KR102669215B1 - apparatus and method of electrocardiogram - Google Patents

Abstract

In the method of measuring an electrocardiogram by the electrocardiogram measuring device of the present invention, the electrocardiogram measuring device includes a housing forming an internal space, a control unit accommodated in the internal space, coupled to the housing, and receiving a potential signal from the body of the person being measured. First to third electrodes that receive input, an external input unit formed in the housing and receiving a potential signal measured outside the housing, and an external input unit formed separately from the housing and receiving a potential signal from the body of the person being measured. 1. A first external electrode unit that can be coupled to an external electrode and the external input unit and includes a first connection unit capable of transmitting a potential signal received by the first external electrode to the external input unit, and the method includes: Determining whether the first external electrode unit is coupled to the external input unit, if it is determined that the first external electrode unit is coupled to the external input unit, at least one measurement capable of measuring an electrocardiogram using the first external electrode Providing a first option including a mode, if it is determined that the first external electrode unit is not coupled to the external input unit, including at least one measurement mode capable of measuring an electrocardiogram without using the first external electrode. providing a second option, receiving selection information selected by the user for one of the first option and the second option, and determining one measurement mode according to the selection information as a motion measurement mode, Receiving a potential signal through at least one electrode used in the motion measurement mode among the first to third electrodes and the first external electrode, transferring the potential signal received in the input step to the motion measurement mode An electrocardiogram measurement method comprising calculating electrocardiogram measurement results by processing them using a predetermined signal processing method, and providing the electrocardiogram measurement results.

Description

Electrocardiogram measuring device and method {apparatus and method of electrocardiogram}

This technology relates to a method for an electrocardiogram measuring device to measure an electrocardiogram.

Recently, it is possible to conveniently diagnose a patient's heart condition through an electrocardiogram (ECG) device. The presence or absence of heart abnormalities can be confirmed through electrocardiogram measurement, and it is a basic indicator considered for diagnosing cardiovascular diseases such as arrhythmia, cardiomyopathy, valvular disease, and heart failure.

Among various electrocardiogram measurement devices, hospital electrocardiogram devices use a 12-channel electrocardiograph using 10 wet electrodes as standard. Hospital electrocardiogram devices can measure detailed heart conditions, but they can only be used when the user visits a hospital. Additionally, the user feels uncomfortable during the measurement process due to the use of a large number of electrodes. For this reason, a simplified electrocardiogram measurement device is sometimes used. A simplified ECG measurement device can measure the ECG using fewer electrodes than a hospital ECG device. Specifically, the simplified ECG measurement device can conveniently measure the ECG using only 6 channels with 3 electrodes or 8 channels with 4 electrodes.

However, although the conventional simplified ECG measurement device reduces the discomfort felt by the user during the measurement process, there is a problem in that the measurement results are relatively less accurate than hospital ECG devices.

Accordingly, there is an increasing demand for an ECG measurement device that simply measures the ECG using a simplified ECG measurement device and produces more accurate results than existing simplified ECG measurement devices.

Republic of Korea Patent Publication No. 10-2020-0001823 (Publication date: January 7, 2020, Title of invention: Electrocardiogram measurement method and system using a wearable device)

The purpose of the electrocardiogram measurement method of the present invention is to provide options for measuring electrocardiograms depending on the type of electrode.

In addition, the purpose of the electrocardiogram measurement method of the present invention is to measure the electrocardiogram using electrodes suitable for the selected electrocardiogram measurement method of the electrocardiogram measurement device.

In the method of measuring an electrocardiogram by the electrocardiogram measuring device of the present invention, the electrocardiogram measuring device includes a housing forming an internal space, a control unit accommodated in the internal space, coupled to the housing, and receiving a potential signal from the body of the person being measured. First to third electrodes that receive input, an external input unit formed in the housing and receiving a potential signal measured outside the housing, and an external input unit formed separately from the housing and receiving a potential signal from the body of the person being measured. 1. A first external electrode unit that can be coupled to an external electrode and the external input unit and includes a first connection unit capable of transmitting a potential signal received by the first external electrode to the external input unit, the method comprising: Determining whether the first external electrode unit is coupled to the external input unit, if it is determined that the first external electrode unit is coupled to the external input unit, at least one measurement capable of measuring an electrocardiogram using the first external electrode Providing a first option including a mode, if it is determined that the first external electrode unit is not coupled to the external input unit, including at least one measurement mode capable of measuring an electrocardiogram without using the first external electrode. providing a second option, receiving selection information selected by the user for one of the first option and the second option, and determining one measurement mode according to the selection information as a motion measurement mode, Receiving a potential signal through at least one electrode used in the motion measurement mode among the first to third electrodes and the first external electrode, transferring the potential signal received in the input step to the motion measurement mode It includes calculating electrocardiogram measurement results by processing them using a predetermined signal processing method, and providing the electrocardiogram measurement results.

The electrocardiogram measuring device of the present invention is formed separately from the housing and can be coupled to a second external electrode and the external input unit that receive a potential signal from the body of the subject, and the potential received by the second external electrode Further comprising a second external electrode unit including a second connection unit capable of transmitting a signal to the external input unit, the method comprising: determining whether the second external electrode unit is coupled to the external input unit; When it is determined that the electrode unit is coupled to the external input unit, providing a third option including at least one measurement mode capable of measuring an electrocardiogram using the second external electrode, for any one of the third options Receiving selection information selected by the user and determining one measurement mode according to the selection information as an operation measurement mode, at least one of the first to third electrodes and the second external electrode used in the operation measurement mode It may further include receiving a potential signal through one electrode.

In the electrocardiogram measuring device of the present invention, when one of the first external electrode unit and the second external electrode unit is coupled to an external input unit, the other may not be coupled.

In the electrocardiogram measuring device of the present invention, the first external electrode of the first external electrode unit may be formed in the form of at least one of a clamp, a band, a patch, and a strap in order to receive the potential signal from one of the limbs. there is.

In the electrocardiogram measuring device of the present invention, the second external electrode of the second external electrode unit may be formed in the form of at least one of a chest ball, Velcro, and pad in order to receive the electric potential signal from the chest.

In the electrocardiogram measuring device of the present invention, the first electrode and the second electrode may be coupled to the front of the housing to be spaced apart from each other, and the third electrode may be coupled to the rear of the housing.

The electrocardiogram measuring device of the present invention further includes a display, and the method may further include outputting at least one of the first to third options to the display.

The electrocardiogram measuring device of the present invention includes a communication unit capable of communicating with an external device, and the method includes selecting at least one of the first to third options to the external device through the communication unit. A step of transmitting information may be further included.

The method of the present invention is performed when the first external electrode unit is combined and the first external electrode unit replaces any one of the first electrode to the third electrode, any one of the first electrode to the third electrode. A step of deactivating may be further included.

The electrocardiogram measurement method of the present invention has the advantage of providing options for measuring electrocardiograms depending on the type of electrode.

Additionally, the electrocardiogram measurement method of the present invention has the advantage of being able to measure the electrocardiogram using electrodes suitable for the selected electrocardiogram measurement method of the electrocardiogram measurement device.

Figure 1 shows an electrocardiogram device according to an embodiment of the present invention.
Figure 2 is a diagram for explaining an embodiment of the electrocardiogram measurement method according to the present invention.
Figure 3 shows an electrocardiogram device according to another embodiment of the present invention.
Figure 4 is a diagram for explaining another embodiment of the electrocardiogram measurement method according to the present invention.
Figure 5 is an exemplary diagram to explain an embodiment in which selection information is output to a display or an external device of the present invention.

Hereinafter, embodiments disclosed in the present specification will be described in detail with reference to the attached drawings. However, identical or similar components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted. Additionally, in describing the embodiments disclosed in this specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed descriptions will be omitted.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

Singular expressions include plural expressions unless the context clearly dictates otherwise.

In this application, each step described may be performed regardless of the listed order, except when it must be performed in the listed order due to a special causal relationship.

In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, an embodiment of the present invention will be described with reference to FIG. 1.

Figure 1 shows an electrocardiogram device according to an embodiment of the present invention.

Referring to Figure 1, the electrocardiogram measuring device of the present invention includes a housing 10, a control unit (not shown), a first electrode 200, a second electrode 300, a third electrode 400, an external input unit 20, and Includes a first external electrode unit 500.

The housing 10 forms an internal space that accommodates various components. The housing 10 may be formed in a dumbbell shape. The internal space formed by the housing 10 may have an open top. The upper part of the internal space may be covered by a display to be described later. The first electrode 200 and the second electrode 300 may be connected to the front of the housing 10. A third electrode 400 may be connected to the rear of the housing 10. In some cases, the first to third electrodes 200 to 400 may be part of the housing 10 or may be formed to be inserted into the housing 10.

The housing 10 includes an external input unit 20. The external input unit 20 is formed outside the housing 10. The external input unit 20 may be formed in the form of a receiver or port inserted into the housing 10. The first external electrode unit 500, which is formed separately from the housing 10, may be coupled to the housing 10 through the external input unit 20. When the external input unit 20 is a port, the housing 10 and the first external electrode unit 500 may be connected with a wired cable. Specifically, the external input unit 20 may be formed of a USB port, 3.5 pie terminal, DC port, etc.

On the other hand, when the external input unit 20 is a receiver, the housing 10 and the first external electrode unit 500 can be wirelessly coupled. Through the combination of the external input unit 20 and the first external electrode unit 500, a potential signal measured in a device formed separately from the housing 10 can be received.

Although not shown in FIG. 1, the housing 10 may include a display and a control unit. Specifically, the display may be coupled to the front of the housing 10. The display is formed in a plate shape and is the part that comes into contact with the sensing object. Through the display, options according to the electrocardiogram measurement method, which will be described later, can be output. The display may include a circuit structure and a chipset that can detect the touch of the sensed object. The specific structure of this circuit structure and chipset may be determined by a capacitive method, a pressure-sensitive method, etc., but since this corresponds to a structure already known in the related art, a detailed description will be omitted.

The communication unit may be located in the internal space of the housing 10. The communication unit is formed of a chipset and can communicate with external devices. Specifically, through the communication unit, information on at least one of the first to third options to be described later can be transmitted to a separate external device that is separate from the electrocardiogram measuring device, and the measured potential signal can be transmitted and received.

The control unit is present inside the housing 10. The control unit may calculate electrocardiogram measurement results through the potential signals of the subject being measured that are input from the first electrode 200 to the third electrode 400 and the first external electrode 520 unit 500. Additionally, the electrocardiogram measurement method, which will be described later, can be controlled through the control unit.

The display of the electrocardiogram measuring device of the present invention can detect actions such as the position, movement, or pressing of the sensed object. Therefore, when the sensed object selects a given option, the received information is transmitted to the control unit, and the control unit operates the ECG measurement device in a single mode based on the received input information.

The first electrode 200 to the third electrode 400 are coupled to the housing 10. The first electrode 200 to the third electrode 400 may be at least one of a dry electrode or a wet electrode. As in the embodiment of FIG. 1, the first electrode 200 to the third electrode 400 may be formed as part of the housing 10. When formed as part of the housing 10, the electrocardiogram sensing device can receive a potential signal by directly contacting the body part of the subject with the first electrode 200 to the third electrode without a separate cable. The first electrode 200 to the third electrode 400 may be inserted into the housing 10 .

When the first connection part 510 of the first external electrode part 500, which will be described later, is coupled to the external input part 20 formed in the housing 10, the potential signal received by the third electrode 400 is connected to the first external electrode. The first external electrode 520 of the unit 500 may be replaced with an input potential signal. When the role of the third electrode 400 is replaced by the first external electrode unit 500, the third electrode 400 is deactivated, and by deactivating the third electrode 400, noise is generated in the process of receiving the potential signal. can be suppressed, malfunctions can be prevented, and unnecessary power consumption can be prevented. Additionally, the third electrode 400 may be inserted into the interior of the housing 10 in the deactivation step.

In another embodiment, the first electrode 200 to the third electrode 400 may include a cable extending from the housing 10. In the case of a type including a cable, the person being measured can directly attach the first electrode 200 to the third electrode 400 to the body part where the potential signal is to be measured so that the ECG sensing device can receive the potential signal. The electrocardiogram measuring device of the present invention is not limited to the combination of electrodes described above.

The electrocardiogram measuring device can receive a potential signal according to the heartbeat of the subject by contacting, adhering to, or attaching the above-mentioned electrodes to the body of the subject. Electrocardiogram measurement results can be calculated through the input potential signal. In order to calculate electrocardiogram measurement results, a potential difference input signal received from at least two or more electrodes is required.

The first external electrode unit 500 includes a first external electrode 520 and a first connection part 510. The first external electrode unit 500 is formed separately from the housing 10. The first external electrode 520 of the first external electrode unit 500 is formed in the form of at least one of clips, a band, a patch, and a strap. Accordingly, the first external electrode can receive a potential signal from one of the limbs. For example, if you want to measure electric potential signals from one of the limbs, it can be formed in the form of a pincer or strap.

In this way, depending on which part of the limb receives the electric potential signal, the first external electrode is formed in an appropriate one of the above-described forms. The first connection part 510 is connected to the first external electrode 520 and includes a cable. A portion of the extreme end of the first connection portion 510 is formed in a shape corresponding to the external input portion 20. Specifically, when the external input unit 20 is a port, it is formed in the same shape as the corresponding insertion unit. Specifically, it can be formed with a USB socket, 3.5 pi jack, DC connector, etc. On the other hand, when the external input unit 20 is in the form of a receiver, it is formed in the same form as the corresponding antenna sensor.

Hereinafter, an embodiment of the present invention will be described with reference to FIG. 2.

Figure 2 is a diagram for explaining an embodiment of the electrocardiogram measurement method according to the present invention.

In step S210, the ECG measurement device determines whether the first external electrode unit 500 is coupled to the external input unit 20. Specifically, the electrocardiogram measurement device determines whether the first connection portion 510 of the first external electrode portion 500 is coupled to the external input portion 20 formed in the housing 10. When the external input unit 20 is formed as a port, it is determined whether the first connection unit 510 is coupled physically or electrically. As a physical method, the number of port pins can be changed or a physical switch can be inserted into the ECG measurement device. By electrical method, current can be passed when the first connection part 510 is coupled to the port. When the external input unit 20 is connected wirelessly, pairing can be determined. As described above, signals can be received differently depending on whether the first external electrode unit 500 is coupled or not and the type of connection. Therefore, by the external input unit 20 of the ECG measuring device generating an additional signal depending on whether the first external electrode unit is coupled, the ECG measuring device determines whether the first external electrode unit 500 is coupled or not and whether the first external electrode unit 500 ) can be determined. The electrocardiogram measurement method of the present invention is not limited to the type of determination of whether the electrodes are coupled or not described above.

When step S210 is completed, the next step, step S221 or step S222, is performed.

In step S221, if it is determined that the first external electrode unit 500 is coupled to the external input unit 20, at least one measurement mode that can measure the electrocardiogram using the first external electrode 520 is included. Provides the first option. The first option using the first external electrode unit 500 may provide various image options depending on the use of the first external electrode unit 500.

For example, at least one of the images provided by the first option disables the third electrode 400 and utilizes only the first electrode 200, the second electrode 300, and the first external electrode unit 500. An image measuring the electrocardiogram can be provided as an option. The first option provided by the electrocardiogram measuring device is not only the option of receiving a potential signal using a suitable electrode, but it can also guide a desirable posture in a situation where a potential signal is input by using an electrode, such as attaching or pinching an electrode. Specifically, when the first external electrode 520 unit 500 is in the form of a clamp suitable for measuring the potential signal of the leg, the first external electrode 520 unit 500 is used for one leg (left leg or right leg). ), you can receive a potential signal by picking it up.

In addition, in the method of attaching the first electrode 200 and the second electrode 300 to both hands, the preferred attachment position can be guided, and in the method of pinching the legs of the first external electrode unit 500, the preferred attachment position can be guided. It can guide you where to pick it up. The method of providing the first option may be output through a display unit coupled to the electrocardiogram measurement device. In some cases, selection information may be transmitted to a separate external device that is separate from the electrocardiogram measurement device.

In addition to the examples described above, various options may be provided. In the above-described example, it is explained that the third electrode 400 is deactivated and the first external electrode 520 is activated, but the present invention is not limited to this. In some cases, all of the first, second, and third electrodes and the first external electrode 520 may be activated, providing an option to measure the electrocardiogram using four electrodes.

In step S222, if it is determined that the first external electrode unit 500 is not coupled to the external input unit 20, at least one measurement mode that can measure the electrocardiogram without using the first external electrode 520 is selected. Provides a second option included. The second option, which does not use the first external electrode 520 unit 500, may provide various image options depending on the use of the third electrode 400.

For example, at least one of the images provided by the second option is an image measuring the electrocardiogram using only the first electrode 200 and the second electrode 300 without using the third electrode 400. can be provided. The second option provided by the electrocardiogram measuring device is not only the option of receiving a potential signal using a suitable electrode, but it can also guide a desirable posture in a situation where a potential signal is input by using an electrode, such as attaching or holding an electrode. Specifically, when the first electrode 200 to the third electrode 400 of the electrocardiogram measuring device are formed as one piece, hold the first electrode 200 with your left hand and hold the second electrode 300 with your right hand, 3 The electrode 400 is in an inactive state and can provide the option of receiving potential signals from only two locations.

In addition, in the method of holding the first electrode 200 and the second electrode 300 of the above-described options, the preferred holding position of the fingers can be guided. The method of providing the second option may be output through a display unit coupled to the electrocardiogram measurement device. In some cases, selection information may be transmitted to a separate external device that is separate from the electrocardiogram measurement device.

When step S221 or step S222 is completed, the next step, step S230, is performed.

In step S230, selection information regarding the user's selection of one of the first option and the second option is input, and one measurement mode according to the selection information is determined as the motion measurement mode. The ECG measurement device determines a separate single measurement mode according to the user's selection and utilization of the first electrode 200 to the third electrode 400 and the first external electrode 520.

For example, when a choice is provided through a display, the display may be formed in a structure capable of detecting the touch of the sensed object, as described above. In this case, when the user selects one option through touch interaction, the selected option is transmitted to the ECG measurement device and operates in a single measurement mode. As another example, when the display is formed in a structure that cannot detect touch, a control unit with a separate button may be formed in the ECG device. Accordingly, the user selects one option through the control panel and operates in a single measurement mode appropriate for that option.

As another example, when option information is transmitted to a separate external device connected to the ECG device, an option is selected by manipulating the external device, and the ECG device receives the selected option information to determine a single measurement mode. A separate external device may be a smartphone, smart pad, display device, etc. The present invention is not limited to the method of receiving the above-described option information. When step S230 is completed, the next step, step S240, is performed.

In step S240, a potential signal is input through at least one electrode used in the operation measurement mode among the first electrode 200 to the third electrode 400 and the first external electrode 520 unit 500. Receive.

The single measurement mode in which the ECG measurement device operates measures the potential signal using only the necessary electrodes among the first electrodes 200 to 3 electrodes 400 and the first external electrode unit 500 used for measurement according to the selection information. do. By determining a single measurement mode, unused electrodes can be deactivated, thereby preventing unnecessary power consumption and the inflow of external signals generated by unused electrodes. When the measurement mode receives a potential signal, the potential signal can be input from three electrodes or two electrodes.

Additionally, when receiving a potential signal using three electrodes, the potential signal can be received by attaching two electrodes to one area and attaching the other to another area. For example, when receiving a potential signal using three electrodes, attach one electrode to one hand (right hand or left hand) and then attach the other two electrodes to one leg (left leg or right leg). By attaching it, you can receive a potential signal. The present invention is not limited to the number of electrodes receiving potential signals. In the process of determining the measurement mode and receiving the potential signal, if there is an abnormality in the reception state of the potential signal, a warning can be sent to the user through the display or external device described above.

When step S240 is completed, the next step, step S250, is performed.

In step S250, the potential signal received in the input receiving step is processed by a predetermined signal processing method according to the motion measurement mode to produce an electrocardiogram measurement result. Since the potential signal received by the ECG device is different depending on the selected measurement mode, the ECG measurement result is calculated according to a predetermined signal processing method. Specifically, depending on the selected measurement mode, the input potential signals may be from both arms and left legs, or from the left arm and both legs. Therefore, since the potential signals measured at different parts have different waveforms, the electrocardiogram measurement results are calculated according to a predetermined signal processing method by matching the selected measurement mode and the input potential signal.

When step S250 is completed, the next step, step S260, is performed.

In step S260, electrocardiogram measurement results are provided. The electrocardiogram measurement results calculated by the electrocardiogram device can be transmitted to the display or external device described above and provided to the user. Through the measurement results provided to the user, the user can check whether there is an abnormality in his or her heart. Specifically, prior to diagnosing cardiovascular diseases such as arrhythmia, cardiomyopathy, valvular disease, and heart failure, it is possible to check for abnormalities to determine whether a detailed diagnosis is required in the future.

Hereinafter, another embodiment of the present invention will be described with reference to FIG. 3.

Figure 3 shows an electrocardiogram device according to another embodiment of the present invention.

For convenience of explanation, the embodiment described with reference to FIG. 3 will be described focusing on differences from the embodiment described in FIGS. 1 and 2.

In Figure 3, the second external electrode unit 600 is shown. The second external electrode unit 600 is formed separately from the housing 10. The second external electrode unit 600 may be coupled to the housing 10 through the external input unit 20 of the housing 10. As described above, when the external input unit 20 of the housing 10 is a port, the housing 10 and the second external electrode unit 600 may be coupled with a wired cable. On the other hand, when the external input unit 20 is a receiver, the housing 10 and the second external electrode 620 unit 600 can be wirelessly coupled. Through the combination of the external input unit 20 and the second external electrode unit 600, a potential signal measured in a device formed separately from the housing 10 can be received.

The second external electrode unit 600 includes a second external electrode 620 and a second connection part 610. The second external electrode unit 600 is formed separately from the housing 10. The second external electrode 620 of the second external electrode unit 600 is formed in the form of at least one of a chest ball, Velcro, and pad in order to receive the potential signal from the chest. Accordingly, the second external electrode can receive a potential signal from one point in the chest.

For example, if you want to measure a potential signal at a specific point in the chest, it can be shaped like a chest ball or Velcro. In this way, the second external electrode is formed in one of the above-described forms, depending on which point in the chest receives the potential signal. A portion of the extreme end of the second connection portion 610 is formed in a shape corresponding to the external input portion 20. Specifically, when the external input unit 20 is a port, it is formed in the same shape as the corresponding insertion unit. On the other hand, when the external input unit 20 is in the form of a receiver, it is formed in the same form as the corresponding antenna sensor.

Hereinafter, another embodiment of the present invention will be described with reference to FIG. 4.

Figure 4 is a diagram for explaining another embodiment of the electrocardiogram measurement method according to the present invention.

For convenience of explanation, another embodiment described with reference to FIG. 4 will be described focusing on differences from the embodiment described in FIGS. 1 to 3.

4 , if it is determined in step S410 that the first external electrode unit is not coupled to the external input unit, the next step, step S420, is performed.

In step S420, the ECG measurement device determines whether the second external electrode unit 600 is coupled to the external input unit 20. Specifically, the electrocardiogram measurement device determines whether the second connection portion 610 of the second external electrode 620 portion 600 is coupled to the external input portion 20 formed in the housing 10. When the external input unit 20 is formed as a port, it is determined whether the second connection unit 610 is coupled physically or electrically. As a physical method, the number of port pins can be changed or a physical switch can be inserted into the ECG measurement device. By electrical means, current can be passed when the second connection part 610 is coupled to the port. When the first connection unit 510 and the external input unit 20 are connected wirelessly, pairing can be determined.

As described above, a signal can be received depending on whether the second external electrode unit 600 is coupled or not and the type of connection. Therefore, by the external input unit 20 of the ECG measuring device generating an additional signal depending on whether the second external electrode unit is coupled, the ECG measuring device determines whether the second external electrode unit 600 is coupled or not and the first external electrode unit 500. ) can be determined. The electrocardiogram measurement method of the present invention is not limited to the type of determination of whether the electrodes are coupled or not described above.

When step S420 is completed, the next step, step S423 or step S422, is performed.

Since the description of the second option in step S422 is the same as the above-described step S222, step S423 will be explained.

In step S423, if it is determined that the second external electrode unit 600 is coupled to the external input unit 20, at least one measurement mode that can measure the electrocardiogram using the second external electrode 620 is included. Provides a third option. The third option using the second external electrode unit 600 may provide various image options depending on the use of the second external electrode unit 600.

For example, at least one of the images provided by the third option disables the third electrode 400 and utilizes only the first electrode 200, the second electrode 300, and the second external electrode unit 600. An image measuring the electrocardiogram can be provided as an option. The third option provided by the electrocardiogram measuring device is not only the option of receiving a potential signal using an appropriate electrode, but it can also guide the preferred posture in situations where a potential signal is being input by using an electrode, such as by attaching or holding an electrode. Specifically, when the second external electrode unit 600 is in the form of a pad suitable for measuring potential signals from the chest, the second external electrode unit 620 unit 600 can be attached to the chest to receive potential signals.

In addition, in the method of attaching the first electrode 200 and the second electrode 300 to both hands, a preferred attachment position can be guided, and in attaching the electrode of the second external electrode unit 600 to the chest, It can guide the desired attachment location. A method of providing a third option may be output through a display unit coupled to an electrocardiogram measurement device. In some cases, selection information may be transmitted to a separate external device that is separate from the electrocardiogram measurement device.

Figure 5 is an exemplary diagram to explain an embodiment in which selection information is output to a display or an external device of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to FIG. 5.

The electrocardiogram measurement method of the present invention provides different options depending on whether the first external electrode and the second external electrode are combined. The electrocardiogram measurement method provides at least one option among the first to third options.

As shown in Figure 5, when providing the first option (A), it includes at least one electrocardiogram measurement option for measuring LL (left foot). When receiving a potential signal using three electrodes, the attached electrodes can be divided into a main electrode and a sub electrode to receive the potential signal. For example, referring to Figure 5, when measuring a potential signal by attaching electrodes to the left hand, right arm, and leg, the main electrode is set to the (+) pole of the left hand, and the secondary electrode is set to the (-) pole of the right arm and left foot. Electrocardiogram measurement results are calculated using the potential difference between electrodes.

When providing a third option (B), it includes at least one electrocardiogram measurement option for measuring V1 (chest). When receiving a potential signal using three electrodes, the attached electrodes can be divided into a main electrode and a sub electrode to receive the potential signal. For example, referring to Figure 5, in the third option (B), the main electrode is the right hand (+) pole, and the secondary electrodes are the left and chest (-) poles, so that the potential difference between the right and left electrodes, and the potential between the right and left hands ECG measurement results are calculated using the average of and the potential difference between the chest electrodes. In some cases, detailed potential signals may be received by attaching multiple electrodes to the same area. When multiple electrodes are attached to the same area to receive detailed potential signals, the accuracy of electrocardiogram measurement results can be improved.

Although not shown in FIG. 5, when providing a second option, it includes at least one option for electrocardiogram measurement using the third electrode 400. In the second option, a potential signal can be received using all of the first electrode 200 to the third electrode 400. However, in some cases, a potential signal can be received through two electrodes by using only the first electrode 200 and the second electrode 300 without using the third electrode 400.

In the above-described first to third options, when receiving a potential signal using electrodes, the electrocardiogram is not necessarily measured at three locations, but may be measured at only two electrodes depending on the user's option selection.

In this way, even if the positions of the attached electrodes are the same, the electrocardiogram measuring device measures the potential signal by distinguishing between the main electrode and the sub electrode, so the user selects one selection information from the first to third options provided. shall. The electrocardiogram measurement method receives selection information selected by the user and operates in one measurement mode according to the input selection information. The present invention is not limited to the number of electrodes described above. In some cases, the potential signal can be measured using all four electrodes.

In terms of providing a choice of electrocardiogram measurement method and attaching electrodes, the present invention is not limited to the above-described examples. The subject can be measured using a variety of measurement methods that can measure the electrocardiogram by varying the number or attachment location of electrodes, such as commonly performed standard limb leads, amplified limb leads, single leads, and multiple leads.

Above, embodiments of the electrocardiogram measurement method of the present invention have been described. The technical features disclosed in each embodiment of the present invention are not limited to the corresponding embodiment, and unless they are incompatible with each other, the technical features disclosed in each embodiment may be combined and applied to other embodiments.

Therefore, in each embodiment, the description is focused on each technical feature, but unless the technical features are incompatible with each other, they can be applied in combination with each other.

The present invention is not limited to the above-described embodiments and the accompanying drawings, and various modifications and variations will be possible from the perspective of those skilled in the art to which the present invention pertains. Therefore, the scope of the present invention should be determined not only by the claims of this specification but also by equivalents to these claims.

10: Housing
20: External input unit
200: first electrode
300: second electrode
400: third electrode
500: First external electrode unit
510: first connection portion
520: First external electrode
600: Second external electrode unit
610: second connection
620: Second external electrode

Claims (9)

In a method for an electrocardiogram measuring device to measure an electrocardiogram,
The electrocardiogram measurement device,
a housing forming an internal space;
a control unit accommodated in the internal space;
first to third electrodes coupled to the housing and receiving potential signals from the body of the subject;
an external input unit formed in the housing and receiving a potential signal measured outside the housing; and
It is formed separately from the housing, can be coupled to a first external electrode that receives a potential signal from the body of the subject and the external input unit, and can transmit the potential signal received by the first external electrode to the external input unit. A first external electrode unit including a first connection part;
Including,
The above method is,
determining whether the first external electrode unit is coupled to the external input unit;
When it is determined that the first external electrode unit is coupled to the external input unit, providing a first option including at least one measurement mode for measuring an electrocardiogram using the first external electrode;
If it is determined that the first external electrode unit is not coupled to the external input unit, providing a second option including at least one measurement mode capable of measuring an electrocardiogram without using the first external electrode;
receiving selection information about a user's selection of one of the first option and the second option, and determining one measurement mode according to the selection information as a motion measurement mode;
Receiving a potential signal through at least one electrode used in the motion measurement mode among the first to third electrodes and the first external electrode;
Processing the potential signal received in the input step using a predetermined signal processing method according to the motion measurement mode to calculate an electrocardiogram measurement result;
Including providing the electrocardiogram measurement results,
The operation measurement mode measures a potential signal using only necessary electrodes among the first to third electrodes and the first external electrode unit used for measurement according to the selection information, and deactivates unused electrodes.
How to measure electrocardiogram. According to claim 1,
The electrocardiogram measurement device,
It is formed separately from the housing and can be coupled to a second external electrode that receives a potential signal from the body of the subject and the external input unit, and can transmit the potential signal received by the second external electrode to the external input unit. Further comprising a second external electrode portion including a second connection portion,
The above method is,
determining whether the second external electrode unit is coupled to the external input unit;
When it is determined that the second external electrode unit is coupled to the external input unit, providing a third option including at least one measurement mode for measuring an electrocardiogram using the second external electrode;
receiving the user's selection information regarding any one of the third options, and determining one measurement mode according to the selection information as a motion measurement mode;
Further comprising receiving a potential signal through at least one electrode used in the operation measurement mode among the first to third electrodes and the second external electrode.
How to measure electrocardiogram. According to clause 2,
When one of the first external electrode unit and the second external electrode unit is coupled to the external input unit, the other is not coupled,
How to measure electrocardiogram. According to clause 3,
The first external electrode of the first external electrode unit is formed in the form of at least one of pincers, bands, patches, and straps to receive the potential signal from one of the limbs.
How to measure electrocardiogram. According to clause 3,
The second external electrode of the second external electrode unit is formed in the form of at least one of a chest ball, Velcro, and pad to receive the potential signal from the chest.
How to measure electrocardiogram. According to claim 1,
The first electrode and the second electrode are coupled to the front of the housing to be spaced apart from each other,
The third electrode is coupled to the rear of the housing,
How to measure electrocardiogram. According to claim 1,
The electrocardiogram measurement device further includes a display,
The method further includes outputting at least one of the first to third options on a display,
How to measure electrocardiogram. According to claim 1,
The electrocardiogram measurement device includes a communication unit capable of communicating with an external device,
The method further includes transmitting selection information of at least one of the first to third options to the external device through the communication unit.
How to measure electrocardiogram. According to claim 1,
The method includes the step of deactivating any one of the first to third electrodes when the first external electrode unit is coupled and the first external electrode unit replaces any one of the first to third electrodes. Containing more,
How to measure electrocardiogram.