KR20180076655A - The measurement system and method of electrocardiogram - Google Patents

Abstract

The present invention relates to a system and a method for measuring an electrocardiogram and, more specifically, to a system and a method for measuring an electrocardiogram which induces a user to use an electrocardiogram measurement method to allow anyone to easily measure an electrocardiogram. According to the present invention, the system for measuring an electrocardiogram includes a sensor means and a main body means. The sensor means includes a plurality of sensors each including: a unique number; a measurement unit attached to a body to measure an electrocardiogram of the body; a touch unit to sense a grip status from a user; a notification unit to display a notification to the outside; and a transmission unit to transmit the grip status in the touch unit, a signal measured by the measurement unit, and the unique number. The main body means includes: a channel unit wherein a channel is assigned to the unique number of each sensor to collect an electrocardiogram signal measured by the measurement unit of each sensor; an operating unit to operate the notification units of the sensors in an order of the unique numbers of the sensors assigned to the channel unit to allow the sensors to be attached to the body in the order; a receiving unit to receive data transmitted by the sensors; and a control unit to match the channels in the order in which the operating unit operates in an order of being sensed by the touch unit and measured by the measurement unit to be received by the receiving unit. According to the present invention, since sensors to be attached to the body are notified in an order, a user can attach the sensors notified by the notification to the body in the order. Therefore, even if a user is not an expert, the user can attach the electrocardiogram sensors in accordance with the order.

Description

[0001] The present invention relates to an electrocardiogram measuring system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system and method for measuring electrocardiogram, and more particularly, to a system and method for measuring electrocardiogram (ECG) by which a user can easily measure an electrocardiogram.

Electrocardiogram (ECG) is a measure of the activity current of a cardiac muscle during its contraction and expansion. The action potential, which is generated when the cardiac muscle relaxes and contracts, generates a current that spreads from the heart to the body. This current generates a potential difference depending on the position of the body. The potential difference is detected through a surface electrode attached to the skin of the human body Can be recorded. These electrocardiograms are used to check for cardiac anomalies and are one of the most important medical devices that are used as a basic method for measuring diseases of heart diseases such as angina pectoris, myocardial infarction, and arrhythmia.

Conventionally, due to the nature of busy modern people, a portable electrocardiogram measuring device has been developed so that an electrocardiogram can be measured outside the hospital.

Open Patent No. 10-2006-0091187 (published on August 18, 2006) Registration Utility Model No. 20-0209363 (Registration date October 25, 2000) Registration No. 10-0356421 (registered on September 30, 2002)

The electrocardiogram measuring device is equipped with several sensors and is attached to the body. At this time, each sensor has a unique number, and each sensor having a unique number should be accurately attached to the position to be attached. However, there is a problem in that it is difficult to utilize the sensor because it does not know what order to attach the sensor or which sensor should be attached to which position of the body when the person is not a professional or expert.

The present invention is intended to solve the above problems. An object of the present invention is to provide an electrocardiogram measuring system and a method thereof, which can easily attach a sensor by guiding a sensor to be attached in order.

It is another object of the present invention to provide an electrocardiogram measuring system and a method for detecting and correcting an electrocardiogram when a user attaches the sensor at a wrong position.

The electrocardiogram measuring system according to the present invention includes a sensor means and a body means. Wherein the detection sensor means includes a unique number, a measurement unit attached to the body to measure the electrocardiogram of the body, a touch unit that detects whether the user is grasped from the user, a notification unit that displays an external notification, And a transmitter for transmitting the signal measured by the measuring unit and the unique number. Wherein the main body means comprises a channel portion allocated with a channel for each unique number of each sensor for collecting the electrocardiogram signal measured by the measuring portion of each sensor, An operation unit for sequentially operating the notifying units of the respective sensors so that the sensors are attached to the body in order; a receiving unit for receiving data transmitted from the respective sensors; And a controller for matching the channels in the order in which they are operated by the operating unit in the order received by the receiving unit.

In the above electrocardiogram measurement system, it is preferable that the notification unit displays an alarm using light.

The electrocardiogram measuring method according to the present invention includes a step of displaying an attached electrode, a receiving step and a storing step. In the step of displaying the attachment electrodes, the notification units of the plurality of sensors of the monitoring sensor means are operated in order in order to attach the sensors having the unique numbers allocated for each channel to the body in order to collect the electrocardiographic signals of the body. The receiving step receives the electrocardiogram data by the unique number from sensors attached to the body, which are held by the user. The storing step stores the signals of the sensors in the order of the order in which the sensor is operated in the step of displaying the attached electrodes in the order received in the receiving step.

According to the present invention, since the sensors to be attached to the body are notified in order, the user may attach the sensors, which are known as notifications, to the body in order. Therefore, even if you are not an expert, you can attach ECG sensors in order.

In addition, according to the present invention, when the user mistakenly attaches the sensor, the signal received from the attached sensor is matched to the normal channel in the wrong order. Therefore, even if the user attaches the sensor in the wrong order, it can match the normal channel and receive the correct information.

1 is a conceptual diagram of an embodiment of an electrocardiogram measurement system according to the present invention,
Fig. 2 is a structural view of the sensing means and the body means of the embodiment shown in Fig. 1. Fig.

An embodiment of the electrocardiogram measuring system according to the present invention will be described with reference to FIGS. 1 and 2. FIG.

The electrocardiogram measuring system according to the present invention comprises a sensor means and body means (20).

The detection sensor means comprises a plurality of sensors (10). The sensor 10 is attached to the body 1 to measure the electrocardiogram of the body 1. [ The sensor 10 includes a unique number 11, a measurement unit 13, a touch unit 15, a notification unit 17, and a transmission unit 19.

The unique number 11 is set for each sensor 10 to specify the sensor 10. The measurement unit 13 measures the current data of the electrocardiogram from the body when the sensor 10 is attached to the body. The gripper 15 senses whether or not the user grasps. That is, whether or not the user holds the sensor 10 or releases it. The notification unit 17 displays a notification to the outside by light or the like so that the user can recognize it. The transmitting unit 19 transmits the grasping result and the signal measured by the measuring unit 13 to the main body unit 20 together with the unique number 11 from the grasping unit 15. The sensor 10 and the body means 20 can communicate wirelessly.

The main body means 20 includes a channel portion 21, an operation portion 23, and a control portion 25. [

The channel unit 21 has a channel assigned to each sensor 10 by a unique number so as to collect electrocardiogram signals measured by the measuring unit 13 of each sensor 10. That is, when the sensor 10 has six channels, the channel unit 21 has six channels, and each channel is matched with the sensor 10 one to one. Thus, the electrocardiogram signal measured by the measuring unit 13 of each sensor 10 is stored in each matched channel.

The operation section 23 serves to guide the user to attach the sensor 10 to the predetermined position of the body 1 in order. To this end, the operation unit 23 controls the notification unit 17 of each sensor 10 so that the sensor 10 is attached to the body in the order of the unique numbers of the sensors 10 assigned to the channel unit 21 Operate in the above-mentioned order. That is, there is a sensor 10 assigned to each channel of the channel unit 21, and each sensor 10 is specified to which part of the body 1 it should be attached. Thus, the user must attach each sensor 10 to a predetermined position of the body 1. This ensures that the correct signal comes into the channel and the information can be analyzed. However, when the user is not an expert, it is difficult to accurately know the attachment position of the sensor 10. Accordingly, the operation unit 23 operates the notification unit 17 in order for each sensor 10. The user can grip the sensor 10 indicated by the notification unit 17 and attach them to the body 1 in the predetermined order.

The receiving unit 25 receives data transmitted from each sensor 10. At this time, the received data is the signal of the sensor 10, together with the unique number 11 of the sensor 10, and the signal measured by the measuring unit 13.

The control unit 27 matches the channels in the sequence in which the notification unit 17 is operated in the operation unit 23 in the order in which they are sensed by the touch unit 15 and measured by the measurement unit 13 and received by the reception unit 25 . In order for the sensor 10 to be attached to the body 1, the user must grasp the sensor 10 first. Therefore, in order to receive a proper signal, it must be detected by the touch unit 15. Therefore, in order to be allocated to the channel unit 21, the touch unit 15 must be sensed and a signal must be received from the measurement unit 13. If the user holds the wrong sensor 10 and does not attach it to the body 1 and then holds it and holds the other sensor 10, the detection signal is transmitted by the touch unit 15 but the signal is not received by the measurement unit 13 It is not assigned to the channel unit 21 as a matter of course. On the other hand, the operation unit 23 operates the notification unit 17 of the sensor 10 in the order of the unique numbers of the respective sensors 10 assigned to the channel unit 21. Therefore, the user basically grasps the sensor 10 in the order and attaches the sensor 10 to the body 1. Accordingly, when the user observes this order, the channel unit 21 can receive the data of the sensor 10 in the order assigned to the channels and store the data transmitted from the sensors assigned to the respective channels. However, the user can grasp another sensor 10 and attach it to the body 1 without holding the sensor 10 in which the notification is activated in the notification unit 17. In this case, the signal of the sensor 10 received by the receiving unit 25 is not a signal of the sensor 10 of the unique number 11 assigned to the channel in the channel unit 21, 10 are received. At this time, although not the sensor 10 assigned to the channel of the channel unit 21, the control unit 27 matches the signal of the received sensor 10 to the channel unit 21. That is, the control unit 27 matches the channel of the order that is operated by the operation unit 23 in the order in which the touch unit 15 is sensed and measured by the measurement unit 13 and received by the reception unit 25.

Hereinafter, a method of measuring an electrocardiogram using the electrocardiogram measuring system of the present embodiment will be described.

A channel for receiving a signal transmitted to the sensor 10 is assigned to the channel unit 21 of the body means 10 in order to analyze the electrocardiogram signal measured by the sensor 10. [ That is, there is a channel allocated to each sensor 10, and data transmitted from the sensor 10 is stored in each assigned channel. When the sensor 10 is attached to six places of the body 1 as in the present embodiment, six channels are allocated to the channel unit 21. [ Therefore, in order to measure the electrocardiogram, the sensor 10 should be attached to the position of 'a', 'b', 'd', 'la', 'ma', and 'bar' of the body 1, The electrocardiogram data can be accurately analyzed only by attaching the sensor 10a to each position of the body 1 and the sensor 10 assigned to each position of the body 1 like the sensor 10b.

However, when the user is not an expert, it may be difficult to accurately attach the sensor 10 corresponding to each position of the body 1. The electrocardiogram measuring device of the present embodiment is intended to prevent this.

The operation section 23 of the body means 20 first monitors the body 1 in order to attach the sensor 10 having the unique number 11 assigned to each channel in order to collect the electrocardiogram signal of the body 1, An indicating electrode display step of operating the notification units 17 of the plurality of sensors 10 of the sensor means in this order is performed. That is, the operation unit 23 displays the notification unit 17 of each sensor 10 in the order of 'a', 'b', 'd', 'la', ' . The notification unit 17 of the sensor 10 is operated in the order of the sensor 10a, the sensor 10b and the sensor 10c.

Then, the user grasps the lit sensor 10 and attaches the sensor 10 in the order of 'a', 'b', and 'd'.

Next, the receiving section 25 of the body means 20 carries out a receiving step of receiving electrocardiogram data together with the unique number 11 from the sensors 10 held by the user and attached to the body 1.

That is, if the user grasps the sensor 10a and attaches the sensor 10a to the sensor 10a, the sensor 10a detects whether or not the touch part 15 is sensed and receives the bio-signal measured at the sensor 22a. The receiving unit 25 of the main body unit 20 is provided with the sensor 10a and the sensor 10b in the order of the sensor 10 in order of the sensor 11 and the sensing unit 15, Lt; / RTI > is received.

Next, the control unit 20 of the main body unit 20 performs a storing step of storing signals of the sensor 10 in the order of the order in which they were received in the receiving step, in the order of the channels operated in the step of displaying the attached electrodes. In principle, since each sensor 10 is assigned to each channel, data of each sensor 10 is stored in each assigned channel. In this case, when the user mistakenly attaches the sensor 10, the biosignal at the wrong position is measured in the sensor 10. [ For example, after the sensor 10a is attached to the 'A', the notification unit 17 of the sensor 10b is lit, but the user can grasp the sensor 10c and attach it to the 'I' position. Then, the sensor 10c measures the bio-signal at the "I" position and the sensor 10b measures the bio-signal at the "Da" position. At this time, when the signal of the sensor 10 allocated to the channel of the channel unit 21 is stored, the main body unit 20 mistakes the signal inputted from the sensor 10c as the signal of the 'multi' position.

In this case, since the sensor 10a, the sensor 10c, and the sensor 10b are received in this order in the receiving unit 25, the controller 27 controls the sensor 10c to measure the signal measured by the sensor 10c, And stores the signal measured by the sensor 10b in the channel assigned to the sensor 10c, not the originally assigned channel. That is, the control unit 27 does not store the signals of the sensors 10 allocated to the respective channels but stores the signals of the sensors 10 in the channels in the order received by the receiving unit 25. Then, the body means 20 can measure the electrocardiogram with the measured signal at the correct position.

1: Body 10: Sensor
20:

Claims (3)

A measuring unit attached to the body for measuring an electrocardiogram of the body, a touch unit for detecting whether or not the user is gripped by the user, a notification unit for displaying an external notification, And a transmitter for transmitting the unique number and the unique number,
A channel unit allocated with a channel for each unique number of each sensor for collecting the electrocardiogram signal measured by the measuring unit of each sensor; An operation unit for operating the notification unit of each of the sensors so as to be attached to the body; a receiving unit for receiving data transmitted from each of the sensors; And a control unit for matching the received channels in the order of operation performed by the operating unit in the order received. The method according to claim 1,
Wherein the notification unit displays an alarm using light. An attachment electrode display step of operating the notification units of the plurality of sensors of the monitoring sensor means in order to attach a sensor having a unique number assigned to each channel in order to collect an electrocardiogram signal of the body,
A receiving step of receiving the electrocardiogram data from the sensors held by the user and attached to the body by the unique number;
And storing the signals of the sensors in the order of the order in which they were operated in the step of displaying the attached electrodes in the order received in the receiving step.

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