KR101392458B1 - Electrocardiogram mapping system and method for position determination of insertion type ecg sensor - Google Patents

Abstract

The present invention relates to an electrocardiogram mapping system for determining a position of an insertion type electrocardiogram sensor and, more concretely, to an electrocardiogram mapping system for measuring electrocardiogram in order to insert the insertion type electrocardiogram sensor, comprising: a plurality of electrocardiogram leads for measuring the electrocardiogram; a pad attached at a portion of the heart of a patient, arranging a grid of the electrocardiogram leads and measuring the cardiogram of the patient; a recording part for recording electrocardiogram signals measured by the electrocardiogram leads arranged on the pad; and a mapping part for constructing an electrocardiogram signal map on the pad by using the recorded electrocardiogram signals. Additionally, the present invention relates to an electrocardiogram mapping method for determining the position of the insertion type electrocardiogram sensor and, more concretely, to an electrocardiogram mapping method to insert the insertion type electrocardiogram sensor, comprising the steps of: (1) arranging the electrocardiogram leads in a grid shape for measuring the electrocardiogram and measuring the electrocardiogram by using the pad attached on a portion of the heart of the patient; and (3) constructing the electrocardiogram signal map on the pad by using the measured electrocardiogram signals. The electrocardiogram mapping system and method for determining the position of the insertion type electrocardiogram sensor, provided in the present invention, construct the electrocardiogram signal map by using the electrocardiogram signals measured by the pad where the electrocardiogram leads are arranged, thereby correctly and efficiently checking the position where the electrocardiogram signals are well measured and determining the correct position for inserting the insertion type electrocardiogram sensor.

Description

TECHNICAL FIELD [0001] The present invention relates to an electrocardiogram map creating system and method for positioning an ECG sensor,

The present invention relates to a system and method for generating an electrocardiogram map, and more particularly, to a system and method for creating an electrocardiogram map for positioning an implantable electrocardiographic sensor.

Generally, the term heart attack refers to a cardiac arrest caused by cardiac arrhythmia, which is caused by irregular activity of cardiac muscle cells contracting the heart muscle, or by a cardiac arrest in which the heart is stopped, To death. Cardiac arrest is a disease that has structural problems in the heart such as coronary artery disease such as acute myocardial infarction and angina, myocardial diseases such as dilated cardiomyopathy or hypertrophic cardiomyopathy, aortic diseases such as aortic dissection, and valve diseases such as aortic valve stenosis .

Here, coronary artery disease and cardiomyopathy are the most common, with about 50% of coronary artery disease deaths occurring in sudden cardiac events, sudden cardiac death in about 20% of patients with acute myocardial infarction, and coronary artery disease and cardiomyopathy It accounts for about 95% of cardiac patients. In addition, QT syndrome and Brugada syndrome, which may cause fatal arrhythmias due to a mutation in the innate ion channel although structural anomalies are not observed, are also the cause of sudden cardiac death.

In order to prevent such sudden cardiac death, it is necessary to continuously monitor the electrocardiogram of a patient. As a method for measuring the electrocardiogram, there is a method of inserting an electrocardiogram sensor into the subcutaneous fat layer on the heart to check the signal from the sensor. Using such an inserted ECG sensor, the ECG can be accurately and continuously measured.

However, when the insertion type ECG sensor is inserted in the wrong position, there is a limitation in that the ECG signal can not be accurately measured because the ECG signal is mixed with a lot of noise. Therefore, it is important to determine the insertion position before inserting the ECG sensor. However, a specific technique for determining the insertion position of the inserted ECG sensor has not been developed yet.

The present invention has been proposed in order to solve the above-mentioned problems of the conventional methods. The present invention creates an electrocardiogram signal map using an electrocardiogram signal measured by a pad having a plurality of electrocardiographic leads, It is an object of the present invention to provide a system and method for creating an electrocardiogram map for positioning an ECG sensor capable of accurately and efficiently grasping a good position and determining an accurate position for insertion of the ECG sensor.

According to an aspect of the present invention, there is provided an electrocardiogram map generation system for positioning an implantable electrocardiogram sensor, the system comprising: an electrocardiogram map generation system for measuring an electrocardiogram for insertion of an implantable electrocardiogram sensor,

A plurality of electrocardiogram leads for measuring an electrocardiogram;

A pad attached to a heart portion of the patient, the plurality of electrocardiogram leads being arranged in a lattice shape to measure the electrocardiogram of the patient;

A recording unit for recording an electrocardiogram signal measured by an electrocardiogram lead disposed on the pad; And

And a map creating unit for creating an ECG signal map in the pad using the recorded ECG signal.

Preferably, the pad may have a square of 100 mm or more on one side.

Preferably, the recording unit includes:

It is possible to record the electrocardiogram signal measured in at least one electrocardiogram lead included in the window while moving the window in a sliding window manner.

More preferably,

And a setting unit configured to receive and set the size of the window.

More preferably,

It may be of a size including three ECG leads.

More preferably, the recording unit includes:

The statistically processed electrocardiogram signal may be statistically processed to record the electrocardiogram signal of the electrocardiogram lead included in the window, and the statistically processed electrocardiogram signal may be recorded as the electrocardiogram signal of the electrocardiogram lead of the predetermined position among the electrocardiogram leads included in the window.

Preferably, the map creating unit creates,

When an electrocardiogram signal is recorded for all of the electrocardiogram leads arranged on the pad, an electrocardiogram signal map in the pad can be generated.

Preferably,

And a map output unit for outputting the electrocardiogram signal map created by the map creating unit.

More preferably, the map output unit outputs,

A position having the greatest intensity of the electrocardiogram signal in the output ECG signal map may be displayed as an insertion position of the inserted ECG sensor and output.

More preferably, the map output unit outputs,

Wherein the pad is displayed in two-dimensional coordinates, and the intensity of the electrocardiogram signal measured on the electrocardiogram lead arranged on the pad is expressed by the value of the coordinate, thereby outputting the three-dimensional electrocardiogram signal map. For the positioning of an electrocardiogram.

According to an aspect of the present invention, there is provided an electrocardiogram map generation method for positioning an ECG sensor,

(1) measuring electrocardiogram using a plurality of electrocardiogram leads for measuring an electrocardiogram and arranged in a lattice shape and using a pad attached to the heart of the patient; And

(3) preparing an electrocardiogram signal map in the pad using the measured electrocardiogram signal.

Preferably, in the step (1)

The electrocardiogram signal can be measured on at least one electrocardiogram lead included in the window while moving the window by a sliding window method.

More preferably, prior to the step (1)

(0) receiving and setting the size of the window.

More preferably, in the step (1)

The statistically processed electrocardiogram signal is statistically processed and the electrocardiogram signal of the electrocardiogram lead at a predetermined position among the electrocardiogram leads included in the window can be used as the electrocardiogram signal.

Preferably, between step (1) and step (3)

(2) recording the electrocardiogram signals measured in the plurality of electrocardiographic leads in the step (1).

More preferably, in the step (3)

In step (2), if an electrocardiogram signal is recorded for all electrocardiogram leads arranged on the pad, an electrocardiogram signal map in the pad can be generated using the recorded electrocardiogram signal.

Preferably, after the step (3)

(4) outputting the electrocardiogram signal map created in the step (3).

More preferably, in the step (4)

A position having the greatest intensity of the electrocardiogram signal in the output ECG signal map may be displayed as an insertion position of the inserted ECG sensor and output.

More preferably, in the step (4)

Dimensional electrocardiogram signal map by displaying the pad in two-dimensional coordinates and displaying the intensity of the electrocardiogram signal measured in the electrocardiogram lead disposed on the pad as the value of the coordinate.

According to the system and method for creating an electrocardiogram map for positioning an implantable electrocardiogram sensor proposed in the present invention, an electrocardiogram signal map is generated using an electrocardiogram signal measured by a pad having a plurality of electrocardiographic leads, It is possible to accurately and efficiently grasp the position where the measurement is performed and to determine the exact position for insertion of the insertion type electrocardiograph sensor.

1 is a view showing a conventional electrocardiogram measuring apparatus.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electrocardiographic sensor,
3 is a diagram illustrating an example of an electrocardiogram map creation system for positioning an insertion type electrocardiographic sensor according to an embodiment of the present invention.
FIG. 4 illustrates an example of a patient to which a pad is attached in an electrocardiogram map generation system for positioning an implantable electrocardiogram sensor according to an embodiment of the present invention. FIG.
FIG. 5 illustrates a first window for electrocardiographic measurement of a sliding window system in an electrocardiogram map creation system for positioning an implantable electrocardiogram sensor according to an embodiment of the present invention. FIG.
6 is a diagram illustrating a second window for electrocardiographic measurement of a sliding window system in an electrocardiogram map creation system for positioning an insertion-type electrocardiographic sensor according to an embodiment of the present invention.
FIG. 7 illustrates a last window for electrocardiographic measurement of a sliding window system in an electrocardiogram map generation system for positioning an implantable electrocardiogram sensor according to an embodiment of the present invention. FIG.
FIG. 8 illustrates an ECG signal map output in an ECG mapping system for positioning an ECG sensor according to an exemplary embodiment of the present invention. FIG.
FIG. 9 is a view illustrating a state where an insertion type electrocardiogram sensor is inserted at a position determined by the electrocardiogram mapping system for positioning an insertion type electrocardiogram sensor according to an embodiment of the present invention. FIG.
10 is a flowchart illustrating a method of generating an electrocardiogram map for positioning an implantable electrocardiogram sensor according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

1 is a view showing a conventional electrocardiogram measuring apparatus. As shown in FIG. 1, a conventional electrocardiogram measuring device outputs a signal of an electrocardiogram measured by a sensor attached to a chest area of a patient to a monitor or a monitor so that a medical staff can check the ECG signal. At this time, since the electrocardiogram signals measured by the respective sensors are individually output, it is difficult to compare the intensity of the electrocardiogram signal. In addition, there is a limit to attaching the sensor to the chest area of the patient, and it is not possible to accurately determine the position of the heart with the naked eye. Therefore, using the conventional electrocardiogram measuring apparatus, There is a problem that can not be determined.

2 is a diagram showing a configuration of an electrocardiogram map generation system 10 for positioning an insertion type electrocardiographic sensor according to an embodiment of the present invention. 2, the electrocardiogram map generating system 10 for positioning an ECG sensor according to an embodiment of the present invention includes a pad 100, a recording unit 200, and a map generating unit 300 And may further include a map output unit 400 and a setting unit 500.

The pad 100 may be attached to the heart area of the patient and may include a plurality of electrocardiographic leads 110 for the measurement of electrocardiographic signals. At this time, the electrocardiogram lead 110 may be configured as an electrode for sensing an electrocardiogram signal, which is a configuration for measuring an electrocardiogram. The pad 100 has a plurality of electrocardiogram leads 110 arranged in a lattice pattern so that a plurality of electrocardiogram leads 110 can measure a patient's electrocardiogram.

3 is a diagram showing an example of an ECG mapping system 10 for positioning an ECG sensor according to an embodiment of the present invention. 3, the ECG mapping system 10 for positioning an ECG sensor according to an exemplary embodiment of the present invention may include a main body and a pad 100, And may include a plurality of electrocardiogram leads 110. The main body may include a recording unit 200, a map generating unit 300 and the like which will be described in detail below.

FIG. 4 illustrates an example of a patient to which the pad 100 is attached in the electrocardiogram mapping system 10 for positioning an insertion-type electrocardiographic sensor according to an embodiment of the present invention. 4, in the electrocardiogram mapping system 10 for positioning an implantable electrocardiogram sensor according to an embodiment of the present invention, the pad 100 may be attached to a heart part of a patient to measure an electrocardiogram have. For accurate electrocardiogram measurement, the pad 100 is large enough to cover the heart and the heart, and may be formed in a rectangular shape or the like. More specifically, the pad 100 may be configured to have a square of 100 mm or more on one side so as to cover the heart and its periphery.

The recording unit 200 can record the electrocardiogram signal measured by the electrocardiographic lead 110 disposed on the pad 100. [ That is, a plurality of electrocardiogram leads 110 disposed on the pad 100 attached to the heart of the patient collect electrocardiogram signals, and the recording unit 200 can receive and record electrocardiogram signals. At this time, the recording unit 200 can record the electrocardiogram signal according to the position on the pad 100 by recording the electrocardiogram signal and the position of the electrocardiogram lead 110, which measure the electrocardiogram signal.

Meanwhile, the recording unit 200 may record the electrocardiogram signal measured by at least one electrocardiographic lead 110 included in the window while moving the window in a sliding window manner. That is, the electrocardiogram can be measured while moving the window of a predetermined size, and the ECG signal can be measured and recorded while moving the ECG one by one.

FIGS. 5 to 7 illustrate a sliding window type electrocardiographic measurement, for example, in the electrocardiogram mapping system 10 for positioning an insertion-type electrocardiographic sensor according to an embodiment of the present invention. 5, in the electrocardiogram mapping system 10 for positioning an ECG sensor according to an embodiment of the present invention, a window 120 including a plurality of ECG leads 110 is used The electrocardiogram signal can be measured. 5 to 7, the window 120 may have a size including three electrocardiogram leads 110, and may be variously implemented according to the embodiment.

As shown in FIG. 5, when the electrocardiogram signal is measured in the first window 120, the window 120 is moved by one electrocardiogram lead 110 according to the sliding window method, The electrocardiogram signal can be measured in the window 120. The electrocardiogram signal can be measured while moving the window 120 in the manner shown in FIGS. 5 and 6, and the electrocardiogram signal can be measured up to the last window 120 as shown in FIG. In this way, the electrocardiogram signal can be measured for all the electrocardiogram leads 110 disposed on the pad 100 and the electrocardiogram can be measured in the window 120. Therefore, Since the signal is collected, the accuracy of the collected electrocardiogram signal can be improved.

The recording unit 200 statistically processes the electrocardiogram signal measured by the electrocardiogram lead 110 included in the window 120 and outputs the statistically processed electrocardiogram signal to the recording unit 200 in advance of the electrocardiogram lead 110 included in the window 120 It is possible to record the electrocardiogram signal of the electrocardiogram lead 110 at the predetermined position. That is, since a plurality of electrocardiogram leads 110 may be included in the window 120, the measured electrocardiogram signals may be statistically processed by an average, an intermediate value, etc., and the statistically processed values may be stored in any one of the plurality of electrocardiogram leads 110 . ≪ / RTI > For example, as shown in FIGS. 5 to 7, when three electrocardiogram leads 110 are included in the window 120, the average value of the three measured electrocardiogram signals is calculated, It is possible to record the electrocardiogram signal by the electrocardiogram signal of the electrocardiogram lead 110.

The map creating unit 300 can create an electrocardiogram signal map in the pad 100 using the recorded electrocardiogram signal. The electrocardiogram signal map is created in a map form so that the electrocardiogram signal recorded in the recording unit 200 can be confirmed at a glance. It is possible to confirm at which position of the pad 100 the electrocardiogram signal is strongly measured using the electrocardiogram map. At this time, the map creator 300 can generate the electrocardiogram signal map on the pad 100 when the electrocardiogram signal is recorded on all the electrocardiogram leads 110 disposed on the pad 100.

That is, the ECG signal is recorded in the ECG lead 110 in the recording unit 200, but since there are a plurality of ECG leads 110 arranged in the pad 100, the ECG signal is checked one by one, Judging whether it is large can be inefficient and its accuracy may be degraded. The map creating unit 300 can create a map of the electrocardiogram signal so that the position where the intensity of the electrocardiogram signal is large can be easily grasped.

The map output unit 400 can output the electrocardiogram signal map generated by the map generating unit 300. [ The map output unit 400 may be implemented as a monitor screen or the like of the electrocardiogram mapping system 10 as shown in FIG. 3 to electronically output an electrocardiogram signal map. Likewise, it is possible to output the electrocardiogram signal map in paper form.

The map output unit 400 may display the intensity of the electrocardiogram signal on the coordinates of the pad 100 by using contour lines or colors on the pad 100. The pad 100 ) Of the electrocardiogram signal may be displayed to indicate the intensity of the electrocardiogram signal by making a difference in the color of each figure indicating the electrocardiogram lead 110. The map output unit 400 displays the pad 100 as two-dimensional coordinates and displays the intensity of the electrocardiogram signal measured by the electrocardiographic lead 110 disposed on the pad 100 as a coordinate value, The electrocardiogram signal map of FIG. In addition, the map output unit 400 may output the electrocardiogram map in various ways, and may use an output method that intuitively recognizes the distribution of the intensity of the electrocardiogram signal at the request of the system user or the manager.

8 is a diagram illustrating an ECG signal map output in the ECG mapping system 10 for positioning an ECG sensor 20 according to an exemplary embodiment of the present invention. 8, the map output unit 400 of the electrocardiogram mapping system 10 for positioning the implantable electrocardiogram sensor 20 according to an embodiment of the present invention includes an ECG signal map in three dimensions And the distribution of the electrocardiographic signal intensity can be intuitively grasped through the electrocardiogram signal map.

In addition, the map output unit 400 may display the location of the ECG signal with the highest intensity in the ECG signal map output as the insertion position of the ECG sensor. That is, the present invention is for inserting an insertion type electrocardiogram sensor at a position where the electrocardiogram signal is best measured by recognizing the position of the electrocardiogram signal at which position, using the prepared electrocardiogram map. Therefore, the insertion position of the insertion type electrocardiogram sensor can be displayed on the electrocardiogram signal map, thereby facilitating the positioning of the insertion type electrocardiograph sensor.

9 shows a state where the insertion type electrocardiogram sensor 20 is inserted at a position determined by the electrocardiogram mapping system 10 for positioning the insertion type electrocardiogram sensor 20 according to an embodiment of the present invention. FIG. 9, in the electrocardiogram mapping system 10 for positioning the implantable electrocardiogram sensor 20 according to the embodiment of the present invention, the electrocardiogram signal map output from the map output unit 400 It is possible to easily determine a position where the intensity of the electrocardiogram signal is large, and the insertion type electrocardiogram sensor 20 can be inserted at the corresponding position to perform accurate insertion and electrocardiogram monitoring.

The setting unit 500 can receive and set the size of the window 120. That is, the setting unit 500 may be configured to set the size of the window 120 in the electrocardiogram signal measurement using the sliding window method, and to set the size of the window 120 by the user or manager of the system . Depending on the embodiment, the size of the window 120 may be preset by the maker of the system.

10 is a flowchart illustrating a method of generating an electrocardiogram map for positioning an insertion-type electrocardiograph sensor 20 according to an embodiment of the present invention. 10, a method of preparing an electrocardiogram map for positioning an ECG sensor 20 according to an embodiment of the present invention includes using a pad 100 in which a plurality of ECG leads 110 are disposed A step S200 of recording the electrocardiogram signal measured by the plurality of electrocardiogram leads 110 and a step S300 of generating an electrocardiogram signal map in the pad 100 using the electrocardiogram signal, (S10) of receiving and setting the size of the window 120, and outputting the generated electrocardiogram signal map (S400).

In step S10, the size of the window 120 can be input and set. Step S10 may be processed by the setting unit 500 of the electrocardiogram map generation system 10. [ The size of the window 120 can be input and set in various forms such as the number of electrocardiogram leads 110 included in the window 120 and the width of the window 120.

In step S100, a plurality of electrocardiogram leads 110 for measuring an electrocardiogram are arranged in a lattice pattern and the electrocardiogram can be measured using the pad 100 attached on the heart of the patient. Step S100 can be processed by the pad 100 and the recording unit 200 of the electrocardiogram mapping system 10. At this time, in step S100, the electrocardiogram signal can be measured by at least one electrocardiogram lead 110 included in the window 120 while moving the window 120 in a sliding window manner. In step S100, the electrocardiogram signal measured in the electrocardiogram lead 110 included in the window 120 is statistically processed and the statistically processed electrocardiogram signal is transmitted to a predetermined position among the electrocardiogram leads 110 included in the window 120 The electrocardiogram signal of the electrocardiogram lead 110 of FIG.

In step S200, the electrocardiogram signals measured by the plurality of electrocardiogram leads 110 can be recorded in step S100. Step S200 can be processed by the recording unit 200 of the electrocardiogram map creation system 10. [ That is, the ECG signal measured in step S100 may be received and recorded by the recording unit 200, and the statistically processed ECG signal may be recorded.

In step S300, the electrocardiogram signal map in the pad 100 can be generated using the measured electrocardiogram signal. Step S300 can be processed by the map creator 300 of the electrocardiogram signal map creation system. In step S300, when an electrocardiogram signal is recorded for all of the electrocardiographic leads 110 arranged in the pad 100 in step S200, the electrocardiogram signal map in the pad 100 can be generated using the recorded electrocardiogram signal.

In step S400, the electrocardiogram signal map created in step S300 can be output. Step S400 may be processed by the map output unit 400 of the electrocardiogram map creation system 10. [ At this time, in step S400, a position having the greatest intensity of the electrocardiogram signal in the outputted electrocardiogram signal map may be displayed as the inserted position of the inserted type electrocardiograph sensor 20 and output. In step S400, the pad 100 is displayed in two-dimensional coordinates, and the intensity of the electrocardiogram signal measured by the electrocardiogram lead 110 disposed on the pad 100 is expressed as a coordinate value to generate a three-dimensional electrocardiogram signal map May be output.

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

10: ECG mapping system
20: Insertion type electrocardiogram sensor 100: Pad
110: electrocardiogram lead 120: window
200: recording unit 300: map creating unit
400: map output unit 500: setting unit
S10: Step of inputting the size of the window
S100: a step of measuring electrocardiogram using a pad on which a plurality of ECG leads are arranged
S200: recording the electrocardiogram signal measured in a plurality of electrocardiographic leads
S300: Creating an electrocardiogram signal map on the pad using the electrocardiogram signal
S400: outputting the created electrocardiogram signal map

Claims (19)

An electrocardiogram mapping system (10) for measuring an electrocardiogram for insertion of an insertion type electrocardiograph sensor,
A plurality of electrocardiogram leads (110) for measuring an electrocardiogram;
A pad 100 attached to the heart of the patient, the plurality of electrocardiogram leads 110 being arranged in a lattice shape to measure the electrocardiogram of the patient;
A recording unit 200 for recording an electrocardiogram signal measured by the electrocardiographic lead 110 disposed on the pad 100; And
And a map generator (300) for generating an electrocardiogram signal map in the pad (100) using the recorded electrocardiogram signal. The electrocardiogram map generating system (10) for positioning an insertion type electrocardiograph sensor .
The method of claim 1, wherein the pad (100)
(10) for positioning an electrocardiogram sensor of an insertion type, wherein one side is a square of 100 mm or more.
The apparatus of claim 1, wherein the recording unit (200)
The electrocardiograph according to claim 1, characterized by recording the electrocardiogram signal measured by at least one electrocardiogram lead (110) included in the window (120) while moving the window (120) by a sliding window method (10).
The method of claim 3,
Further comprising a setting unit (500) configured to receive and set the size of the window (120), and to set the magnitude of the window (120).
4. The apparatus of claim 3, wherein the window (120)
(EN) An electrocardiographic map generation system (10) for positioning an implantable electrocardiogram sensor, characterized in that it has a size including three electrocardiogram leads (110).
4. The apparatus of claim 3, wherein the recording unit (200)
The electrocardiogram signal processing unit 110 statistically processes the electrocardiogram signal measured by the electrocardiogram lead 110 included in the window 120 and outputs the statistically processed electrocardiogram signal to an electrocardiogram lead 110 of a predetermined position among the electrocardiogram leads 110 included in the window 120, (10) according to claim 1, wherein the electrocardiogram signal is recorded in the electrocardiogram signal of the electrocardiogram sensor (110).
The apparatus of claim 1, wherein the map generator (300)
Wherein the ECG signal map is generated by the pad (100) when the electrocardiogram signal is recorded on all the ECG leads (110) disposed on the pad (100) (10).
The method according to claim 1,
Further comprising a map output unit (400) for outputting the ECG signal map generated by the map generating unit (300).
The map output unit according to claim 8, wherein the map output unit (400)
Wherein the position of the ECG signal having the greatest intensity in the output ECG signal map is displayed as an insertion position of the ECG sensor and is output to the ECG map.
The map output unit according to claim 8, wherein the map output unit (400)
The pad 100 is displayed in two-dimensional coordinates, and the intensity of the electrocardiogram signal measured by the electrocardiographic lead 110 disposed on the pad 100 is displayed as the value of the coordinate, thereby outputting a three-dimensional electrocardiogram signal map (10) for positioning an electrocardiogram sensor of an insertion type.
A method for creating an electrocardiogram map for insertion of an insertion type electrocardiograph sensor,
(1) measuring a electrocardiogram using a pad 100 having a plurality of electrocardiogram leads 110 for measuring an electrocardiogram arranged in a lattice pattern and attached to the heart of a patient; And
(3) preparing an electrocardiogram signal map in the pad (100) by using the measured electrocardiogram signal.
12. The method according to claim 11, wherein in the step (1)
An electrocardiogram (100) for position determination of an insertion-type electrocardiograph sensor, characterized by measuring an electrocardiogram signal on at least one electrocardiogram lead (110) included in a window (120) while moving a window (120) How to create a map.
13. The method of claim 12, wherein prior to step (1)
(0) the magnitude of the window (120), and setting the size of the window (120).
13. The method according to claim 12, wherein in the step (1)
The electrocardiogram signal processing unit 110 statistically processes the electrocardiogram signal measured by the electrocardiogram lead 110 included in the window 120 and outputs the statistically processed electrocardiogram signal to an electrocardiogram lead 110 of a predetermined position among the electrocardiogram leads 110 included in the window 120. [ And the electrocardiogram signal of the insertion type electrocardiogram sensor is used as the electrocardiogram signal of the electrocardiogram sensor.
12. The method of claim 11, wherein between step (1) and step (3)
(2) recording the electrocardiogram signal measured by the plurality of electrocardiographic leads (110) in the step (1).
16. The method of claim 15, wherein in step (3)
When an electrocardiogram signal is recorded on all the electrocardiogram leads 110 disposed in the pad 100 in the step 2, the electrocardiogram signal map in the pad 100 is generated using the recorded electrocardiogram signal Wherein the position of the ECG sensor is determined based on the position of the ECG sensor.
12. The method of claim 11, wherein after step (3)
(4) outputting the electrocardiogram signal map created in the step (3). ≪ Desc / Clms Page number 19 >
18. The method of claim 17, wherein in step (4)
Wherein the position of the electrocardiogram signal having the greatest intensity in the output ECG signal map is displayed as an insertion position of the ECG sensor and is output.
18. The method of claim 17, wherein in step (4)
The pad 100 is displayed in two-dimensional coordinates, and the intensity of the electrocardiogram signal measured by the electrocardiographic lead 110 disposed on the pad 100 is displayed as the value of the coordinate, thereby outputting a three-dimensional electrocardiogram signal map Wherein the electrocardiogram signal is generated by the electrocardiogram sensor.

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