CN110772248B - Wearable device electrocardio real-time monitoring system and method - Google Patents

Abstract

The embodiment of the invention discloses a wearable device electrocardio real-time monitoring system and a wearable device electrocardio real-time monitoring method, wherein the wearable device electrocardio real-time monitoring system comprises the following steps: wearable equipment, adjusting equipment and display equipment; the wearable device is used for acquiring initial electrocardiogram data of a first stage of a patient wearing the wearable device; the adjusting device is used for carrying out ST-stage adjustment on the initial electrocardiogram data to obtain target ST data; the wearable device sets the target ST data as an initialization configuration parameter, acquires second-stage target electrocardio data of a patient wearing the wearable device based on the initialization configuration parameter, and sends the target electrocardio data to the display device; the display equipment is used for receiving the target electrocardio data and displaying the target electrocardio data, so that the displayed electrocardio data is more visual, the real-time monitoring of the electrocardio data of the patient is realized, a doctor can conveniently diagnose and treat the patient in time according to the electrocardio data, the interaction between the patient and the doctor is enhanced, and the danger of disease occurrence is reduced.

Description

Wearable device electrocardio real-time monitoring system and method

Technical Field

The invention relates to the technical field of medical treatment, in particular to a wearable device electrocardio real-time monitoring system and a wearable device electrocardio real-time monitoring method.

Background

With the trend of obesity and aging of the population in China, the number of people with heart diseases is increased rapidly, and the lives of the people in China are threatened seriously. For heart diseases, the death is greatly reduced by examining the electrocardiogram conventionally so as to discover and treat the heart diseases as soon as possible. The dynamic electrocardiogram is widely applied in the heart function examination scheme at present, is combined with intelligent terminals such as mobile phones and the like, and can easily realize remote medical treatment and real-time monitoring through a network. In recent years, wearable devices are continuously developed, and it is possible to record real-time electrocardiograms of human bodies by using the wearable devices, so that the health monitoring requirements of people and effective ways with limited medical resources are relieved.

However, wearable electrocardio monitoring system commonly used at present all sets up fixed parameter in advance in the monitoring process and realizes the monitoring, and not only the process is loaded down with trivial details, and moreover because the heart electrograph monitoring data is comparatively complicated, this wearable electrocardio monitoring system commonly used monitors heart electrograph data and is difficult to guarantee directly perceived nature and accuracy, and because lack the real-time nature that the interaction is difficult to guarantee the monitoring, consequently, need provide a high-efficient wearing formula electrocardio monitoring system urgently.

Disclosure of Invention

Therefore, in order to solve the above problems, a wearable device electrocardiograph real-time monitoring system and method capable of accurately and real-time electrocardiograph monitoring for a wearable device are provided.

In a first aspect, the present invention provides a wearable device electrocardiograph real-time monitoring system, which includes: the wearable device is in communication connection with the adjusting device and the display device respectively, and the adjusting device is in communication connection with the display device;

the wearable device is used for acquiring initial electrocardiogram data of a first stage of a patient wearing the wearable device;

the adjusting device is used for performing ST-segment adjustment on the initial electrocardiogram data to obtain target ST data, and sending the target ST data to the wearable device;

the wearable device receives the target ST data, sets the target ST data as an initialization configuration parameter, collects second-stage target electrocardio data of a patient wearing the wearable device based on the initialization configuration parameter, and sends the target electrocardio data to the display device;

and the display equipment is used for receiving the target electrocardio data and displaying the target electrocardio data.

In one embodiment, the adjusting device is further configured to receive target electrocardiographic data sent by the wearable device, analyze the target electrocardiographic data, convert the target electrocardiographic data into an ST trend graph, and send the ST trend graph to the display device for display.

In one embodiment, the adjustment device is further configured to analyze the patient condition rating of the patient wearing the wearable device based on the ST trend graph.

In one embodiment, the wearable device further comprises:

a positioning unit for positioning a real-time position of the patient wearing the wearable device;

and the alarm linkage unit is used for linking the 120 emergency system when the disease condition grade exceeds a preset grade, and sending the real-time position to the 120 emergency system.

In one embodiment, the wearable device comprises: and the scanning unit is used for scanning the two-dimensional code corresponding to the medical record of the patient wearing the wearable equipment.

In one embodiment, the adjusting device further comprises a plotting unit for plotting a waveform of the patient condition level versus time according to the patient condition level and transmitting the waveform to the display device.

In one embodiment, the wearable device electrocardiographic real-time monitoring system further comprises: and the doctor shift exchange module is used for responding to the shift exchange request according to the target electrocardio data in the shift exchange request sent by the doctor end.

In a second aspect, the invention further provides a wearable device electrocardio real-time monitoring method, which includes:

acquiring initial electrocardiogram data of a first stage of a patient wearing the wearable device;

performing ST-segment adjustment on the initial electrocardiogram data to obtain target ST data;

obtaining target electrocardiographic data of a second stage of the patient wearing the wearable device based on the target ST data;

and displaying the target electrocardiogram data in an ST trend graph mode.

A computer-readable storage medium storing a computer program which, when executed by a processor, causes the processor to perform the steps of:

in one embodiment, the performing ST-segment adjustment on the initial electrocardiographic data to obtain target ST data includes:

obtaining an ISO baseline point and an ST point based on the initial electrocardiogram data;

calculating the amplitude difference between the ST point and the ISO base line point;

determining the target ST data based on the amplitude difference.

In one embodiment, the displaying the target electrocardiographic data by using an ST trend graph includes:

acquiring the target electrocardio data of N patients, wherein N is a natural number greater than 1;

acquiring a reference point from the target electrocardio data;

and performing curve fitting on the target electrocardiogram data based on the reference point to obtain a oscillogram as the ST trend graph.

The wearable device electrocardio real-time monitoring system and the wearable device electrocardio real-time monitoring method comprise a wearable device, a regulating device and a display device, wherein the wearable device is respectively in communication connection with the regulating device and the display device, and the regulating device is in communication connection with the display device; the wearable device is used for acquiring initial electrocardiogram data of a first stage of a patient wearing the wearable device; the adjusting device is used for performing ST-segment adjustment on the initial electrocardiogram data to obtain target ST data, and sending the target ST data to the wearable device; the wearable device receives the target ST data, sets the target ST data as an initialization configuration parameter, collects second-stage target electrocardio data of a patient wearing the wearable device based on the initialization configuration parameter, and sends the target electrocardio data to the display device; the display equipment is used for receiving the target electrocardio data and displaying the target electrocardio data, so that the displayed electrocardio data is more visual, the real-time monitoring of the electrocardio data of the patient is realized, a doctor can conveniently diagnose and treat the patient in time according to the electrocardio data, the interaction between the patient and the doctor is enhanced, and the danger of disease occurrence is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Wherein:

FIG. 1 is a schematic diagram of an embodiment of a wearable device electrocardiographic real-time monitoring system;

FIG. 2 is a schematic diagram of an electrocardiographic monitoring system of a wearable device according to another embodiment;

FIG. 3 is a schematic diagram of an electrocardiographic monitoring system of a wearable device according to another embodiment;

FIG. 4 is a schematic diagram of an electrocardiographic monitoring system of a wearable device according to yet another embodiment;

FIG. 5 is a schematic diagram of an electrocardiographic monitoring system of a wearable device according to yet another embodiment;

FIG. 6 is a flow chart of a wearable device electrocardiographic real-time monitoring method in one embodiment;

FIG. 7 is a flow diagram of a method for ST segment adjustment in one embodiment;

FIG. 8 is a flow diagram of a method of computing an ST trend graph in one embodiment.

Detailed Description

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

As shown in fig. 1, in one embodiment, there is provided a wearable device electrocardiographic real-time monitoring system, which includes: wearable equipment 10, adjusting device 20 and display device 30, wearable equipment respectively with adjusting device with display device communication connection, adjusting device with display device communication connection.

The wearable device 10 is a portable device worn on a user for performing electrocardiographic data monitoring, such as a Holter (cartridge), however, a conventional Holter requires parameter configuration before use, and is cumbersome and unable to provide real-time continuous electrocardiographic monitoring service for the user. In this embodiment, the wearable device electrocardiograph real-time monitoring system includes wearable device 10, adjusting device 20 and display device 30, where adjusting device 20 is used to accurately configure the parameters of wearable device 10, and display device 30 is used to display electrocardiograph information collected by the wearable device after adjustment by adjusting device 20 in real time, so as to overcome the defects of the conventional Holter. The wearable device 10 is in communication connection with the adjusting device 20 and the display device 30 respectively, and the adjusting device 20 is in communication connection with the display device 30, so that instant transmission of electrocardiogram information and instructions is guaranteed.

It should be noted that the adjusting device 20 and the display device 30 may be assembled as a single unit, or may not be assembled as two devices.

The wearable device 10 is used for acquiring initial electrocardiogram data of a first stage of a patient wearing the wearable device.

The first phase refers to a phase in which the configuration parameters of the wearable device 10 are default parameters and are not adjusted by the adjustment device 20, for example, within 20 minutes, 25 minutes, or 30 minutes of starting the acquisition, or the like. The initial electrocardiogram data refers to data stored on the wearable device and used for reflecting electrocardiogram information of the patient, such as an electrocardiogram waveform diagram and the like.

The adjusting device 20 is configured to perform ST-segment adjustment on the initial electrocardiographic data to obtain target ST data, and send the target ST data to the wearable device 10.

The adjusting device can be realized by a processor, or a mobile terminal capable of performing ST adjustment on the electrocardiographic data is installed, and is used for performing ST-segment adjustment on the initial electrocardiographic data to obtain target ST data, and sending the target ST data to the wearable device 10. The traditional Holter is preset with parameters in the box, and the set parameters are set based on empirical values, so that the accuracy of the parameters is difficult to ensure, and the accuracy of electrocardio data acquired by wearable equipment is influenced. Therefore, in this embodiment, the ST-segment adjustment is performed on the initial electrocardiographic data by the adjustment device, and the adjusted target ST data is sent to the wearable device 10, so that the wearable device can obtain the parameters set based on the electrocardiographic data of the patient, and the accuracy of parameter configuration of the wearable device is improved.

The wearable device 10 receives the target ST data, sets the target ST data as an initialization configuration parameter, collects second-stage target electrocardiographic data of a patient wearing the wearable device based on the initialization configuration parameter, and sends the target electrocardiographic data to the display device 30.

Specifically, the wearable device 10 receives the target ST data and sets the target ST data as the initialization configuration parameters, i.e., sets the target ST data as the initialization configuration parameters of the wearable device. The wearable device with the adjusted configuration parameters continues to acquire the second-stage target electrocardiographic data of the patient wearing the wearable device, and sends the target electrocardiographic data to the display device 30. The second stage refers to a time period for collecting the configuration parameters of the wearable device after the configuration parameters are adjusted, such as within 10 hours, within 11 hours, or within 12 hours, which is not limited herein. By continuously acquiring the target electrocardio data of the second stage, the electrocardio data of the patient can be acquired, and the electrocardio of the patient can be monitored.

The display device 30 is configured to receive the target electrocardiographic data and display the target electrocardiographic data.

The display device 30 can be implemented by a display screen and a communication module, and is used for receiving the target electrocardiogram data and displaying the target electrocardiogram data, so that the displayed electrocardiogram data is more visual, the real-time monitoring of the electrocardiogram data of the patient is realized, a doctor can conveniently diagnose and treat the patient in time according to the electrocardiogram data, the interaction between the patient and the doctor is enhanced, and the danger of disease occurrence is reduced.

The wearable device electrocardio real-time monitoring system comprises wearable devices, adjusting devices and display devices, wherein the wearable devices are respectively in communication connection with the adjusting devices and the display devices, and the adjusting devices are in communication connection with the display devices; the wearable device is used for acquiring initial electrocardiogram data of a first stage of a patient wearing the wearable device; the adjusting device is used for performing ST-segment adjustment on the initial electrocardiogram data to obtain target ST data, and sending the target ST data to the wearable device; the wearable device receives the target ST data, sets the target ST data as an initialization configuration parameter, collects second-stage target electrocardio data of a patient wearing the wearable device based on the initialization configuration parameter, and sends the target electrocardio data to the display device; the display equipment is used for receiving the target electrocardio data and displaying the target electrocardio data, so that the displayed electrocardio data is more visual, the real-time monitoring of the electrocardio data of the patient is realized, a doctor can conveniently diagnose and treat the patient in time according to the electrocardio data, the interaction between the patient and the doctor is enhanced, and the danger of disease occurrence is reduced.

In one embodiment, the adjusting device is further configured to receive target electrocardiographic data sent by the wearable device, analyze the target electrocardiographic data, convert the target electrocardiographic data into an ST trend graph, and send the ST trend graph to the display device for display.

Specifically, the adjusting device is further used for analyzing and processing the received target electrocardiogram data and converting the analysis and processing result into an ST trend graph, so that the electrocardiogram data of the patient can be better reflected, and the electrocardiogram data is more visual. Understandably, under the condition that the adjusting equipment is not used, the doctor cannot visually analyze the electrocardio data in real time, the data are analyzed and processed by the adjusting equipment, and the ST trend graph is sent to the display equipment to be displayed, so that the electrocardio data monitoring process of the doctor on the patient is simplified, and the working efficiency of the doctor is improved.

In one embodiment, the adjustment device is further configured to analyze the patient condition rating of the patient wearing the wearable device based on the ST trend graph.

Wherein, the disease level is an index for measuring the severity of the heart disease of the patient. Specifically, the adjusting device analyzes the ST trend graph, for example, classifies the electrocardiogram data of the ST trend graph, counts the quantity of each type of electrocardiogram data, and further calculates and determines the disease condition grade, so that a doctor can more conveniently and accurately know the disease condition severity of a patient and can perform early warning in time.

As shown in fig. 2, in one embodiment, the wearable device further comprises:

and the positioning unit 11 is used for positioning the real-time position of the patient wearing the wearable device.

The positioning unit 11 may be implemented by installing navigation software on the wearable device or installing a positioning sensor, and is configured to position the position of the patient wearing the wearable device in real time to obtain the position information of the patient.

And the alarm linkage unit 12 is used for linking the 120 emergency system when the disease condition grade exceeds a preset grade, and sending the real-time position to the 120 emergency system.

The alarm linkage unit 12 can be linked with the emergency system 120 to realize linkage of the emergency system, so as to perform emergency treatment on the patient in case of serious disease grade of the patient.

The wearable device comprises a positioning unit 11 and an alarm linkage unit 12, wherein the positioning unit 11 is used for positioning the real-time position of a patient wearing the wearable device; the alarm linkage unit 12 is used for linking the 120 emergency system when the disease condition level exceeds a preset level, and sending a real-time position to the 120 emergency system, so that the critical patient can be rescued in time.

As shown in fig. 3, in one embodiment, the wearable device comprises: and the scanning unit 13 is used for scanning the two-dimensional code corresponding to the medical record of the patient wearing the wearable device.

The scanning unit 13 can be implemented by a processor which is provided with a camera device and processes a two-dimensional code or a bar code, specifically, a medical record can be newly created for a patient by a doctor, the medical record is filled with information of the patient, an emergency contact, a monitoring doctor and the like, the recording mode has sources such as manual mode, one-key recording of an identity card or a social security card, a his system and the like, the medical record information is generated into the two-dimensional code, and the wearable device scans the two-dimensional code corresponding to a medical record image to realize communication between a server and a client.

As shown in fig. 4, in one embodiment, the adjusting device further comprises a drawing unit 21 for drawing a waveform chart of the patient condition level and time according to the patient condition level and sending the waveform chart to the display device.

The drawing unit 21 may be implemented by a client installed with drawing software or a processor having a function of analyzing and processing graphic information. Specifically, the drawing unit 21 establishes a time-to-illness mapping table according to the patient illness state level identifier as a different mark, for example, by a different color identifier, and draws a oscillogram of the patient illness state level and time according to the corresponding relationship of the mapping mark, and sends the oscillogram to the display device, so that a doctor can quickly and accurately monitor the patient electrocardiographic data condition, and efficient diagnosis of the patient is realized.

As shown in fig. 5, in an embodiment, the wearable device electrocardiographic real-time monitoring system further includes: and the doctor shift exchanging module 40 is configured to respond to the shift exchanging request according to the target electrocardiogram data in the shift exchanging request sent by the doctor end.

The doctor shift exchanging module 40 may be implemented by a client or a mobile terminal connected to the wearable device 10 for communication and equipped with a liu browser, and is configured to respond to the shift exchanging request according to the target electrocardiographic data in the shift exchanging request sent by the doctor.

In one embodiment, the process of the physician to physician shift between the physician and the first physician is: if the doctor A wants to initiate shift change behavior, the doctor shift change module 40 queries whether the doctor A has a medical record being monitored currently; if not, the shift change behavior is ended; if yes, returning a corresponding medical record list: the medical record monitoring method comprises the steps of acquiring medical record ID, patient information, monitoring duration, remaining monitoring duration and the like, then inquiring the doctor ID of a doctor A, and acquiring a corresponding monitoring center (name and ID); then inquiring whether a doctor starts to take a shift in the monitoring center; if not, ending the shift change behavior; if yes, returning the ID of the corresponding shift-receiving doctor and the information of the doctor; then, the medical record (part or all) monitored by the doctor A and the doctor who takes a shift are selected by the doctor A to generate a shift task, and the shift task is sent to the server; the server generates a message according to the shift task, sends the message to the shift-receiving doctor, and pops up a dialog box at the client of the shift-receiving doctor for display: monitoring the information of each patient in the task for a long time; and finally, the doctor A waits for the information of the server about the shift-changing task, and obtains a shift-changing result if the information is: if the opposite doctor accepts, transferring the medical records to be handed over by the first doctor to the second doctor, so that the medical records in the monitoring list of the first doctor are less, and the medical records in the monitoring list of the second doctor are more; if no message comes within the specified time, the shift register quits overtime or the other party refuses, and the shift change action is cancelled.

The doctor shift exchanging module 40 is configured to respond to the shift exchanging request according to the target electrocardiographic data in the shift exchanging request sent by the doctor end, so that the doctor can conveniently exchange shifts, the working flexibility of the doctor is improved, and the efficiency of doctor management work is also improved.

As shown in fig. 6, in an embodiment, a wearable device electrocardiograph real-time monitoring method is provided, which is applied to a wearable device, and the wearable device electrocardiograph real-time monitoring method can be applied to both a terminal and a server, and specifically includes the following steps:

step 102, obtaining initial electrocardiogram data of a first stage of a patient wearing the wearable device.

Specifically, the server side obtains initial electrocardiogram data of a first stage of a patient, which is acquired by the wearable device.

And step 104, performing ST-segment adjustment on the initial electrocardiogram data to obtain target ST data.

The ST-segment adjustment is a processing method for analyzing electrocardiogram data, and target ST data are obtained by performing ST-segment adjustment on initial electrocardiogram data so as to obtain accurate electrocardiogram data based on the target ST data.

And 106, acquiring second-stage target electrocardio data of the patient wearing the wearable device based on the target ST data.

Specifically, the server side obtains target electrocardiogram data of a second stage of the patient wearing the wearable device according to the target ST data, so that real-time monitoring of electrocardiogram of the patient is achieved based on the target electrocardiogram data.

And step 108, displaying the target electrocardiogram data in an ST trend graph mode.

Specifically, the server displays the target electrocardiogram data in an ST trend graph mode, so that real-time monitoring of the electrocardiogram of the patient is achieved.

According to the real-time electrocardio monitoring method for the wearable device, initial electrocardio data of a first stage of a patient wearing the wearable device are obtained; performing ST-segment adjustment on the initial electrocardiogram data to obtain target ST data; obtaining target electrocardiographic data of a second stage of the patient wearing the wearable device based on the target ST data; and the target electrocardiogram data is displayed in an ST trend graph mode, so that real-time monitoring of the electrocardiogram of the patient is realized.

As shown in fig. 7, in an embodiment, the performing ST-segment adjustment on the initial electrocardiographic data to obtain target ST data includes:

and step 104A, acquiring an ISO base line point and an ST point based on the initial electrocardiogram data.

The ISO base line point refers to a flat part of the R wave front surface, and the ST point refers to a position 40ms after the J point. And acquiring an ISO base line point and an ST point through a oscillogram corresponding to the initial electrocardiogram data.

And step 104B, calculating the amplitude difference between the ST point and the ISO base line point.

Specifically, the patient is judged whether or not there is a symptom of medical "myocardial ischemia" by calculating the difference in amplitude (voltage difference) between the ST point and the ISO baseline point. When the amplitude difference is positive, the rising is represented; when the difference is negative, it indicates depression, i.e. a symptom of medical "myocardial ischemia".

Step 104C, determining the target ST data based on the amplitude difference.

Specifically, target ST data are obtained through positive and negative analysis of the amplitude difference, and ST segment adjustment is carried out on the initial electrocardiogram data, so that the target ST data are more visual, and a doctor can conveniently and rapidly and accurately diagnose based on the target ST data.

In the above embodiment, an ISO baseline point and an ST point are obtained from the initial electrocardiographic data; calculating the amplitude difference between the ST point and the ISO base line point; and determining the target ST data based on the amplitude difference, so that the target ST data is more visual, and a doctor can conveniently and rapidly diagnose based on the target ST data.

As shown in fig. 8, in an embodiment, the displaying the target electrocardiographic data by using an ST trend graph includes:

and step 108A, acquiring the target electrocardio data of N patients, wherein N is a natural number larger than 1.

Specifically, the wearable device electrocardio real-time monitoring method can simultaneously monitor target electrocardio data of a plurality of patients in real time, so that the server can acquire the target electrocardio data of the plurality of patients to improve the efficiency of electrocardio monitoring of the patients.

And step 108B, acquiring a reference point from the target electrocardio data.

The datum points refer to critical points of target electrocardiogram data classification, so that classification fitting is carried out on the target data based on the datum points.

And 108C, performing curve fitting on the target electrocardiogram data based on the reference point to obtain a waveform diagram serving as the ST trend diagram.

Specifically, target electrocardiogram data corresponding to time in a oscillogram is fitted according to parameters such as sampling, walking speed and gain of an electrocardiogram waveform and reference points of each patient, if the slope is larger in the fitting process and exceeds a preset threshold, a connecting line between fitting points is changed into a curve until the corresponding target electrocardiogram data can be automatically connected into a line, then the fitted curve is drawn by using a GDI (graphics device interface) to form an ST trend graph, the electrocardiogram data of the patient can be displayed more intuitively and accurately through the ST trend graph, the efficiency of monitoring the electrocardiogram data of the patient is realized, and meanwhile, a doctor can diagnose and early warn in time conveniently.

In the above embodiment, the target electrocardiographic data of N patients is obtained; acquiring a reference point from the target electrocardio data; the target electrocardiogram data is subjected to curve fitting based on the datum points, and the obtained oscillogram is used as the ST trend graph, so that the electrocardiogram data of a patient can be displayed more visually and accurately, the efficiency of monitoring the electrocardiogram data of the patient is realized, and a doctor can diagnose and early warn conveniently in time.

It should be noted that, the wearable device electrocardiograph real-time monitoring system and the wearable device electrocardiograph real-time monitoring method belong to a general inventive concept, and the contents in the wearable device electrocardiograph real-time monitoring system and the wearable device electrocardiograph real-time monitoring method embodiments are mutually applicable.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (1)

1. The utility model provides a wearing formula equipment electrocardio real-time monitoring system which characterized in that, the system includes: the wearable device is in communication connection with the adjusting device and the display device respectively, and the adjusting device is in communication connection with the display device;

the wearable device is used for acquiring initial electrocardiogram data of a patient wearing the wearable device in a first stage and sending the initial electrocardiogram data to the adjusting device, wherein the first stage is a stage in which configuration parameters of the wearable device are default parameters and are not adjusted by the adjusting device;

the adjusting device is configured to perform ST-segment adjustment on the initial electrocardiographic data to obtain target ST data, send the target ST data to the wearable device, and perform ST-segment adjustment on the initial electrocardiographic data to obtain target ST data, and includes: obtaining an ISO base line point and an ST point based on the initial electrocardiogram data, calculating an amplitude difference between the ST point and the ISO base line point, and determining the target ST data based on the amplitude difference;

the adjusting device is further used for receiving the target electrocardio data sent by the wearable device, analyzing the target electrocardio data, converting the target electrocardio data into an ST trend graph, and sending the ST trend graph to the display device for displaying; the adjustment device is further configured to analyze the patient condition level with the wearable device based on the ST trend graph;

the wearable device receives the target ST data, sets the target ST data as an initialization configuration parameter, collects second-stage target electrocardio data of a patient wearing the wearable device based on the initialization configuration parameter, and sends the target electrocardio data to the display device, wherein the second stage is a time period collected after the configuration parameter of the wearable device is adjusted;

the display device is used for receiving the target electrocardiogram data and displaying the target electrocardiogram data;

the wearable device further comprises:

a positioning unit for positioning a real-time position of the patient wearing the wearable device;

the alarm linkage unit is used for linking the 120 emergency system when the disease condition grade exceeds a preset grade, and sending the real-time position to the 120 emergency system;

the scanning unit is used for scanning the two-dimensional code corresponding to the medical record of the patient wearing the wearable device;

the adjusting device further comprises a drawing unit which is used for drawing a waveform chart of the patient disease level and the time according to the patient disease level and sending the waveform chart to the display device.

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