CN115944277B - Pulse diagnosis instrument auxiliary pulse diagnosis system based on data analysis - Google Patents

Abstract

The invention provides a pulse diagnosis instrument auxiliary pulse diagnosis system based on data analysis, which comprises the following specific steps: acquiring pulse feeling information in the pulse feeling process of a pulse feeling instrument; the data analysis module receives the pulse feeling information and analyzes the pulse feeling information to obtain pulse feeling parameters and environment parameters, the data acquisition module receives the pulse feeling parameters and the pulse feeling information to acquire pulse feeling reference values, the data acquisition module receives the environment parameters and the pulse feeling information to acquire the environment reference values, and the pulse feeling reference values and the environment reference values are transmitted to the data analysis module; the data analysis module analyzes based on the numerical variation of the pulse diagnosis reference value and the environment reference value, and the invention respectively analyzes based on the pulse diagnosis information of the patient and the pulse diagnosis environment information in the pulse diagnosis information to obtain the pulse diagnosis reference value and the environment reference value, performs pulse diagnosis adjustment based on the pulse diagnosis reference value, and adjusts the pulse diagnosis environment based on the environment reference value.

Description

Pulse diagnosis instrument auxiliary pulse diagnosis system based on data analysis

Technical Field

The invention relates to the technical field of pulse diagnosis instruments, in particular to an auxiliary pulse diagnosis system of a pulse diagnosis instrument based on data analysis.

Background

The pulse-taking instrument is mainly used for realizing objectification of pulse-taking in traditional Chinese medicine. Pulse diagnosis is one of four diagnostic methods in TCM, and is a unique diagnostic method. The pulse diagnosis device mainly analyzes the characteristics of 'position, number, shape, potential' and the like of pulse by using finger feeling so as to judge the functional state of viscera, thereby realizing the purpose of noninvasive diagnosis and having positive significance for diagnosis and treatment of diseases.

In the prior art, in the pulse diagnosis process of the pulse diagnosis instrument, the pulse diagnosis information cannot be acquired and analyzed based on the pulse diagnosis environment and the age interval of a patient, and only a simple pulse diagnosis is performed in the pulse diagnosis process, so that pulse diagnosis errors are easy to occur, and the pulse diagnosis accuracy is influenced.

Disclosure of Invention

Aiming at the defects of the prior art, the invention aims to provide an auxiliary pulse feeling instrument pulse feeling system based on data analysis.

In order to achieve the above object, the present invention is realized by the following technical scheme: the pulse diagnosis instrument auxiliary pulse diagnosis system based on data analysis comprises a pulse diagnosis information acquisition module, a data analysis module, a data acquisition module, a pulse diagnosis judgment module, a control and regulation module, an alarm module and a server; the pulse feeling information acquisition module, the data analysis module, the data acquisition module, the pulse feeling judgment module, the control adjustment module and the alarm module are respectively connected with the server in a data mode;

the pulse feeling information acquisition module acquires pulse feeling information in the pulse feeling process of the pulse feeling instrument;

the pulse feeling information is transmitted to the data analysis module, the data analysis module receives the pulse feeling information to analyze to obtain pulse feeling parameters and environment parameters, and the pulse feeling parameters, the environment parameters and the pulse feeling information are transmitted to the data acquisition module;

the data acquisition module receives the pulse feeling parameters and pulse feeling information to acquire pulse feeling reference values, receives the environment parameters and the pulse feeling information to acquire the environment reference values, and transmits the pulse feeling reference values and the environment reference values to the data analysis module;

the data analysis module analyzes based on the numerical variation of the pulse diagnosis reference value and the environment reference value to obtain an analysis result, and the analysis result is transmitted to the pulse diagnosis judgment module;

the pulse diagnosis judging module performs pulse diagnosis and environment judgment according to the received analysis result to obtain a standard pulse diagnosis reference value and a standard environment reference value, and defines the standard pulse diagnosis reference value and the standard environment reference value as judging results;

the judgment result is transmitted to a control and regulation module and a server, the control and regulation module performs pulse diagnosis regulation based on the judgment result, the server acquires the pulse diagnosis reference value and the environment reference value which are obtained after regulation, if the pulse diagnosis reference value and the environment reference value are different from the standard pulse diagnosis reference value or the standard environment reference value, an alarm is sent out through an alarm module, and if the pulse diagnosis reference value and the environment reference value are identical, the alarm module does not send out an alarm.

Further, the pulse feeling information includes patient pulse feeling information and pulse feeling environment information;

the patient pulse feeling information comprises pulse feeling time information, patient age information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information;

the pulse feeling environment information comprises pulse feeling temperature information, pulse feeling contact humidity information and noise decibel information.

Further, the data analysis module receives pulse feeling time information, patient age information, pulse feeling frequency information, pulse feeling strength information and pulse feeling distance information in the pulse feeling information of the patient, analyzes the patient age information, and specifically comprises the following steps:

acquiring a patient age value based on the patient age information, and setting a first age interval, a second age interval, a third age interval and a fourth age interval by the acquired patient age value;

analyzing pulse feeling time information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information in the first age interval to the fourth age interval respectively;

acquiring a pulse feeling time value of a patient when feeling pulse based on pulse feeling time information, acquiring a pulse feeling frequency value based on pulse feeling frequency information, acquiring a force value of each pulse feeling time based on pulse feeling force information, and acquiring a distance value of each pulse feeling position from a wrist center position based on pulse feeling distance information;

acquiring a pulse diagnosis frequency value, a force value and a distance value from the central position of the wrist, which correspond to pulse diagnosis time values acquired by a patient during measurement;

taking the abscissa as a pulse feeling time value, the ordinate as a pulse feeling frequency value, taking the o point as a coordinate origin as a pulse feeling time reference coordinate system, taking the floating, middle and sinking changes of pulse conditions in the pulse feeling time value as coordinate points based on the pulse feeling frequency value, and smoothly connecting a plurality of coordinate points by curves to form a pulse feeling frequency graph;

forming a plurality of pulse feeling frequency graphs in a pulse feeling time reference coordinate system through multiple times of measurement, acquiring a plurality of pulse feeling periods based on the pulse feeling frequency graphs, acquiring the longest pulse feeling period, acquiring a period time value according to the intersection point of the longest pulse feeling period and a pulse feeling time value, and defining the acquired period time value as a standard pulse feeling time value;

in the process of making coordinate points on pulse feeling frequency values within pulse feeling time values, obtaining corresponding force values and distance values, if the corresponding coordinate points are not obtained clearly in the process of representing, judging that the force values are smaller and the distance values deviate in the process of feeling the pulse, obtaining the force values and the distance values corresponding to the clear state, obtaining the minimum force values when the clear state is represented, defining the current force values as standard force values, obtaining the pulse feeling positions of patients corresponding to the obtained distance values, observing the pulse feeling positions corresponding to the obvious wrist parts, and selecting the current distance values as standard distance values;

the standard pulse feeling time value, the standard force value and the standard distance value in the first age interval to the fourth age interval are respectively obtained, the standard pulse feeling time value, the standard force value and the standard distance value are defined as pulse feeling parameters, and the pulse feeling parameters are transmitted to the data acquisition module.

Further, the data analysis module receives and analyzes the pulse feeling temperature information, the pulse feeling contact humidity information and the noise decibel information in the pulse feeling environment information, and the data analysis module is specifically as follows:

acquiring a pulse feeling temperature value in the pulse feeling process based on pulse feeling temperature information, acquiring a pulse feeling humidity value in the pulse feeling process based on pulse feeling humidity information, and acquiring a noise decibel value in the pulse feeling process based on noise decibel information;

when a patient is subjected to pulse diagnosis, pulse condition information of the known patient is obtained, pulse diagnosis is respectively carried out on patients for multiple times under different environments, and pulse diagnosis temperature value, pulse diagnosis humidity value and noise decibel value in the pulse diagnosis process are obtained;

setting the pulse feeling information of the patient acquired in n environments, wherein the pulse feeling frequency acquired in each environment is a, and the correct frequency of the pulse feeling information is b;

acquiring pulse feeling temperature values, pulse feeling humidity values and noise decibel values of the first environment to the nth environment, acquiring a plurality of pulse feeling times under each environment, comparing the pulse feeling temperature values, the pulse feeling humidity values and the noise decibel values with pulse condition information of known patients, determining correct pulse feeling times, and setting the acquired pulse feeling times of the first environment to be a1 … … and the pulse feeling times of the nth environment to be an; the correct number of pulse feeling information of the first environment is b1 … …, and the correct number of pulse feeling information of the nth environment is bn;

acquiring pulse diagnosis accuracy based on the correct times of pulse diagnosis information in each environment and the pulse diagnosis times in each environment;

acquiring pulse feeling information corresponding to the highest pulse feeling accuracy, defining a pulse feeling temperature value in the current pulse feeling information as a standard temperature value, defining a pulse feeling humidity value in the current pulse feeling information as a standard humidity value, and defining a noise decibel value in the current pulse feeling information as a standard noise decibel value;

and defining the standard temperature value, the standard humidity value and the standard noise decibel value as environment parameters, and transmitting the environment parameters to the data acquisition module.

Further, the data acquisition module receives a standard pulse feeling time value, a standard force value and a standard distance value in pulse feeling parameters; receiving pulse feeling time values, force values and distance values in pulse feeling information to acquire pulse feeling reference data;

obtaining pulse feeling reference data, obtaining a plurality of pulse feeling reference data based on the obtained pulse feeling information, and defining the pulse feeling reference data as pulse feeling reference values;

setting a pulse diagnosis reference interval based on the pulse diagnosis reference value, and sequentially setting a first pulse diagnosis reference interval, a second pulse diagnosis reference interval and a third pulse diagnosis reference interval;

defining the pulse diagnosis reference interval as an analysis result, and transmitting the analysis result to a pulse diagnosis judging module.

Further, the data acquisition module receives a standard temperature value, a standard humidity value and a standard noise decibel value in the environmental parameters, and receives a pulse feeling temperature value, a pulse feeling humidity value and a noise decibel value in pulse feeling information to acquire environmental reference data;

obtaining environment reference data, obtaining a plurality of environment reference data based on the obtained pulse feeling information, and defining the environment reference data as environment reference values; the acquired pulse diagnosis reference value and the environment reference value are transmitted to a data analysis module;

setting an environment reference interval based on the environment reference value, and sequentially setting a first environment reference interval, a second environment reference interval and a third environment reference interval;

and defining an environment reference interval as an analysis result, and transmitting the analysis result to a pulse diagnosis judging module.

Further, the pulse diagnosis judging module receives the pulse diagnosis reference section to judge, and the specific judgment is as follows:

if the pulse feeling reference value is in the first pulse feeling reference interval, judging that the pulse feeling is accurate in the current pulse feeling reference interval, and setting the pulse feeling reference value in the range to be the standard pulse feeling reference value;

if the pulse feeling reference value is in the second pulse feeling reference interval, judging that the pulse feeling effect is general, and readjusting the pulse feeling;

if the pulse feeling reference value is in the third pulse feeling reference interval, an alarm is sent out by the alarm module.

Further, the pulse diagnosis judging module receives the environment reference section to judge, and the specific judgment is as follows:

if the environment reference value is in the first environment reference interval, judging that the environment reference value is in the current environment reference interval, and is good in environment effect, suitable for pulse diagnosis, and setting pulse diagnosis reference values in the range of the environment reference value as standard environment reference values;

if the environment reference value is in the second environment reference interval, judging that the environment is general, and adjusting the pulse diagnosis environment;

if the environment reference value is in the third environment reference interval, judging that the current environment is poor, sending out an alarm through the alarm module, and replacing the pulse diagnosis environment.

The invention has the beneficial effects that:

1. the invention obtains pulse feeling information in the pulse feeling process of the pulse feeling instrument, respectively analyzes the pulse feeling information of a patient and the pulse feeling environment information in the pulse feeling information to obtain a pulse feeling reference value and an environment reference value, performs pulse feeling adjustment based on the pulse feeling reference value, and adjusts the pulse feeling environment based on the environment reference value.

2. According to the invention, the age information of the patient is acquired, the age information of the patient is divided into a plurality of age intervals, the pulse feeling information of the patient in each age interval is acquired respectively, the pulse feeling data of different age intervals are judged, and when pulse feeling is carried out, different pulse feeling can be carried out according to different age intervals, so that the pulse feeling accuracy is improved.

Drawings

Other features, objects and advantages of the present invention will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic block diagram of an auxiliary pulse diagnosis system of a pulse diagnosis instrument based on data analysis according to the present invention;

fig. 2 is a diagram showing the steps of a pulse diagnosis assisting system based on data analysis.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

In the present invention, referring to fig. 1 and 2, a pulse diagnosis instrument auxiliary pulse diagnosis system based on data analysis includes a pulse diagnosis information acquisition module, a data analysis module, a data acquisition module, a pulse diagnosis judgment module, a control adjustment module, an alarm module and a server; the pulse feeling information acquisition module, the data analysis module, the data acquisition module, the pulse feeling judgment module, the control adjustment module and the alarm module are respectively connected with the server in a data mode.

In the invention, in the pulse diagnosis process of the pulse diagnosis instrument, pulse diagnosis information in the pulse diagnosis process of the pulse diagnosis instrument is acquired through a pulse diagnosis information acquisition module;

the pulse feeling information comprises pulse feeling information of a patient and pulse feeling environment information;

the patient pulse feeling information comprises pulse feeling time information, patient age information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information;

the pulse feeling environment information comprises pulse feeling temperature information, pulse feeling contact humidity information and noise decibel information;

the pulse feeling information is transmitted to the data analysis module, the data analysis module receives the pulse feeling information to analyze to obtain pulse feeling parameters and environment parameters, and the pulse feeling parameters, the environment parameters and the pulse feeling information are transmitted to the data acquisition module;

the data analysis module receives pulse feeling time information, patient age information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information in the pulse feeling information of the patient, analyzes the patient age information, and specifically comprises the following steps:

acquiring a patient age value based on the patient age information, and setting a first age interval, a second age interval, a third age interval and a fourth age interval by the acquired patient age value;

analyzing pulse feeling time information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information in the first age interval to the fourth age interval respectively;

acquiring a pulse feeling time value of a patient when feeling pulse based on pulse feeling time information, acquiring a pulse feeling frequency value based on pulse feeling frequency information, acquiring a force value of each pulse feeling time based on pulse feeling force information, and acquiring a distance value of each pulse feeling position from a wrist center position based on pulse feeling distance information;

acquiring a pulse diagnosis frequency value, a force value and a distance value from the central position of the wrist, which correspond to pulse diagnosis time values acquired by a patient during measurement;

taking the abscissa as a pulse feeling time value, the ordinate as a pulse feeling frequency value, taking the o point as a coordinate origin as a pulse feeling time reference coordinate system, taking the floating, middle and sinking changes of pulse conditions in the pulse feeling time value as coordinate points based on the pulse feeling frequency value, and smoothly connecting a plurality of coordinate points by curves to form a pulse feeling frequency graph;

forming a plurality of pulse feeling frequency graphs in a pulse feeling time reference coordinate system through multiple times of measurement, acquiring a plurality of pulse feeling periods based on the pulse feeling frequency graphs, acquiring the longest pulse feeling period, acquiring a period time value according to the intersection point of the longest pulse feeling period and a pulse feeling time value, and defining the acquired period time value as a standard pulse feeling time value;

in the process of making coordinate points on pulse feeling frequency values within pulse feeling time values, obtaining corresponding force values and distance values, if the corresponding coordinate points are not obtained clearly in the process of representing, judging that the force values are smaller and the distance values deviate in the process of feeling the pulse, obtaining the force values and the distance values corresponding to the clear state, obtaining the minimum force values when the clear state is represented, defining the current force values as standard force values, obtaining the pulse feeling positions of patients corresponding to the obtained distance values, observing the pulse feeling positions corresponding to the obvious wrist parts, and selecting the current distance values as standard distance values;

the standard pulse feeling time value, the standard force value and the standard distance value in the first age interval to the fourth age interval are respectively obtained, the standard pulse feeling time value, the standard force value and the standard distance value are defined as pulse feeling parameters, and the pulse feeling parameters are transmitted to the data acquisition module;

in the case of information acquisition for patients in the first age group, the second age group, the third age group, and the fourth age group, information acquisition is performed for the same patient in each age group by sub-measurement, and data summarization is performed by multiple diagnoses of one patient.

The data analysis module receives and analyzes the pulse feeling temperature information, the pulse feeling contact humidity information and the noise decibel information in the pulse feeling environment information, and the data analysis module is specifically as follows:

acquiring a pulse feeling temperature value in the pulse feeling process based on pulse feeling temperature information, acquiring a pulse feeling humidity value in the pulse feeling process based on pulse feeling humidity information, and acquiring a noise decibel value in the pulse feeling process based on noise decibel information;

when a patient is subjected to pulse diagnosis, pulse condition information of the known patient is obtained, pulse diagnosis is respectively carried out on patients for multiple times under different environments, and pulse diagnosis temperature value, pulse diagnosis humidity value and noise decibel value in the pulse diagnosis process are obtained;

setting the pulse feeling information of the patient acquired in n environments, wherein the pulse feeling frequency acquired in each environment is a, and the correct frequency of the pulse feeling information is b;

acquiring pulse feeling temperature values, pulse feeling humidity values and noise decibel values of the first environment to the nth environment, acquiring a plurality of pulse feeling times under each environment, comparing the pulse feeling temperature values, the pulse feeling humidity values and the noise decibel values with pulse condition information of known patients, determining correct pulse feeling times, and setting the acquired pulse feeling times of the first environment to be a1 … … and the pulse feeling times of the nth environment to be an; the correct number of pulse feeling information of the first environment is b1 … …, and the correct number of pulse feeling information of the nth environment is bn;

acquiring pulse diagnosis accuracy based on the correct times of pulse diagnosis information in each environment and the pulse diagnosis times in each environment;

when the pulse diagnosis accuracy is acquired, the method specifically comprises the following steps:

setting the acquired pulse feeling frequency as a, the correct frequency of pulse feeling information as b, the pulse feeling accuracy rate as zql, and specifically solving the pulse feeling accuracy rate by referring to the following formula:

Zql=b/a；

acquiring pulse feeling information corresponding to the highest pulse feeling accuracy, defining a pulse feeling temperature value in the current pulse feeling information as a standard temperature value, defining a pulse feeling humidity value in the current pulse feeling information as a standard humidity value, and defining a noise decibel value in the current pulse feeling information as a standard noise decibel value;

defining a standard temperature value, a standard humidity value and a standard noise decibel value as environment parameters, and transmitting the environment parameters to a data acquisition module;

the data acquisition module receives the pulse feeling parameters and pulse feeling information to acquire pulse feeling reference values, and the data acquisition module receives the environment parameters and the pulse feeling information to acquire the environment reference values and transmits the pulse feeling reference values and the environment reference values to the data analysis module;

the data acquisition module receives a standard pulse feeling time value, a standard force value and a standard distance value in pulse feeling parameters; receiving pulse feeling time values, force values and distance values in pulse feeling information to acquire pulse feeling reference data;

setting standard pulse feeling time values as follows: BZZMSJz; the standard force value is: BZLDSz; the standard distance values are: BZJLSz; pulse feeling time values are: ZMSJSz; the force value is as follows: LDSz; the distance values are: JLSz; pulse feeling reference data are: zmcksj;

for specific calculations, refer to the following formula:

zmcksj=｜ZMSJSz-BZZMSJz｜×｜BZLDSz-LDSz｜×｜BZJLSz-JLSz｜；

it should be noted that, when pulse feeling measurement is performed, the pulse feeling time value is not smaller than the standard pulse feeling time value;

obtaining pulse feeling reference data, obtaining a plurality of pulse feeling reference data based on the obtained pulse feeling information, and defining the pulse feeling reference data as pulse feeling reference values;

the data acquisition module receives a standard temperature value, a standard humidity value and a standard noise decibel value in the environmental parameters, and receives a pulse feeling temperature value, a pulse feeling humidity value and a noise decibel value in pulse feeling information to acquire environmental reference data;

the standard temperature value is set as follows: BZWDz; the standard humidity value is: BZSDz; the standard noise decibel value is: BZZYFBz; the pulse feeling temperature values are as follows: ZMWDSz; pulse feeling humidity values are: ZMSDSz; the noise decibel value is: ZYFBz; the environmental reference data are: hjcksj;

for specific calculations, refer to the following formula:

hjcksj=｜BZWDz-ZMWDSz｜×｜BZSDz-ZMSDSz｜×｜BZZYFBz-ZYFBz｜；

obtaining environment reference data, obtaining a plurality of environment reference data based on the obtained pulse feeling information, and defining the environment reference data as environment reference values; the acquired pulse diagnosis reference value and the environment reference value are transmitted to a data analysis module;

the data analysis module analyzes based on the numerical changes of the pulse diagnosis reference value and the environment reference value to obtain an analysis result, and the analysis result is transmitted to the pulse diagnosis judging module;

the data analysis module is used for analyzing the pulse diagnosis reference value and the environment reference value, and specifically comprises the following steps:

setting a pulse diagnosis reference interval based on the pulse diagnosis reference value, and sequentially setting a first pulse diagnosis reference interval, a second pulse diagnosis reference interval and a third pulse diagnosis reference interval;

setting an environment reference interval based on the environment reference value, and sequentially setting a first environment reference interval, a second environment reference interval and a third environment reference interval;

defining a pulse diagnosis reference interval and an environment reference interval as analysis results, and transmitting the analysis results to a pulse diagnosis judging module;

the pulse diagnosis judging module performs pulse diagnosis and environment judgment according to the received analysis result to obtain a standard pulse diagnosis reference value and a standard environment reference value, and defines the standard pulse diagnosis reference value and the standard environment reference value as judging results;

the pulse diagnosis judging module receives the pulse diagnosis reference interval to judge, and the specific judgment is as follows:

if the pulse feeling reference value is in the first pulse feeling reference interval, judging that the pulse feeling is accurate in the current pulse feeling reference interval, and setting the pulse feeling reference value in the range to be the standard pulse feeling reference value;

if the pulse feeling reference value is in the second pulse feeling reference interval, judging that the pulse feeling effect is general, and readjusting the pulse feeling;

if the pulse feeling reference value is in the third pulse feeling reference interval, an alarm is sent out by the alarm module.

The pulse diagnosis judging module receives the environment reference interval for judgment, and the specific judgment is as follows:

if the environment reference value is in the first environment reference interval, judging that the environment reference value is in the current environment reference interval, and is good in environment effect, suitable for pulse diagnosis, and setting pulse diagnosis reference values in the range of the environment reference value as standard environment reference values;

if the environment reference value is in the second environment reference interval, judging that the environment is general, and adjusting the pulse diagnosis environment;

if the environment reference value is in the third environment reference interval, judging that the current environment is poor, sending out an alarm through the alarm module, and replacing the pulse diagnosis environment.

And transmitting the judgment result to a control and regulation module and a server, wherein the control and regulation module performs pulse diagnosis regulation based on the judgment result, the server acquires the pulse diagnosis reference value and the environment reference value which are obtained after regulation, and if the pulse diagnosis reference value and the environment reference value are different from the standard pulse diagnosis reference value or the standard environment reference value, an alarm is sent out by an alarm module, and if the pulse diagnosis reference value and the environment reference value are identical to each other, the alarm module does not send out an alarm.

The auxiliary pulse feeling system of the pulse feeling instrument based on data analysis specifically comprises the following steps in the process of auxiliary pulse feeling:

step S1: acquiring pulse feeling information in the pulse feeling process of the pulse feeling instrument, transmitting the pulse feeling information to a data analysis module, receiving the pulse feeling information by the data analysis module, analyzing the pulse feeling information to obtain pulse feeling parameters and environment parameters, and transmitting the pulse feeling parameters, the environment parameters and the pulse feeling information to a data acquisition module;

the pulse feeling information comprises pulse feeling information of a patient and pulse feeling environment information;

the data analysis module receives and analyzes pulse feeling time information, patient age information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information in pulse feeling information of a patient, and the specific steps are as follows when the analysis is performed:

step S11: acquiring a patient age value based on the patient age information, and setting a first age interval, a second age interval, a third age interval and a fourth age interval by the acquired patient age value;

analyzing pulse feeling time information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information in the first age interval to the fourth age interval respectively;

step S111: acquiring a pulse feeling time value of a patient when feeling pulse based on pulse feeling time information, acquiring a pulse feeling frequency value based on pulse feeling frequency information, acquiring a force value of each pulse feeling time based on pulse feeling force information, and acquiring a distance value of each pulse feeling position from a wrist center position based on pulse feeling distance information;

step S112: acquiring a pulse diagnosis frequency value, a force value and a distance value from the central position of the wrist, which correspond to pulse diagnosis time values acquired by a patient during measurement;

step S113: taking the abscissa as a pulse feeling time value, the ordinate as a pulse feeling frequency value, taking the o point as a coordinate origin as a pulse feeling time reference coordinate system, taking the floating, middle and sinking changes of pulse conditions in the pulse feeling time value as coordinate points based on the pulse feeling frequency value, and smoothly connecting a plurality of coordinate points by curves to form a pulse feeling frequency graph;

step S114: forming a plurality of pulse feeling frequency graphs in a pulse feeling time reference coordinate system through multiple times of measurement, acquiring a plurality of pulse feeling periods based on the pulse feeling frequency graphs, acquiring the longest pulse feeling period, acquiring a period time value according to the intersection point of the longest pulse feeling period and a pulse feeling time value, and defining the acquired period time value as a standard pulse feeling time value;

step S115: acquiring a corresponding force value and a distance value in the process of making a coordinate point on the pulse frequency value within the pulse time value, and judging that the force value is smaller and the distance value is deviated in the process of making pulse if the corresponding coordinate point is not clearly acquired in the process of representing;

step S116: acquiring a corresponding force value and a distance value when the force value is clearly indicated, acquiring a minimum force value when the force value is clearly indicated, defining a current force value as a standard force value, acquiring a pulse feeling position of a patient corresponding to the acquired distance value, observing a pulse feeling position of the wrist obvious corresponding to the distance value, and selecting the current distance value as the standard distance value;

step S117: the standard pulse feeling time value, the standard force value and the standard distance value in the first age interval to the fourth age interval are respectively obtained, the standard pulse feeling time value, the standard force value and the standard distance value are defined as pulse feeling parameters, and the pulse feeling parameters are transmitted to the data acquisition module;

step S12: the data analysis module receives and analyzes the pulse feeling temperature information, the pulse feeling contact humidity information and the noise decibel information in the pulse feeling environment information, and the data analysis module is specifically as follows:

step S13: acquiring a pulse feeling temperature value in the pulse feeling process based on pulse feeling temperature information, acquiring a pulse feeling humidity value in the pulse feeling process based on pulse feeling humidity information, and acquiring a noise decibel value in the pulse feeling process based on noise decibel information;

step S14: when a patient is subjected to pulse diagnosis, pulse condition information of the known patient is obtained, pulse diagnosis is respectively carried out on patients for multiple times under different environments, and pulse diagnosis temperature value, pulse diagnosis humidity value and noise decibel value in the pulse diagnosis process are obtained;

step S15: setting the pulse feeling information of the patient acquired in n environments, wherein the pulse feeling frequency acquired in each environment is a, and the correct frequency of the pulse feeling information is b;

step S16: acquiring pulse feeling temperature values, pulse feeling humidity values and noise decibel values of the first environment to the nth environment, acquiring a plurality of pulse feeling times under each environment, comparing the pulse feeling temperature values, the pulse feeling humidity values and the noise decibel values with pulse condition information of known patients, determining correct pulse feeling times, and setting the acquired pulse feeling times of the first environment to be a1 … … and the pulse feeling times of the nth environment to be an; the correct number of pulse feeling information of the first environment is b1 … …, and the correct number of pulse feeling information of the nth environment is bn;

step S17: acquiring pulse diagnosis accuracy based on the correct times of pulse diagnosis information in each environment and the pulse diagnosis times in each environment;

step S18: acquiring pulse feeling information corresponding to the highest pulse feeling accuracy, defining a pulse feeling temperature value in the current pulse feeling information as a standard temperature value, defining a pulse feeling humidity value in the current pulse feeling information as a standard humidity value, and defining a noise decibel value in the current pulse feeling information as a standard noise decibel value;

step S19: and defining the standard temperature value, the standard humidity value and the standard noise decibel value as environment parameters, and transmitting the environment parameters to the data acquisition module.

Step S2: the data acquisition module receives the pulse feeling parameters and pulse feeling information to acquire pulse feeling reference values, and the data acquisition module receives the environment parameters and the pulse feeling information to acquire the environment reference values and transmits the pulse feeling reference values and the environment reference values to the data analysis module;

step S3: the data analysis module analyzes based on the numerical changes of the pulse diagnosis reference value and the environment reference value to obtain an analysis result, the analysis result is transmitted to the pulse diagnosis judging module, the pulse diagnosis judging module performs pulse diagnosis and environment judgment according to the received analysis result to obtain a standard pulse diagnosis reference value and a standard environment reference value, and the standard pulse diagnosis reference value and the standard environment reference value are defined as judging results;

step S4: and transmitting the judgment result to a control and regulation module and a server, wherein the control and regulation module performs pulse diagnosis regulation based on the judgment result, the server acquires the pulse diagnosis reference value and the environment reference value which are obtained after regulation, and if the pulse diagnosis reference value and the environment reference value are different from the standard pulse diagnosis reference value or the standard environment reference value, an alarm is sent out by an alarm module, and if the pulse diagnosis reference value and the environment reference value are identical to each other, the alarm module does not send out an alarm.

The above formulas are all formulas for removing dimensions and taking numerical calculation, the formulas are formulas for obtaining the latest real situation by collecting a large amount of data and performing software simulation, preset parameters in the formulas are set by a person skilled in the art according to the actual situation, if weight coefficients and proportion coefficients exist, the set sizes are specific numerical values obtained by quantizing the parameters, the subsequent comparison is convenient, and the proportional relation between the weight coefficients and the proportion coefficients is not influenced as long as the proportional relation between the parameters and the quantized numerical values is not influenced.

In the foregoing embodiments of the present application, the descriptions of the embodiments are emphasized, and for a portion of this disclosure that is not described in detail in this embodiment, reference is made to the related descriptions of other embodiments.

It will be appreciated by those skilled in the art that embodiments of the present invention may be provided as a method, system, or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media having computer-usable program code embodied therein. The storage medium may be implemented by any type or combination of volatile or nonvolatile Memory devices, such as static random access Memory (Static Random Access Memory, SRAM), electrically erasable Programmable Read-Only Memory (Electrically Erasable Programmable Read-Only Memory, EEPROM), erasable Programmable Read-Only Memory (Erasable Programmable Read Only Memory, EPROM), programmable Read-Only Memory (PROM), read-Only Memory (ROM), magnetic Memory, flash Memory, magnetic disk, or optical disk. These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

The above examples are only specific embodiments of the present invention, and are not intended to limit the scope of the present invention, but it should be understood by those skilled in the art that the present invention is not limited thereto, and that the present invention is described in detail with reference to the foregoing examples: any person skilled in the art may modify or easily conceive of the technical solution described in the foregoing embodiments, or perform equivalent substitution of some of the technical features, while remaining within the technical scope of the present disclosure; such modifications, changes or substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention, and are intended to be included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (5)

1. The pulse diagnosis instrument auxiliary pulse diagnosis system based on data analysis is characterized by comprising a pulse diagnosis information acquisition module, a data analysis module, a data acquisition module, a pulse diagnosis judgment module, a control and regulation module, an alarm module and a server; the pulse feeling information acquisition module, the data analysis module, the data acquisition module, the pulse feeling judgment module, the control adjustment module and the alarm module are respectively connected with the server in a data mode;

the pulse feeling information acquisition module acquires pulse feeling information in the pulse feeling process of the pulse feeling instrument;

the pulse feeling information is transmitted to the data analysis module, the data analysis module receives the pulse feeling information to analyze to obtain pulse feeling parameters and environment parameters, and the pulse feeling parameters, the environment parameters and the pulse feeling information are transmitted to the data acquisition module;

the data acquisition module receives the pulse feeling parameters and pulse feeling information to acquire pulse feeling reference values, receives the environment parameters and the pulse feeling information to acquire the environment reference values, and transmits the pulse feeling reference values and the environment reference values to the data analysis module;

the data analysis module analyzes based on the numerical variation of the pulse diagnosis reference value and the environment reference value to obtain an analysis result, and the analysis result is transmitted to the pulse diagnosis judgment module;

the pulse diagnosis judging module performs pulse diagnosis and environment judgment according to the received analysis result to obtain a standard pulse diagnosis reference value and a standard environment reference value, and defines the standard pulse diagnosis reference value and the standard environment reference value as judging results;

the judgment result is transmitted to a control and regulation module and a server, the control and regulation module performs pulse diagnosis regulation based on the judgment result, the server acquires a pulse diagnosis reference value and an environment reference value which are obtained after regulation, if the pulse diagnosis reference value is different from a standard pulse diagnosis reference value or a standard environment reference value, an alarm is sent out through an alarm module, and if the pulse diagnosis reference value is the same as the standard pulse diagnosis reference value or the standard environment reference value, the alarm module does not send out an alarm;

the pulse feeling information comprises pulse feeling information of a patient and pulse feeling environment information;

the patient pulse feeling information comprises pulse feeling time information, patient age information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information;

the pulse feeling environment information comprises pulse feeling temperature information, pulse feeling contact humidity information and noise decibel information;

the data analysis module receives pulse feeling time information, patient age information, pulse feeling frequency information, pulse feeling strength information and pulse feeling distance information in the pulse feeling information of the patient, analyzes the patient age information, and specifically comprises the following steps:

acquiring a patient age value based on the patient age information, and setting a first age interval, a second age interval, a third age interval and a fourth age interval by the acquired patient age value;

analyzing pulse feeling time information, pulse feeling frequency information, pulse feeling force information and pulse feeling distance information in the first age interval to the fourth age interval respectively;

acquiring a pulse feeling time value of a patient when feeling pulse based on pulse feeling time information, acquiring a pulse feeling frequency value based on pulse feeling frequency information, acquiring a force value of each pulse feeling time based on pulse feeling force information, and acquiring a distance value of each pulse feeling position from a wrist center position based on pulse feeling distance information;

acquiring a pulse diagnosis frequency value, a force value and a distance value from the central position of the wrist, which correspond to pulse diagnosis time values acquired by a patient during measurement;

taking the abscissa as a pulse feeling time value, the ordinate as a pulse feeling frequency value, taking the o point as a coordinate origin as a pulse feeling time reference coordinate system, taking the floating, middle and sinking changes of pulse conditions in the pulse feeling time value as coordinate points based on the pulse feeling frequency value, and smoothly connecting a plurality of coordinate points by curves to form a pulse feeling frequency graph;

forming a plurality of pulse feeling frequency graphs in a pulse feeling time reference coordinate system through multiple times of measurement, acquiring a plurality of pulse feeling periods based on the pulse feeling frequency graphs, acquiring the longest pulse feeling period, acquiring a period time value according to the intersection point of the longest pulse feeling period and a pulse feeling time value, and defining the acquired period time value as a standard pulse feeling time value;

in the process of making coordinate points on pulse feeling frequency values within pulse feeling time values, obtaining corresponding force values and distance values, if the corresponding coordinate points are not obtained clearly in the process of representing, judging that the force values are smaller and the distance values deviate in the process of feeling the pulse, obtaining the force values and the distance values corresponding to the clear state, obtaining the minimum force values when the clear state is represented, defining the current force values as standard force values, obtaining the pulse feeling positions of patients corresponding to the obtained distance values, observing the pulse feeling positions corresponding to the obvious wrist parts, and selecting the current distance values as standard distance values;

the standard pulse feeling time value, the standard force value and the standard distance value in the first age interval to the fourth age interval are respectively obtained, the standard pulse feeling time value, the standard force value and the standard distance value are defined as pulse feeling parameters, and the pulse feeling parameters are transmitted to the data acquisition module;

the data analysis module receives and analyzes pulse feeling temperature information, pulse feeling contact humidity information and noise decibel information in pulse feeling environment information, and the data analysis module is specifically as follows:

acquiring a pulse feeling temperature value in the pulse feeling process based on pulse feeling temperature information, acquiring a pulse feeling humidity value in the pulse feeling process based on pulse feeling humidity information, and acquiring a noise decibel value in the pulse feeling process based on noise decibel information;

when a patient is subjected to pulse diagnosis, pulse condition information of the known patient is obtained, pulse diagnosis is respectively carried out on patients for multiple times under different environments, and pulse diagnosis temperature value, pulse diagnosis humidity value and noise decibel value in the pulse diagnosis process are obtained;

setting the pulse feeling information of the patient acquired in n environments, wherein the pulse feeling frequency acquired in each environment is a, and the correct frequency of the pulse feeling information is b;

acquiring pulse feeling temperature values, pulse feeling humidity values and noise decibel values of the first environment to the nth environment, acquiring a plurality of pulse feeling times under each environment, comparing the pulse feeling temperature values, the pulse feeling humidity values and the noise decibel values with pulse condition information of known patients, determining correct pulse feeling times, setting the acquired pulse feeling times of the first environment to be a1, and setting the pulse feeling times of the nth environment to be an; the correct number of pulse feeling information of the first environment is b1, and the correct number of pulse feeling information of the nth environment is bn;

acquiring pulse diagnosis accuracy based on the correct times of pulse diagnosis information in each environment and the pulse diagnosis times in each environment;

acquiring pulse feeling information corresponding to the highest pulse feeling accuracy, defining a pulse feeling temperature value in the current pulse feeling information as a standard temperature value, defining a pulse feeling humidity value in the current pulse feeling information as a standard humidity value, and defining a noise decibel value in the current pulse feeling information as a standard noise decibel value;

and defining the standard temperature value, the standard humidity value and the standard noise decibel value as environment parameters, and transmitting the environment parameters to the data acquisition module.

2. The data analysis-based pulse-taking assistance system of claim 1, wherein the data acquisition module receives a standard pulse-taking time value, a standard force value, and a standard distance value from pulse-taking parameters; receiving pulse feeling time values, force values and distance values in pulse feeling information to acquire pulse feeling reference data;

obtaining pulse feeling reference data, obtaining a plurality of pulse feeling reference data based on the obtained pulse feeling information, and defining the pulse feeling reference data as pulse feeling reference values;

setting a pulse diagnosis reference interval based on the pulse diagnosis reference value, and sequentially setting a first pulse diagnosis reference interval, a second pulse diagnosis reference interval and a third pulse diagnosis reference interval;

defining the pulse diagnosis reference interval as an analysis result, and transmitting the analysis result to a pulse diagnosis judging module.

3. The pulse diagnosis apparatus auxiliary pulse diagnosis system based on data analysis of claim 1, wherein the data acquisition module receives a standard temperature value, a standard humidity value and a standard noise decibel value in the environmental parameter, and receives a pulse diagnosis temperature value, a pulse diagnosis humidity value and a noise decibel value in pulse diagnosis information to acquire environmental reference data;

obtaining environment reference data, obtaining a plurality of environment reference data based on the obtained pulse feeling information, and defining the environment reference data as environment reference values; the acquired pulse diagnosis reference value and the environment reference value are transmitted to a data analysis module;

setting an environment reference interval based on the environment reference value, and sequentially setting a first environment reference interval, a second environment reference interval and a third environment reference interval;

and defining an environment reference interval as an analysis result, and transmitting the analysis result to a pulse diagnosis judging module.

4. The pulse diagnosis apparatus auxiliary pulse diagnosis system based on data analysis according to claim 2, wherein the pulse diagnosis judgment module receives a pulse diagnosis reference section for judgment, and the specific judgment is as follows:

if the pulse feeling reference value is in the first pulse feeling reference interval, judging that the pulse feeling is accurate in the current pulse feeling reference interval, and setting the pulse feeling reference value in the range to be the standard pulse feeling reference value;

if the pulse feeling reference value is in the second pulse feeling reference interval, judging that the pulse feeling effect is general, and readjusting the pulse feeling;

if the pulse feeling reference value is in the third pulse feeling reference interval, an alarm is sent out by the alarm module.

5. The pulse diagnosis apparatus auxiliary pulse diagnosis system based on data analysis according to claim 3, wherein the pulse diagnosis judgment module receives the environmental reference section for judgment, and the specific judgment is as follows:

if the environment reference value is in the first environment reference interval, judging that the environment reference value is in the current environment reference interval, and is good in environment effect, suitable for pulse diagnosis, and setting pulse diagnosis reference values in the range of the environment reference value as standard environment reference values;

if the environment reference value is in the second environment reference interval, judging that the environment is general, and adjusting the pulse diagnosis environment;

if the environment reference value is in the third environment reference interval, judging that the current environment is poor, sending out an alarm through the alarm module, and replacing the pulse diagnosis environment.

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