KR102582943B1 - Ecg measurement system and ecg measurement method - Google Patents

Abstract

The electrocardiogram measurement system includes a three-lead electrocardiogram measurement module that includes electrode terminals and measures the electrocardiogram by attaching the electrode terminals to the user's chest; And a server that receives the 3-lead ECG data measured by the 3-lead ECG measurement module and converts it into 12-lead ECG data, wherein the user with the 3-lead ECG measurement module attached to the chest receives the 3-lead ECG data when symptoms occur. When the button on the lead ECG measurement module is clicked, 3-lead ECG data for a certain period including the time of symptom occurrence is transmitted to the server.

Description

Electrocardiogram measurement system and electrocardiogram measurement method {ECG MEASUREMENT SYSTEM AND ECG MEASUREMENT METHOD}

The present invention relates to an electrocardiogram measurement device and an electrocardiogram measurement system using the same. More specifically, the present invention relates to an electrocardiogram measurement device in the form of a wearable device, which measures the electrocardiogram over a long period of time and analyzes the patient's electrocardiogram more accurately based on the measured electrocardiogram data. This relates to an electrocardiogram measurement method for.

As medical technology develops and the aging society progresses, medical technology focusing on diagnosis and prevention is also being developed.

For example, cardiovascular disease is a chronic disease that is difficult to cure once it occurs. Since the cardiovascular condition needs to be continuously measured or managed even after or before the onset, the development of electrocardiogram measurement devices is continuously being conducted.

Specifically, an electrocardiogram is a graphical recording of potentials related to heartbeat on the surface of the body. It is a test for diagnosing circulatory diseases and is often used to diagnose arrhythmia and coronary artery disease. For example, if arrhythmia occurs intermittently, it is not possible to diagnose arrhythmia with just one electrocardiogram test, so it is useful to obtain an electrocardiogram recorded during daily life.

There are two types of devices that measure the electrocardiogram: the Holter monitor and the diagnostic electrocardiogram. The Holter monitor records the electrocardiogram for 24 hours and is used to analyze patterns, and the diagnostic electrocardiograph measures the electrocardiogram with 12 leads and provides comprehensive diagnostic equipment. Used as a diagnostic system.

In the past, it was essential to visit a hospital to directly attach electrodes or sensors to the body to measure the electrocardiogram, which resulted in restrictions on time and location and the inability to detect heart diseases that occur during daily life at an early stage.

To improve this inconvenience, a portable electrocardiogram device (wearable electrocardiogram device) measures and stores an individual's electrocardiogram (ECG) signal, allowing the ECG information measured at the hospital to be confirmed. However, in the case of these portable electrocardiogram devices, there was a problem in that the accuracy of electrocardiogram data was reduced due to the small size and light manufacturing, such as by simplifying the number of measurement electrodes compared to electrocardiogram measuring devices used in hospitals.

Prior Art 1 (Korean Patent No. 10-1739542)

Accordingly, the technical object of the present invention is to provide an electrocardiogram measurement system and method that improves the accuracy of measurement data from a portable electrocardiogram measurement device.

In addition, another object of the present invention is to provide an electrocardiogram measurement system and method that contribute to early detection of the occurrence of heart disease in patients by improving the accuracy of electrocardiogram measurement data of a portable electrocardiogram measurement device.

In order to achieve the above-described object, in one aspect, the present embodiment includes a three-lead electrocardiogram measurement module that includes an electrode terminal and measures an electrocardiogram by attaching the electrode terminal to the user's chest; And a server that receives the 3-lead ECG data measured by the 3-lead ECG measurement module and converts it into 12-lead ECG data, wherein the user with the 3-lead ECG measurement module attached to the chest receives the 3-lead ECG data when symptoms occur. We intend to provide an ECG measurement system that transmits 3-lead ECG data for a certain period including the time of symptom occurrence to the server when the button on the lead ECG measurement module is clicked.

In addition, the server attaches the 3-lead ECG measurement module at the same time as the 12-lead ECG measurement module when the user first attaches it, and receives both 3-lead ECG data and 12-lead ECG data for a certain period including the time of initial attachment. , A conversion equation can be created to convert the received 3-lead ECG data at the time of initial attachment into 12-lead ECG data, and the 3-lead ECG data can be converted into the 12-lead ECG data based on the conversion equation.

In addition, when the server analyzes the 12-lead ECG data converted based on the conversion formula and determines that abnormal symptoms have occurred, it transmits abnormal symptom information to a terminal in the hospital or provides a hospital visit notification to the user's terminal. You can.

In addition, the 3-lead ECG measurement module stores ECG data during the period when the user attached the 3-lead ECG measurement module, and the server stores the 3-lead ECG measurement module when the user returns the 3-lead ECG measurement module. ECG data stored in the lead ECG measurement module can be received and analyzed, and the analyzed ECG information can be displayed on the terminal within the hospital.

In another aspect of the present invention, measuring the electrocardiogram by attaching the electrode terminal of a 3-lead electrocardiogram measurement module including electrode terminals to the user's chest; When the user with the 3-lead ECG measurement module attached to the chest clicks the button on the 3-lead ECG measurement module when symptoms occur, 3-lead ECG data for a certain section including the time of symptom occurrence is transmitted to the server. step; and receiving, by a server, the 3-lead ECG data measured by the 3-lead ECG measurement module and converting it into 12-lead ECG data.

In addition, when the user first attaches the 3-lead ECG measurement module, attaching it simultaneously with the 12-lead ECG measurement module to receive both 3-lead ECG data and 12-lead ECG data for a certain period including the time of initial attachment; Generating a conversion equation for converting the received 3-lead ECG data at the time of initial attachment into 12-lead ECG data; and converting the 3-lead ECG data into the 12-lead ECG data based on the conversion equation.

In addition, when it is determined that abnormal symptoms have occurred by analyzing the 12-lead ECG data converted based on the conversion formula, transmitting abnormal symptom information to a terminal in the hospital or providing a hospital visit notification to the user's terminal; It can be included.

In addition, when the user returns the 3-lead ECG measurement module, the server receives and analyzes the ECG data stored in the 3-lead ECG measurement module, and displays the analyzed ECG information on the terminal in the hospital. It can be included.

According to another aspect of the present invention, the electrode terminal of the 3-lead ECG measurement module is attached to the user's chest to receive measured 3-lead ECG data, and the user connects the 3-lead ECG measurement module to a 12-lead ECG measurement module. When attached at the same time, both 3-lead ECG data and 12-lead ECG data for a certain period including the time of initial attachment are input, and a conversion formula is generated to convert the received 3-lead ECG data at the time of initial attachment into 12-lead ECG data. In addition, a recording medium storing a computer program that operates an electrocardiogram measurement system that converts the 3-lead electrocardiogram data into the 12-lead electrocardiogram data based on the conversion formula and displays it on a terminal in the hospital can be provided.

In addition, when the user returns the 3-lead ECG measurement module, the ECG measurement system is operated to receive and analyze the ECG data stored in the 3-lead ECG measurement module and display the analyzed ECG information on the terminal in the hospital. You can.

According to the electrocardiogram measurement system and method according to embodiments of the present invention, it may be possible to synthesize data measured through a portable electrocardiogram measurement device with a small number of leads into electrocardiogram data based on a 12-lead electrocardiogram measurement device used in hospitals. there is. Therefore, the accuracy of measurement data of the portable electrocardiogram measurement device can be improved.

In addition, the accuracy of electrocardiogram measurement data from portable electrocardiogram measurement devices can be improved, and accurate judgments about abnormal symptoms can be made, thereby preventing the occurrence of heart disease in patients.

However, the effects of the present invention are not limited to the above effects, and may be expanded in various ways without departing from the spirit and scope of the present invention.

1 is a block diagram of an electrocardiogram measurement system and an external terminal according to an embodiment of the present invention.
Figure 2 is a schematic diagram explaining a method of using a 3-lead ECG measurement module and a 12-lead ECG measurement module according to an embodiment of the present invention.
Figure 3 is a graph showing 3-lead ECG measurement data synthesized into 12-lead ECG measurement data according to an embodiment of the present invention.
Figure 4 is a flowchart showing a method for initially setting up data from a 3-lead ECG measurement module to be converted into data from a 12-lead ECG measurement module according to an embodiment of the present invention.
Figure 5 is a flowchart showing a method of operating an electrocardiogram measurement system according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

Since the present invention can be subject to various changes and have various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Figure 1 is a block diagram for explaining the relationship between an electrocardiogram measurement system, a 12-lead electrocardiogram measurement module installed in a hospital, and a terminal according to an embodiment of the present invention, and Figure 2 is a 3-lead electrocardiogram according to an embodiment of the present invention. This is a schematic diagram explaining how to use the measurement module and 12-lead ECG measurement module.

Before explaining the configuration of the ECG measurement system 1 included in FIG. 1, the terminal 300 and the 12-lead ECG measurement module 400 shown in FIG. 1 will be briefly described.

The terminal 300 includes a display unit 330 that displays data like a monitor (screen), a communication unit 340 that receives data by wire or wirelessly, an input unit 310 that receives data through the communication unit, and each component as a whole. It includes a control unit 320 that controls. For example, this may include a terminal containing a monitor used by a doctor in a hospital or by ECG staff in an ECG room.

Next, the 12-lead (lead) electrocardiogram measurement module 400 uses 10 electrodes. The electrodes usually consist of a conductive gel and are attached to an adhesive pad.

A 12-lead electrocardiogram measurement includes twelve leads (leads): the standard leads (I, II, III), which record the electrocardiogram of the heart in the frontal plane, the limb leads (aVR, aVL, aVF), and the horizontal plane. (horizontal plane) Includes thoracic leads (V1, V2, V3, V4, V5, V6) that record the electrocardiogram of the heart.

Electrodes are connected to the right hand (RA), left hand (LA), left foot (LL), and right foot (RL) to record standard leads and limb leads, and six electrodes are attached to designated positions on the chest to record chest leads. do.

The ECG graph measured by the 12-lead ECG measurement module 400 can be checked by a user (doctor, etc.) through the display 410 included in the 12-lead ECG measurement module. An ECG graph measured with a 12-lead ECG measurement module may appear as shown in (b) of FIG. 3.

Therefore, 10 electrodes of the 12-lead electrocardiogram measurement module 400 in the hospital are attached to both arms, legs, and chest of the patient to measure the electrocardiogram, and the electrocardiogram measurement data is transmitted to the terminal 300.

At this time, the transmitted data may be transmitted in the form of an XML (Extensible Markup Language) file.

Hereinafter, the configuration of the electrocardiogram measurement system 1 according to the present invention will be described in detail.

The electrocardiogram measurement system 1 according to the present invention includes a 3-lead electrocardiogram measurement module 100 and a server 200.

The 3-lead electrocardiogram measurement module 100 may include a communication unit 110, a control unit 120, a button unit 130, and an electrode terminal 140. This 3-lead ECG measurement module 100 is attached to the chest to measure the ECG in daily life. In order to calculate the 3-lead ECG (I, II, III), the electrode terminal 140 is connected to at least three electrodes. may include. Meanwhile, in order to measure a 3-lead electrocardiogram, the position of the electrode is not absolutely fixed, and it is possible to specify the position of the electrode by attaching the 3-lead electrocardiogram measurement module 100 to an appropriate location on the chest structurally. do.

For example, the 3-lead electrocardiogram measurement module 100 may be directly attached in the form of a patch in which a plurality of electrodes are formed collectively on one sheet so that the plurality of electrodes can be collectively attached to the chest, and thus 3-lead electrocardiogram measurement The module 100 receives electrical signals from electrodes, processes them, and transmits them to the outside. That is, the 3-lead electrocardiogram measurement module 100 measures and stores the electrocardiogram signal of the user or patient and transmits it to the server 200.

A 3-lead electrocardiogram can be measured using four electrodes, and the measured data can be transmitted to the terminal 300 or the server 200.

Next, the button unit 130 is a terminal provided to click or push the corresponding button when the patient has symptoms during daily life. Regarding this, although specific drawings are not included, as shown in FIG. 2, when the 3-lead electrocardiogram measurement module 100 is attached to the patient's chest, the electrode terminal 140 may be located on the surface in contact with the chest, and The button portion 130 may be located on the side or top surface excluding the contact surface.

When symptoms occur, the patient clicks or pushes the button on the button unit 130. Accordingly, when the patient's click or push input is input, the button unit 130 can transmit information that a symptom has occurred and ECG data at the time of symptom occurrence to the server 200 through the communication unit 110.

The communication unit 110 may include one or more components that enable communication between the 3-lead ECG measurement module 100 and the terminal 300, or between the 3-lead ECG measurement module 100 and the server 200. . For example, it may include at least one of a short-range communication module, a wired communication module, and a wireless communication module.

The short-range communication module transmits signals using a wireless communication network at a short distance, such as a Bluetooth module, infrared communication module, RFID (Radio Frequency Identification) communication module, WLAN (Wireless Local Access Network) communication module, NFC communication module, and Zigbee communication module. It may include various short-range communication modules that transmit and receive. Accordingly, the communication unit 110 is capable of transmitting and receiving data to the short-range communication module when a patient uses the 3-lead electrocardiogram measurement module 100 near the terminal 300 in an electrocardiogram room in a hospital.

Wired communication modules include a variety of wired communication modules, such as Controller Area Network (CAN) communication modules, Local Area Network (LAN) modules, Wide Area Network (WAN) modules, or Value Added Network (VAN) modules. In addition to communication modules, various cable communications such as USB (Universal Serial Bus), HDMI (High Definition Multimedia Interface), DVI (Digital Visual Interface), RS-232 (recommended standard232), power line communication, or POTS (plain old telephone service) Can contain modules. Accordingly, the communication unit 110 is also capable of transmitting and receiving data through a wired connection when a patient uses the 3-lead electrocardiogram measurement module 100 near the terminal 300 in an electrocardiogram room in a hospital.

In addition to Wi-Fi modules and WiBro (Wireless broadband) modules, wireless communication modules include GSM (global System for Mobile Communication), CDMA (Code Division Multiple Access), WCDMA (Wideband Code Division Multiple Access), and UMTS (universal mobile telecommunications system). ), TDMA (Time Division Multiple Access), and LTE (Long Term Evolution) may include a wireless communication module that supports various wireless communication methods.

The wireless communication module may include a wireless communication interface including an antenna and a transmitter that transmits a signal to the terminal 300 or the server 200. In addition, the wireless communication module may further include a signal conversion module that modulates a digital control signal output from the control unit 120 through a wireless communication interface into an analog wireless signal under the control of the control unit 120.

The wireless communication module may include a wireless communication interface including an antenna and a receiver that receives signals from the terminal 300 or the server 200. Additionally, the wireless communication module may further include a signal conversion module for demodulating an analog wireless signal received through a wireless communication interface into a digital control signal.

The control unit 120 generally controls the 3-lead electrocardiogram measurement module 100. In addition, although not shown in FIG. 1, the control unit 120 additionally includes a storage unit and stores ECG data measured by the 3-lead ECG measurement module 100. At this time, the storage unit can be set to store data on the SD card by inserting a separate SD card into the 3-lead ECG measurement module 100.

In other words, the storage unit consists of non-volatile memory elements such as cache, ROM (Read Only Memory), PROM (Programmable ROM), EPROM (Erasable Programmable ROM), EEPROM (Electrically Erasable Programmable ROM), and flash memory, or RAM (Random Memory). It may be implemented as at least one of a volatile memory device such as Access Memory) or a storage medium such as a hard disk drive (HDD) or CD-ROM, but is not limited thereto.

That is, the storage unit may be a memory implemented as a separate chip from the control unit 120 described above, or may be implemented as a single chip with the processor.

In addition, when the first patient attaches the 3-lead ECG measurement module 100 at the same time as the 12-lead ECG measurement module 400, the control unit 120 monitors the ECG data measured by the 3-lead ECG measurement module 100. Controls transmission to the terminal 300.

In addition, when the patient attaches the 3-lead electrocardiogram measurement module 100 in his/her daily life, the control unit 120 measures the pulse for 1 minute at a predetermined time interval a predetermined number of times (for example, once every 24 hours). The ECG data can be transmitted to the server 200.

Additionally, the control unit 120 stores electrocardiogram data measured in real time. The amount of available data may vary depending on the storage capacity of the storage unit, but ECG data for at least a week (7 days) to approximately up to 20 days during which the patient is attaching the 3-lead ECG measurement module 100. You can save it.

In the above, the configuration of the 3-lead electrocardiogram measurement module 100 of the electrocardiogram measurement system 1 has been described.

Below, the configuration and operation of the server 200 of the electrocardiogram measurement system 1 will be described.

The server 200 includes a communication unit 210, a storage unit 220, and a control unit 230.

The communication unit 210 configured within the server 200 is configured to enable communication with the 3-lead ECG measurement module 100 or the terminal 300, as described in the communication unit 110 of the 3-lead ECG measurement module 100. As shown, it may include wired communication, wireless communication, and short-distance communication modules, and detailed description is omitted.

The storage unit 220 includes a memory element and receives and stores ECG data measured by the 3-lead ECG measurement module 100 and the 12-lead ECG measurement module 400.

In addition, ECG data synthesized by the operation of the control unit 230, which will be described later, can also be stored separately.

Next, the control unit 230 can comprehensively control the operation of the server 200.

The control unit 230 of the server 200 generates 3-lead ECG data based on the 3-lead ECG data received from the 3-lead ECG measurement module 100 and the ECG data received from the 12-lead ECG measurement module 400. Convert to 12-lead ECG data.

That is, the 3-lead ECG data includes only 3 channels of ECG data, but can be converted into 12 channels of ECG data based on a preset conversion formula included in the control unit 230 of the server 200.

However, the server 200 may generate a different conversion formula for each patient. As shown in FIG. 2, the conversion equation can be finally generated when the first patient secures ECG data by attaching both the 3-lead ECG measurement module 100 and the 12-lead ECG measurement module 400. . For example, when converting 3-channel ECG data measured by the 3-lead ECG measurement module 100 of Patient 1 into 12-channel ECG data, the coefficients included in the conversion equation can be obtained as a1, a2, a3, etc. Alternatively, when converting the 3-channel ECG data measured by the 3-lead ECG measurement module 100 of Patient 2 into 12-channel ECG data, the coefficients included in the conversion equation may be obtained as b1, b2, b3, etc.

That is, in the step of attaching both the 3-lead ECG measurement module 100 and the 12-lead ECG measurement module 400 by the first patient in FIG. 2, the acquired 3-lead ECG data is sent to the server 200 as a 12-lead ECG data. This is a procedure for creating a conversion equation based on ECG data.

Specifically, Figure 3 is a graph in which 3-lead ECG measurement data is synthesized into 12-lead ECG measurement data according to an embodiment of the present invention.

As in Figure 3 (a), the ECG data of the three channels (leads) is as shown in Figure 3 (b), standard leads (I, II, III), limb leads (aVR, aVL, aVF), and It can be synthesized into 12-channel ECG data including thoracic leads (V1, V2, V3, V4, V5, V6) that record the ECG of the heart in the horizontal plane.

In this way, the 12-channel ECG data synthesized in the control unit 230 of the server 200 can be displayed and confirmed on the display unit 330 of the terminal 300 in the hospital through the communication unit 210.

Unlike what was explained based on FIGS. 1 to 3, the method for converting 3-channel ECG data into 12-channel ECG data is a program, and can also be operated within the terminal 300. Therefore, the terminal 300 receives ECG data from the 3-lead ECG measurement module 100 and the terminal 300 simultaneously receives ECG data from the 12-lead ECG measurement module 400 to generate an individual conversion formula for each patient. And, based on the generated conversion equation, the patient's 3-lead electrocardiogram measurement data can be synthesized into 12-channel electrocardiogram data, and may be operated as a computer program stored in the medium by combining it with a recording medium or hardware storing a computer program.

Figure 4 is a flowchart showing a method for initially setting up data from a 3-lead ECG measurement module to be converted into data from a 12-lead ECG measurement module according to an embodiment of the present invention.

First, the user (hospital official) attaches both the 3-lead ECG module 100 and the 12-lead ECG module 400 to the patient (A1) (S400).

Afterwards, the user receives both the 12-lead ECG measurement data (d1) of the 12-lead ECG module 400 and the 3-lead ECG data (d2) measured by the 3-lead ECG module 100 through the terminal 300 used by the user. (S410 and S420).

Thereafter, the 3-lead ECG data (d2) is synthesized into 12-lead data based on the 12-lead ECG measurement data (d1) (S430). That is, the 3-lead ECG data is converted into 12-lead data based on the data received while the patient (A1) is attaching both the 3-lead ECG module 100 and the 12-lead ECG module 400, and ultimately, the patient Create an individual conversion equation (eq1) of (A1) (S440).

Specifically, when generating the individual conversion equation (eq1) of the patient (A1), the terminal 300 receiving each data transmits the data to the server 200 to generate the individual conversion equation (eq1) generated by the server 200. And the terminal 300 can again receive the synthesized 12-lead ECG data according to the individual conversion formula.

Alternatively, when generating the individual conversion equation (eq1) of the patient (A1), the terminal 300 that has received each data operates the program stored in the terminal 300 in advance and generates the individual conversion equation (eq1) and the individual conversion equation. It is also possible to obtain synthesized 12-lead ECG data.

Figure 5 is a flowchart showing a method of operating an electrocardiogram measurement system according to an embodiment of the present invention.

Specifically, Figure 5 shows that an individual conversion equation (eq1) has already been created for the patient (A) by the method of Figure 4, and the patient (A) lives with the 3-lead electrocardiogram module (100) attached to the chest. It is assumed that symptoms appear on the first day.

The 3-lead electrocardiogram module 100 attached to the patient (A) is hereinafter referred to as a module. The module a measures the electrocardiogram of the patient (A) (S510). If the patient develops symptoms while living with a module attached, when the patient (A) clicks the button on the a module (S520), ECG data for a preset time interval at the time of clicking the button is sent to the server ( 400).

When the server 200 receives the ECG data (S540), it analyzes the ECG data (S550). At this time, the ECG data received by the server 200 is 3-lead ECG data, and not only is it converted into 12-lead ECG data based on a pre-generated individual conversion equation (eq1), but also the converted ECG data and the received 3-lead ECG data are converted into 12-lead ECG data. It includes analyzing whether there is a graph pattern including abnormal symptoms in the ECG data (S550). At this time, a graph containing abnormal symptoms refers to a case where there is a graph pattern that is judged to be arrhythmia, tachycardia, etc.

Afterwards, the server 200 transmits the analyzed ECG data to the terminal 300 in the hospital (S560) and displays it to the user in the hospital (S590). In this case, information displayed to users in the hospital may include 3-lead ECG data, converted ECG data, and judgment information on whether abnormal symptoms are analyzed by the server. At this time, the step (S600) consisting of S560 and S590 can be controlled by the operation of the electrocardiogram measurement system 1 according to the present invention even in an environment where remote medical treatment is not permitted. This may be meaningful in confirming whether the analyzed graph actually had symptoms or not when the patient later visited the hospital.

Alternatively, if the server 200 determines that the symptoms are abnormal as a result of analyzing the ECG data (S570), it may provide a visit notification to the patient (580). Step S610, consisting of S570 and S590, can be controlled by the operation of the electrocardiogram measurement system 1 according to the present invention in an environment where remote medical treatment is permitted.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention shall be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope shall be construed as being included in the scope of rights of the present invention.

Claims (10)

a three-lead electrocardiogram measurement module that includes electrode terminals and measures the electrocardiogram by attaching the electrode terminals to the user's chest; and
A server that receives 3-lead ECG data measured by the 3-lead ECG measurement module and converts it into 12-lead ECG data,
The 3-lead ECG measurement module, when the user who attaches the 3-lead ECG measurement module to the chest clicks the button of the 3-lead ECG measurement module when symptoms occur, 3 signals in a certain section including the time of symptom occurrence are sent to the server. Transmit lead ECG data to the server,
When the user first attaches the 3-lead ECG measurement module, the server attaches it simultaneously with the 12-lead ECG measurement module and receives both 3-lead ECG data and 12-lead ECG data for a certain period including the time of initial attachment,
Generate a conversion equation to convert the received 3-lead ECG data at the time of initial attachment into 12-lead ECG data,
Converting the 3-lead ECG data into the 12-lead ECG data based on the conversion formula,
The server analyzes the 12-lead ECG data converted based on the conversion formula to see whether there is a graph pattern including abnormal symptoms, and if the analysis results include abnormal symptom information, transmits the abnormal symptom information to a terminal in the hospital, or An electrocardiogram measurement system, characterized in that it provides a hospital visit notification to the user's terminal. delete delete According to paragraph 1,
The 3-lead electrocardiogram measurement module,
Stores ECG data during the period when the user attached the 3-lead ECG measurement module,
The server receives and analyzes ECG data stored in the 3-lead ECG measurement module when the user returns the 3-lead ECG measurement module, and displays the analyzed ECG information on a terminal in the hospital. Measuring the electrocardiogram by attaching the electrode terminal of a 3-lead electrocardiogram measurement module including electrode terminals to the user's chest;
When the user with the 3-lead ECG measurement module attached to the chest clicks the button on the 3-lead ECG measurement module when symptoms occur, 3-lead ECG data for a certain section including the time of symptom occurrence is transmitted to the server,
When the user first attaches the 3-lead ECG measurement module, the server attaches it simultaneously with the 12-lead ECG measurement module and receives both 3-lead ECG data and 12-lead ECG data for a certain period including the time of initial attachment,
Generate a conversion equation to convert the received 3-lead ECG data at the time of initial attachment into 12-lead ECG data,
Converting the 3-lead ECG data into the 12-lead ECG data based on the conversion formula,
The server analyzes the 12-lead ECG data converted based on the conversion formula to see whether there is a graph pattern including abnormal symptoms, and if the analysis results include abnormal symptom information, transmits the abnormal symptom information to a terminal in the hospital, or An electrocardiogram measurement method comprising: providing a hospital visit notification to the user's terminal. delete delete According to clause 5,
When the user returns the 3-lead ECG measurement module, the server receives and analyzes the ECG data stored in the 3-lead ECG measurement module, and displays the analyzed ECG information on the terminal in the hospital; further comprising: How to measure electrocardiogram. Attach the electrode terminal of the 3-lead ECG measurement module to the user's chest to receive the measured 3-lead ECG data.
When the user attaches the 3-lead ECG measurement module and the 12-lead ECG measurement module at the same time, both 3-lead ECG data and 12-lead ECG data for a certain period including the time of initial attachment are input,
Generate a conversion equation to convert the received 3-lead ECG data at the time of initial attachment into 12-lead ECG data,
When the user who attaches the 3-lead ECG measurement module to the chest clicks the button of the 3-lead ECG measurement module when symptoms occur, the 3-lead ECG data is received from the 3-lead ECG measurement module and the 3-lead ECG data is received based on the conversion formula. The operation of converting to 12-lead ECG data, analyzing the converted 12-lead ECG data based on the conversion formula to see if there is a graph pattern containing abnormal symptoms, and displaying it on a terminal in the hospital if the analysis results contain abnormal symptom information. A program stored on a computer-readable recording medium for execution. delete

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