitude value corresponding to a pulse wave determined to be abnormal among all pulse waves, and a correction factor. The normal amplitude value and the corrected amplitude value have a certain amplitude arrangement sequence, and the amplitude arrangement sequence of the normal amplitude value and the corrected amplitude value is consistent with the sequence of the pulse wave.

Specifically, the blood pressure measurement data measured in step S20 is synchronously transmitted to the cloud server, and when the cloud server receives the blood pressure measurement data (including, but not limited to, a plurality of pulse waves, a time interval between two pulse waves, an amplitude value of each pulse wave, a first change rate of the compression phase and a second change rate of the decompression phase, etc.), the cloud server may calculate the pulse frequency according to the time interval between two pulse waves, and generate the correction function according to the pulse frequency, the first change rate of the compression phase and the second change rate of the decompression phase.

Further, firstly, the cloud server inputs each pulse wave and the amplitude value thereof into a discrimination model (preset in the cloud server) containing a preset filter function, receives the abnormal pulse wave and the amplitude value thereof output by the discrimination model, receives the normal pulse wave and the amplitude value thereof output by the discrimination model, and marks the amplitude value of the normal pulse wave as the normal amplitude value; inputting the amplitude value of the abnormal pulse wave into a correction model (preset in a cloud server) comprising the correction function, receiving the amplitude value of the abnormal pulse wave after correction and a correction factor (the absolute value of the difference between the amplitude value before correction and the amplitude value after correction) output by the correction model, and marking the amplitude value of the abnormal pulse wave after correction as a corrected amplitude value; and finally, generating a data analysis table according to the normal amplitude value corresponding to the normal pulse wave, the corrected amplitude value corresponding to the abnormal pulse wave, the pulse frequency and the correction factor, and transmitting the data analysis table to the blood pressure monitoring equipment. Understandably, abnormal pulse waves can be accurately identified through a discrimination model contained in the cloud server, and the data identification efficiency is improved; and the abnormal amplitude value of the pulse wave is corrected through the correction model contained in the cloud server, so that the data processing efficiency is improved, and the measurement precision of the blood pressure value is favorably improved.

And S40, determining the blood pressure measuring result according to the normal amplitude value and the corrected amplitude value included in the data analysis table, and displaying the blood pressure measuring result on the blood pressure monitoring device.

In this embodiment, the blood pressure measurement results include, but are not limited to, systolic pressure, diastolic pressure, differential pressure (absolute value of the difference between systolic pressure and diastolic pressure), pulse rate, correction factor, and the like.

Preferably, the step S40 specifically includes the following steps:

firstly, inputting the normal amplitude value and the corrected amplitude value included in the data analysis table into a preset blood pressure value analysis thread, receiving systolic pressure, diastolic pressure and differential pressure returned by the blood pressure value analysis thread, and recording the systolic pressure, the diastolic pressure and the differential pressure as blood pressure measurement results.

That is, the normal amplitude value and the corrected amplitude value are sequentially placed in the preset blood pressure value analysis thread in the order of amplitude arrangement, at this time, the blood pressure value analysis thread may first generate an amplitude curve from the received normal amplitude value and corrected amplitude value, and determine a reference amplitude value (preferably, a maximum amplitude value) from the amplitude curve, and then obtain an amplitude value for calculating a systolic pressure and an amplitude value for calculating a diastolic pressure using a systolic pressure coefficient, a diastolic pressure coefficient, and the reference amplitude value that are previously arranged in the blood pressure value analysis thread, and finally determine a systolic pressure, a diastolic pressure, and a differential pressure based on the amplitude value for calculating a systolic pressure and the amplitude value for calculating a diastolic pressure, and output the systolic pressure, the diastolic pressure, and the differential pressure. Understandably, the blood pressure measurement result is determined by utilizing a blood pressure value analysis thread, the reliability and the accuracy of the blood pressure measurement result are improved, and experiments prove that the accuracy of the blood pressure measurement result output by the blood pressure monitoring equipment can be improved by 5-10%.

Then, generating a notice of completion of blood pressure measurement, and enabling the blood pressure monitoring equipment to display the blood pressure measurement result in a preset display mode; the preset display mode includes a global display and an equal-scale-down display.

That is, the systolic pressure, the diastolic pressure and the differential pressure returned by the blood pressure value analysis line are used as blood pressure measurement results, and a blood pressure measurement completion notification is automatically generated at the same time to prompt the user to timely view the blood pressure measurement results displayed on the blood pressure monitoring device according to the preset display mode. Preferably, a measurement number can be automatically acquired, and the measurement number and the blood pressure measurement result are stored in a local database corresponding to the blood pressure monitoring device in an associated manner, so that the blood pressure measurement result can be conveniently inquired in the local database corresponding to the blood pressure monitoring device, and the traceability of data is improved.

And preferably, the correction factor and the pulse rate included in the data analysis table may also be displayed on the blood pressure monitoring apparatus as a blood pressure measurement result.

In summary, in this embodiment, when the blood pressure measurement instruction is received and the network connection state between the blood pressure monitoring device and the cloud server is normal connection, the blood pressure measurement data is measured by the blood pressure monitoring device, and is synchronously sent to the cloud server, then the blood pressure measurement data is analyzed by the receiving cloud server and is returned to a data analysis table, and finally, the blood pressure measurement result is determined according to the normal amplitude value and the corrected amplitude value included in the data analysis table, and is displayed on the blood pressure monitoring device. According to the embodiment, data transmission and data interaction between the blood pressure monitoring equipment and the cloud server are realized, the blood pressure measurement data are analyzed through the cloud server, the data processing efficiency is improved, and the accuracy of the blood pressure measurement data is improved; meanwhile, the blood pressure measurement result can be effectively fed back in time, and the timeliness of the blood pressure measurement result is ensured; in addition, the running speed of the blood pressure monitoring device can be increased.

In an embodiment, as shown in fig. 3, the receiving of the blood pressure measurement starting instruction in step S10 specifically includes the following steps:

and S1011, receiving a blood pressure measurement starting instruction sent by a mobile terminal connected with the blood pressure monitoring equipment in a preset communication connection mode.

In an aspect of this embodiment, the preset communication connection manner includes a first connection manner; the first connection mode is that after the physical address of the blood pressure monitoring device is configured in advance in a special program on the mobile terminal, the connection between the blood pressure monitoring device and the mobile terminal is completed through the special program.

Specifically, when the blood pressure monitoring device is connected to the mobile terminal through the first connection mode, a start button bound to the blood pressure measurement start instruction may be provided in the dedicated program on the mobile terminal. When a user needs to measure blood pressure, the special program is opened, the special program is enabled to automatically scan and identify the physical address of the blood pressure monitoring equipment, at the moment, if the special program does not identify the physical address of the blood pressure monitoring equipment, the starting button is enabled to be kept in an unselected state, at the moment, the starting button cannot be clicked, namely, a blood pressure measurement starting instruction cannot be triggered; and if the special program identifies the physical address of the blood pressure monitoring equipment, the starting button is changed from the non-selectable state to the selectable state, and at the moment, the user clicks the starting button to trigger a blood pressure measurement starting instruction. It can be understood that, in the process of opening the special program, since the special program is directly installed on the mobile terminal and the page information of the special program is cached in the mobile database corresponding to the mobile terminal, the user does not need to refresh the page each time the special program is opened. And understandably, the special program can be a program developed by a product developer of the blood pressure monitoring equipment and issued on a webpage server, so that a user can access the webpage server to download and install the program.

In another aspect of this embodiment, the predetermined communication connection mode includes a second connection mode; the second connection mode is that after user information is bound in advance in a service platform on the mobile terminal and a physical address of the blood pressure monitoring device is configured in advance, the connection between the blood pressure monitoring device and the mobile terminal is completed through the service platform.

Specifically, when the blood pressure monitoring device is connected to the mobile terminal through the second connection mode, a menu item bound with the blood pressure measurement start instruction may be set in the service platform on the mobile terminal. When a user needs to measure the blood pressure, the service platform is opened, the service platform automatically scans and identifies the physical address of the blood pressure monitoring equipment, the content of successful connection of the equipment is prompted to the user, and at the moment, the user clicks the menu item, and a blood pressure measurement instruction can be triggered. In the process of opening the service platform, the service platform depends on the existing program resource on the mobile terminal, and is not installed on the mobile terminal, and the page information of the service platform is not cached in the mobile database corresponding to the mobile terminal, so that a user needs to refresh a page each time the service platform is opened.

In another embodiment, the step S40 of displaying the blood pressure measurement result on the blood pressure monitoring device specifically includes the following steps:

generating a blood pressure measurement ending instruction, and transmitting the blood pressure measurement result to the mobile terminal in a preset transmission mode; the preset transmission mode comprises encryption compression transmission.

That is, when it is detected that decompression is completed, a blood pressure measurement completion instruction is automatically generated, a file transfer packet is generated after a blood pressure measurement result (including but not limited to a systolic pressure, a diastolic pressure, a pressure difference, a correction factor, a pulse rate, and the like) is encrypted and compressed, and the file transfer packet is transferred to the mobile terminal, and at this time, the mobile terminal obtains the blood pressure measurement result after the file transfer packet is decompressed and decrypted, and displays the blood pressure measurement result.

Understandably, in the process of blood pressure measurement, the measurement process of blood pressure measurement can be displayed on the mobile terminal in real time, and the measurement process displayed on the mobile terminal reaches a preset completion threshold (such as 100%) when the blood pressure measurement is finished, so that the blood pressure measurement process can be monitored in real time conveniently, and the user experience is improved.

In another embodiment, as shown in fig. 3, before the step S1011, the following steps are included:

and S1012, receiving a communication connection instruction sent by the blood pressure monitoring equipment. That is, the blood pressure monitoring device may be provided with a "connect/disconnect" button bound to the communication connection instruction, and when the user needs to monitor the blood pressure measurement result through the mobile terminal (preferably, a smartphone), the "connect/disconnect" button is pressed, so that the communication connection instruction can be triggered.

And S1013, analyzing the communication connection command and determining the command type of the communication connection command.

That is, the communication connection instruction may carry information such as a physical address of the blood pressure monitoring device and an operation code indicating an instruction type, and when the communication connection instruction is received, the operation code indicating the instruction type is extracted from the communication connection instruction, and the instruction type of the communication connection instruction is determined according to a preset correspondence between the operation code and the instruction type. For example, the instruction corresponding to the operation code "001 d" is an instruction indicating establishment of terminal connection, the instruction corresponding to the operation code "002 d" is an instruction indicating interruption of terminal connection, and the like, that is, the "connect/disconnect" button may correspond to the two operation codes.

And S1014, when the instruction type is an instruction for indicating the establishment of the terminal connection, generating a communication connection request carrying the physical address, and sending the communication connection request to the mobile terminal.

In another embodiment, when the type of the instruction is an instruction indicating to interrupt a terminal connection, a communication interrupt request carrying the physical address is generated, the communication interrupt request is sent to the mobile terminal, a third response result returned by the mobile terminal after responding to the communication interrupt request is received, when the third response result is that communication interrupt is accepted, successful interrupt communication between the blood pressure monitoring device and the mobile terminal is determined, and when the third response result is that communication interrupt is rejected, the interrupt communication between the blood pressure monitoring device and the mobile terminal is determined to be failed, that is, data still can be interacted between the blood pressure monitoring device and the mobile terminal.

And S1015, enabling the mobile terminal to check the physical address carried by the communication connection request, and receiving a first response result sent by the mobile terminal according to the check result.

That is, after receiving the communication connection request, the mobile terminal may match and compare a physical address pre-configured on the dedicated program or the service platform with a physical address carried in the communication connection request, and when the matching is correct, determine that the verification result is a verification pass, at this time, generate a first response result of accepting the communication connection, and return the first response result of accepting the communication connection; and when the matching comparison fails, determining that the verification result is that the verification fails, at the moment, generating a first response result of rejecting the communication connection, and returning the first response result of rejecting the communication connection.

And S1016, when the first response result is that the communication connection is accepted, determining that the communication connection is successfully established between the blood pressure monitoring device and the mobile terminal.

That is, after the blood pressure monitoring device receives a first response result of accepting communication connection returned by the mobile terminal, the blood pressure monitoring device and the mobile terminal are successfully connected, and data can be interacted between the blood pressure monitoring device and the mobile terminal; and after receiving a first response result of refusing the communication connection returned by the mobile terminal, the blood pressure monitoring device determines that the communication connection between the blood pressure monitoring device and the mobile terminal is not successfully established.

In summary, the embodiment can realize data interaction between the blood pressure monitoring device and the mobile terminal, so that the blood pressure monitoring device can be controlled through the mobile terminal, and the blood pressure measurement result of the blood pressure monitoring device is monitored, thereby facilitating timely discovery of abnormality; in addition, user experience can be satisfied.

In an embodiment, as shown in fig. 4, the step S10 of detecting whether the network connection state between the blood pressure monitoring device and the cloud server is a normal connection includes the following steps:

and S1021, sending the network connection request from the blood pressure monitoring equipment to the cloud server.

S1022, a second response result returned after the cloud server responds to the network connection request is waited and received.

And S1023, when the second response result is that network connection is accepted, determining that the network connection state between the blood pressure monitoring device and the cloud server is normal connection, and displaying the network connection state of normal connection on the blood pressure monitoring device.

In this embodiment, before starting blood pressure measurement, a network connection request including network setting data is automatically sent to the cloud server, at this time, the cloud server automatically verifies the network setting data included in the network connection request, when the verification passes, a second response result accepting network connection is generated, and the second response result accepting network connection is returned, and when the blood pressure monitoring device receives the second response result accepting network connection, it is determined that the network connection state between the blood pressure monitoring device and the cloud server is normal connection, and data transmission and data interaction can be performed between the blood pressure monitoring device and the cloud server.

It should be noted that after the blood pressure monitoring device is connected to the cloud server through the network for the first time, the network setting data may be stored in the local database corresponding to the blood pressure monitoring device.

In an embodiment, as shown in fig. 4, after the step S1022, the following steps are included:

and S1024, when the second response result is that network connection is rejected, determining that the network connection state between the blood pressure monitoring device and the cloud server is abnormal connection, and displaying the network connection state of the abnormal connection on the blood pressure monitoring device. Further, when the blood pressure monitoring device receives a second response result of rejecting network connection returned by the cloud server, the blood pressure monitoring device may send a network diagnosis request to the cloud server, receive a fault problem report associated with abnormal connection returned by the cloud server in response to the network diagnosis request, and display the fault problem report on the blood pressure monitoring device.

In summary, the embodiment realizes data transmission and data interaction between the blood pressure monitoring device and the cloud server, so that blood pressure measurement data determined by the blood pressure monitoring device can be synchronously processed by the cloud server, and the data processing efficiency is improved; in addition, the running speed of the blood pressure monitoring device can be increased.

In an embodiment, a blood pressure monitoring device is provided, which is used for executing the blood pressure data processing method in the above embodiment.

In an embodiment, a blood pressure data detection and monitoring system is provided, which includes a cloud server, a mobile terminal, and a blood pressure monitoring device for executing the blood pressure data processing method in the above embodiment; the blood pressure monitoring equipment is in communication connection with the cloud server and the mobile terminal.

The above-mentioned embodiments are only used for illustrating the technical solutions of the present invention, and not for limiting the same; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the spirit and scope of the embodiments of the present invention, and are intended to be included within the scope of the present invention.

Claims (8)

1. A blood pressure monitoring device for performing a blood pressure data processing method, the method comprising:

receiving a blood pressure measurement starting instruction, and detecting whether the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection; the receiving of the blood pressure measurement starting instruction comprises: receiving a blood pressure measurement starting instruction sent by a mobile terminal connected with the blood pressure monitoring equipment in a preset communication connection mode;

when the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection, the blood pressure monitoring equipment starts blood pressure measurement, and blood pressure measurement data measured by the blood pressure monitoring equipment in a blood pressure measurement period is recorded and stored in real time; the blood pressure measurement data comprises a plurality of pulse waves, amplitude values of the pulse waves, a first change rate of a compression phase and a second change rate of a decompression phase;

synchronously sending the blood pressure measurement data measured in the blood pressure measurement period to the cloud server, and receiving a data analysis table returned after the cloud server performs data analysis on the blood pressure measurement data; the data analysis table comprises a normal amplitude value corresponding to a normal pulse wave, a corrected amplitude value corresponding to an abnormal pulse wave after correction according to the correction model and a correction factor; the correction factor is the absolute value of the difference between the amplitude value before correction and the amplitude value after correction; the modification model comprises a modification function; the correction function calculates the pulse frequency according to the time interval between two pulse waves and then generates the correction function according to the pulse frequency, the first change rate of the pressurization stage and the second change rate of the decompression stage; the data analysis table is generated according to a normal amplitude value corresponding to a normal pulse wave, a correction amplitude value corresponding to an abnormal pulse wave, a pulse frequency and a correction factor;

and determining a blood pressure measurement result according to the normal amplitude value and the corrected amplitude value included in the data analysis table, and displaying the blood pressure measurement result on the blood pressure monitoring equipment.

2. The blood pressure monitoring device of claim 1, wherein the predetermined communication connection comprises a first connection; the first connection mode is that after the physical address of the blood pressure monitoring device is configured in advance in a special program on the mobile terminal, the connection between the blood pressure monitoring device and the mobile terminal is completed through the special program.

3. The blood pressure monitoring device of claim 1 wherein the predetermined communication connection comprises a second connection; the second connection mode is that after user information is bound in advance in the existing program resources on the mobile terminal and the physical address of the blood pressure monitoring device is configured in advance, the connection between the blood pressure monitoring device and the mobile terminal is completed through the existing program resources.

4. The blood pressure monitoring device of claim 1, wherein the blood pressure monitoring device is configured to perform a blood pressure data processing method, the method further comprising:

receiving a communication connection instruction sent by the blood pressure monitoring equipment;

analyzing the communication connection instruction and determining the instruction type of the communication connection instruction;

when the instruction type is an instruction for indicating to establish communication connection, acquiring a physical address of the blood pressure monitoring equipment carried in the communication connection instruction;

when the instruction type is an instruction for indicating to establish terminal connection, generating a communication connection request carrying the physical address, and sending the communication connection request to the mobile terminal;

the mobile terminal is enabled to verify the physical address carried by the communication connection request, and a first response result sent by the mobile terminal according to the verification result is received;

and when the first response result is that the communication connection is accepted, determining that the communication connection is successfully established between the blood pressure monitoring equipment and the mobile terminal.

5. The blood pressure monitoring device of claim 1, wherein said detecting whether the network connection status between the blood pressure monitoring device and the cloud server is a normal connection comprises:

sending a network connection request from the blood pressure monitoring device to the cloud server;

waiting and receiving a second response result returned after the cloud server responds to the network connection request;

and when the second response result is that network connection is accepted, determining that the network connection state between the blood pressure monitoring equipment and the cloud server is normal connection, and displaying the network connection state of the normal connection on the blood pressure monitoring equipment.

6. The blood pressure monitoring device of claim 5, wherein the blood pressure monitoring device is configured to perform a blood pressure data processing method, the method further comprising:

and when the second response result is that network connection is refused, determining that the network connection state between the blood pressure monitoring equipment and the cloud server is abnormal connection, and displaying the network connection state of the abnormal connection on the blood pressure monitoring equipment.

7. The blood pressure monitoring device according to claim 1, wherein said determining a blood pressure measurement result from the normal amplitude value and the corrected amplitude value included in the data analysis table and displaying the blood pressure measurement result on the blood pressure monitoring device comprises:

inputting the normal amplitude value and the corrected amplitude value included in the data analysis table into a preset blood pressure value analysis thread, receiving systolic pressure, diastolic pressure and differential pressure returned by the blood pressure value analysis thread, and recording the systolic pressure, the diastolic pressure and the differential pressure as blood pressure measurement results;

generating a blood pressure measurement completion notice, and enabling the blood pressure monitoring equipment to display the blood pressure measurement result in a preset display mode; the preset display mode comprises global display and equal-scale reduction display.

8. A blood pressure data detection monitoring system, which is characterized by comprising a cloud server, a mobile terminal and the blood pressure monitoring device as claimed in claim 1; the blood pressure monitoring equipment is in communication connection with the cloud server and the mobile terminal.

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