KR20180137756A - Apparatus for measuring electroencephalogram and method for measuring electroencephalogram using the same - Google Patents

Abstract

The present invention relates to a device for electroencephalography (EEG) and a method for EEG using the same, in which an electrode moving rail part with a plurality of EEG electrodes are movably-coupled thereto is prepared on an inner circumferential surface of a headband main body formed in a ring shape surrounding a subject′s head circumference to be examined. The position of the EEG electrodes can be changed in accordance with the patient, and the channel can be changed in accordance with the patient to accurately measure the brain waves of the patient, and thus the reliability of the EEG can be improved and the device and method can be applied to various fields of applications enabling the detection of brain waves in various parts of the brain, and the present invention contributes to the study of brain mechanism and provides convenience to individual users.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electroencephalogram measurement apparatus and an electroencephalogram measurement method using the same,

The present invention relates to an EEG measurement apparatus and a method of measuring EEG using the same, and more particularly, it is possible to measure an EEG by changing a measurement region according to a patient, And an EEG measurement method using the same.

In general, EEG (electroencephalogram) is a graphical record on the scalp of a potential fluctuation in the human cerebrum. EEG provides important information about the brain function of the patient and is used in various clinical applications.

The electroencephalography (EEG) device for EEG is designed to detect EEG signals by mounting several electrodes on the patient's scalp, analyze the frequencies of the collected digital data after passing through various signal processing terminals, The signal of each kind is extracted. The placement of the electrodes for extracting EEG information from the EEG is considered to be very important and generally follows the international 10/20 system (standard electrode location).

Conventional electroencephalogram (EEG) devices should be positioned symmetrically with respect to the center line of the head when placing the electrodes on the human scalp. Therefore, the number of electrodes (channel) and the amount of information are proportional. The conventional portable bandgap EEG has preferred a frontal lobe (Fp1, Fp2) position that is mostly related to cognitive ability, emotion, and mental function because of a small number of channels.

The type of electrode that plays a role in the detection of biological signals is divided into a wet electrode and a dry electrode. The wet electrodes are made by applying an electrolytic gel to a silver-silver (Ag-Ag) metal electrode to measure the electroencephalogram (EEG) by reducing the skin resistance, which may result in differences in results depending on the expert's skill, And removal of the gel attached to the hair. In addition, although the reliability of the wet electrode is high, the preparation time for the EEG measurement is longer than that of the dry electrode, causing inconvenience to the subject. If the measurement time is delayed, the electrolyte gel dries and the information may be damaged.

Although the conventional brain wave measuring apparatus used for research has a problem as described above, a device using wet electrode having high reliability of information is mainly used.

The researchers preferred the conventional band type EEG instrument to which the dry electrode was applied, because the above-mentioned problems were caused by using the wet electrode. Therefore, the additional cost and time required for the preparation were not much more than the wet electrode, It has been attempted to use a conventional band-type EEG measuring device which constitutes an electrode part using a dry electrode which is easy to use by the general public.

However, the conventional band-type EEG apparatuses are generally composed of one or two channels, so that information reliability is low, and the position of the electrode unit for measuring the EEG is fixed, thereby limiting the acquisition of various EEG information.

Conventional band-type EEG devices generally have one channel: prefrontal (Fp1 or Fp2); Two channels are prefrontal (Fp1 and Fp2); The third and fourth channels are aimed at measuring brain waves in the frontal lobes (AF3, AF4) and temporal lobes (T7, T8).

In addition, the conventional band type EEG measuring device measures the position of the electrode part for measuring the EEG. Therefore, even though the shape and the size of the skull are different for each person, the EEG measurement is performed at the predetermined electrode part position. And it is difficult to detect EEG by a specific region.

Korean Patent Laid-Open Publication No. 10-2007-0119141 'Portable EEG Measurement Device Using Headband' (2007.12.20)

It is an object of the present invention to provide a brain wave measuring device capable of changing the position of an electrode for EEG measurement according to a patient and measuring a correct EEG according to a patient, And to provide a measurement method.

It is another object of the present invention to provide an EEG measuring device capable of acquiring various bio-signals and utilizing the EEG signals in various fields, and generalizing the EEG, and a method of measuring EEG using the same.

According to another aspect of the present invention, there is provided a brain wave measuring apparatus comprising: a plurality of electroencephalogram electrodes capable of measuring brain waves of an electroencephalogram measurer; a ring shape surrounding the head circumference of the examinee; And a headband main body having an electrode moving rail portion on which an electrode body for a plurality of EEG electrodes is movably coupled.

In the present invention, an electrode moving rail unit may be provided on an inner circumferential surface of the headband main body to allow the electrode body for EEG measurement to be movably coupled.

In the present invention, the electrode moving rail part has an inlet formed by inserting the electrode body for EEG measurement along the inner circumference of the headband body, And one end side of the electrode body for EEG measurement may be inserted into the empty space so as to be caught in the opening. The electrode moving rail part is configured in a hollow form so that it does not interfere with the movement of the electric wire connected to the electrode body for EEG measurement and can move smoothly when the electrode body for EEG measurement is moved. Shape, but a circular shape is preferable.

In the present invention, the headband body may include a plurality of band assemblies detachably coupled to each other.

In the present invention, the band assembly may be provided with a coupling protrusion at one end thereof and a fitting groove into which the coupling protrusion is detachably fitted.

In the present invention, the inner circumferential surface of the headband main body is provided with an electrode moving rail portion to which the electrode for electroencephalogram measurement is movably engaged. The engaging protrusions and the fitting grooves are formed on both sides of the band assembly, And the electrode moving rail portion.

In the present invention, the electrode body for electroencephalogram measurement comprises an electrode mounting body having an electrode at one end and a rail coupling part movably coupled at the other end to the electrode moving rail, A plurality of active electrode members provided on the electrode mounting portion, and a rail penetrating portion provided between the electrode mounting portion and the rail coupling portion and having a diameter capable of passing through the entrance of the electrode movement rail portion.

In the present invention, the electrode mounting body member may be provided with a wire passage through which an electric wire electrically connected to the active electrode member can pass.

The electroencephalogram measuring apparatus according to the present invention further comprises a socket body provided in the headband main body and having a plurality of sockets detachably coupled to the electrode body for EEG measurement and a wire, An amplification unit for amplifying the bio-signal measured by the body and a filter unit for filtering the bio-signal.

In the present invention, the socket body may be provided with a plurality of socket insertion portions capable of detachably coupling the socket.

The EEG measuring device according to the present invention comprises a side band body having both end portions connected to a headband body and bent to wrap an upper side of a head of the examinee and having an electrode body for measuring EEG on the inner side, To the headband main body.

In the present invention, the band coupling portions may be Velcro tapes provided on both end sides of the side band body.

In the present invention, the side band body may include an electrode guide rail portion on the inner surface thereof, to which the electrode body for EEG measurement is movably coupled.

In the present invention, the electrode guide rail portion has an inlet formed by inserting the electrode body for EEG measurement along the inner surface of the side band body, and an electrode body for EEG measurement is movably inserted into the inside of the inlet And the one end side of the electrode body for EEG measurement is inserted into the empty space.

In the present invention, the side band body includes a first side band member whose both end sides are connected to the head band body respectively and which are bent so as to wrap the upper side of the head of the to-be-examined person, and a first side band member which crosses the first side band member, And a second side band member connected to the head band body and bent to wrap the upper side of the subject's head.

In at least one of the first side band member and the second side band member, at least one of the first side band member and the second side band member may have a side A band fitting groove may be provided.

According to another aspect of the present invention, there is provided a brain wave measuring apparatus comprising: a plurality of electrode bodies for measuring brain waves of an EEG measurer; a ring shape surrounding the head circumference of the human subject to be examined; And a headband body having a plurality of the electrode bodies for EEG measurement coupled to an inner circumferential surface thereof, wherein the headband body includes a plurality of band assemblies detachably coupled to each other.

In the present invention, the band assembly may be provided with a coupling protrusion at one end thereof and a fitting groove into which the coupling protrusion is detachably fitted.

Another embodiment of the EEG device according to the present invention further comprises a socket body provided in the headband main body and in which a plurality of sockets connected to the electrode body for EEG measurement and a plurality of sockets are detachably coupled, An amplification unit for amplifying the bio-signal measured by the electrode body for EEG measurement and a filter unit for filtering the bio-signal.

In the present invention, the socket body may be provided with a plurality of socket insertion portions capable of detachably coupling the socket.

Another embodiment of the EEG apparatus according to the present invention is a side band body having both end sides connected to a headband body and bent to wrap an upper side of a subject to be examined and having an electrode body for measuring EEG on the inner side; And a band coupling unit coupling the sideband body to the headband body.

In the present invention, the band coupling portions may be Velcro tapes provided on both end sides of the side band body.

In the present invention, the side band body may include an electrode guide rail portion on the inner surface thereof, to which the electrode body for EEG measurement is movably coupled.

In the present invention, the electrode guide rail portion has an inlet formed by inserting the electrode body for EEG measurement along the inner surface of the side band body, and an electrode body for EEG measurement is movably inserted into the inside of the inlet And an end of the electrode body for EEG measurement may be inserted into the circular space so as to be caught in the mouth.

In the present invention, the side band body may include a first side band member connected to the head band body at both ends thereof and bent to wrap the upper side of the subject's head, And a second side band member positioned to intersect with the first side band member and connected to the head band body at both end sides and bent to wrap the upper side of the subject's head.

In at least one of the first side band member and the second side band member, at least one of the first side band member and the second side band member may have a side A band fitting groove may be provided.

According to another aspect of the present invention, there is provided a method of measuring brain waves, comprising: positioning an electrode body for adjusting an EEG for an EEG measurement on an inner circumferential surface of a headband body surrounding a head of a subject; And measuring an EEG by applying an electric power to the EEG electrode member after the electrode positioning step.

The EEG measuring method according to the present invention may further comprise a band size adjusting step of adjusting the size of the headband body to match the head size of the subject before the electrode positioning step.

According to the present invention, the position of the electrode for EEG measurement can be changed according to the patient, and the channel can be changed, so that accurate EEG according to the patient can be measured, thereby improving the reliability in EEG measurement.

The present invention can be applied to various fields of application, enabling detection of brain waves in various parts of the brain, thereby contributing to research on the mechanism of the brain, and contributing to the convenience of individual users.

In addition, the present invention can reduce the burden of continuously receiving a hospital or a treatment center for diagnosis by receiving information from a home for patients with cranial nerve diseases through popularization of a portable (public) EEG device and a control device, Contributing to society and making it available.

1 is a perspective view illustrating an EEG apparatus according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view showing an EEG apparatus according to an embodiment of the present invention. FIG.
FIG. 3 is a perspective view illustrating an embodiment of a band assembly of a headband main body in an EEG apparatus according to the present invention. FIG.
FIG. 4 is a perspective view showing an embodiment of an electrode body for EEG measurement in the EEG apparatus according to the present invention. FIG.
5 and 6 are enlarged perspective views illustrating an example in which an electrode body for EEG measurement is movably coupled to an electrode movement rail part of a headband main body in the EEG apparatus according to the present invention.
FIG. 7 is a perspective view illustrating an embodiment of a socket body in the EEG apparatus according to the present invention. FIG.
FIG. 8 is an exploded perspective view showing an embodiment of a side band member in the EEG apparatus according to the present invention. FIG.
9 is a perspective view showing an example in which a sideband body is assembled to a headband main body in the EEG apparatus according to the present invention.
FIG. 10 is a flowchart showing a method of measuring EEG using the EEG apparatus according to the present invention. FIG.

Hereinafter, the present invention will be described in more detail.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to the detailed description of the present invention, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

FIG. 1 is a perspective view illustrating an EEG apparatus according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view illustrating an EEG apparatus according to an embodiment of the present invention.

3 is a perspective view illustrating an embodiment of the band assembly 210 of the headband main body 200 in the EEG apparatus according to the present invention.

1 to 3, an EEG apparatus according to an embodiment of the present invention will be described in detail below.

One embodiment of the EEG apparatus according to the present invention includes a plurality of EEG electrodes 100 capable of measuring brain waves of an EEG measurer.

The electrode body for electroencephalogram measurement 100 may be movably coupled to the inner circumferential surface of the headband body 200 formed in a ring shape surrounding the head circumference of the examinee and moved along the inner circumferential surface of the head body.

And an electrode moving rail part 201 to which the electrode body 100 for EEG measurement is movably engaged is provided on the inner circumferential surface of the headband main body 200.

The electrode moving rail part 201 is formed to have a circular shape along the inner side surface of the headband main body 200 so that the electrode body for electroencephalogram measurement 100 is positioned in any direction in the 360 ° direction .

The electrode body for EEG 100 can be moved along the electrode moving rail part 201 and the position can be freely adjusted according to the person to be examined so that the EEG signal required for the examination can be more accurately measured.

The electrode moving rail part 201 is formed with an inlet through which the electrode body for electroencephalogram measurement 100 can be inserted and inserted along the inner surface of the headband main body 200, Shaped space which can be inserted as far as possible, for example, a circular space.

The electrode moving rail part 201 is formed in a space in which the inside is hollow, for example, a space narrower than the circular space around the inner surface of the headband main body 200, And one end side of the electrode body for electroencephalogram measurement 100 is inserted into the space to be engaged.

The electrode moving rail part 201 is formed in an empty shape so that the movement of the electric wire 101 connected to the electrode body for electroencephalogram measurement 100 is not obstructed and the electrode body for electroencephalogram measurement 100 is smooth To be moved.

That is, the electrode body for electroencephalogram measurement 100 can move from the frontal lobe position to the temporal lobe position.

The reference electrode and the ground electrode are positioned on the lower surface of the headband body 200 so as to face each other and can be easily brought into contact with the body of the examinee with a known forceps electrode to easily measure a biological signal such as brain waves .

The electrode body for electroencephalography (EEG) 100 includes a plurality of active electrodes which are in contact with the body of the examinee to measure bio-signals such as electroencephalograms. The electrodes include an active electrode, a reference electrode, It is noted that measuring and checking signals are well known in the art and are not described in further detail herein.

The electrode body 100 for EEG measurement is connected to a terminal such as a PC capable of analyzing the measured signal, and transmits the measured body signal to the terminal.

The headband main body 200 can be worn so as to pass through a part used for EEG measurement in the head of the examinee so that it can be easily used at home.

In addition, the headband main body 200 is divided into four parts by four spaced apart points of Fpz, T7, Oz and T8, and at least one electrode body 100 for EEG measurement is inserted into each part, The EEPROM 100 can be freely moved in each divided part to adjust the detection position. When the detection position is designated, the position is fixed and the body signal such as brain waves is measured and detected at a fixed position do.

The headband main body 200 includes a plurality of band assemblies 210 detachably coupled to each other to adjust the size according to the head size of the test subject.

The headband main body 200 is divided into ten band assemblies 210 and can be assembled to a size suitable for the head size of the subject to be inspected by selecting the number of assembled bodies according to the head size of the test subject.

The band assembly 210 is provided with a coupling protrusion 211 at one end and a fitting groove 212 to which the coupling protrusion 211 is detachably fitted at the other end.

The coupling protrusions 211 and the fitting grooves 212 are positioned between the outer side of the band assembly 210 and the electrode moving rail part 201 at both ends of the band assembly 210, 100 so as not to disturb the movement of the electric wire 101 during the movement thereof.

The plurality of band assemblies 210 are coupled to each other by engaging the protrusions 211 of one of the band assemblies 210 with the fitting grooves 212 of the other band assembly 210 to form the annular headband body 200, .

In addition, the headband main body 200 is configured so that the position is displayed at a ratio of 10% and 20% based on the 10/20 electrode arrangement method. When the size is adjusted to the head size of the subject, Lt; / RTI > For example, the plurality of band assemblies 210 may be constructed of a flexible material, such as a sponge, to facilitate adjustment to the size of the subject's head.

The headband main body 200 is provided with ten size adjustment display portions, and each band assembly 210 is assembled at the boundaries of the respective size adjustment display portions.

That is, the headband main body 200 is divided into 10 or 20 band assemblies 210, and 10% and 20% of the 10 or 20 band assemblies 210 are assembled according to the size of the subject's head, The ratio of the standard electrode arrangement method can be maintained when the size is adjusted to the size of the subject's head.

Each of the band assemblies 210 is marked by a unit so that the headband body 200 can be assembled with an exact dimension. If the same band is inspected by another person at the same position, It is possible to inspect or test it.

The EEG apparatus according to the present invention includes a socket body 300 provided in the headband main body 200 and having a plurality of sockets 310 connected to the electrode body 100 for EEG measurement by a wire 101, As shown in FIG.

The socket 310 is provided with an amplifying unit for amplifying a living body signal measured by the electrode body for EEG 100 and a filter unit for filtering a living body signal.

The socket body 300 is positioned at the back of the headband body 200. The electrode body for electroencephalogram measurement 100 is connected to a terminal such as a PC capable of analyzing the measured signal, .

That is, when the socket 310 is connected, the socket body 300 delivers the filtered signal to a terminal such as a PC capable of analyzing the measured signal.

Meanwhile, FIG. 4 is a perspective view showing an embodiment of the electrode body 100 for EEG measurement in the EEG apparatus according to the present invention.

Referring to FIG. 4, the electrode assembly for electroencephalogram (EEG) 100 includes an electrode mounting portion 111 having an electrode at one end and a rail coupling And a plurality of active electrode members 120 provided on the electrode mounting portion 111. The body 110 may include a plurality of active electrode members 120,

In the electrode mounting body member 110, a wire passage 110a through which an electric wire 101 electrically connected to a plurality of active electrode members provided on one side of the one end of the electrode mounting portion 111 can pass, .

Information transmission means other than wires, such as conductive patterns, can cause damage to minute biological signals during transmission. Therefore, in order to accurately transmit bio-signal information such as a small brain wave or the like, a wire system is employed in which the active electrode member 120 is connected to the control unit through the wire 101. In order to minimize the disconnection and damage of the electric wires 101 at both ends of the electric wire 101, which is a problem in using the electric wire, the electric wire 101 is inserted into a space of a thin cylindrical shape inside the electrode mounting body member 110 Thereby forming a wire passage 110a through which the wire 101 is not only fixed but also the lead wire of the electrode is pulled into the electrode mounting body member 110 to simplify the structure.

A rail penetration portion 113 having a diameter capable of passing through the entrance of the electrode movement rail portion 201 is provided between the electrode mounting portion 111 and the rail coupling portion 112.

The rail engaging portion 112 has a width enough to pass through the entrance of the electrode moving rail portion 201 and is formed in the electrode moving rail portion 201 so as to have a length at which both ends can be caught at the entrance do.

The electrode body for electroencephalogram measurement 100 is connected to the socket body 300 through the electric wire 101 and transmits a bio-signal measured through the electric wire 101 to the terminal through the socket body 300 .

The electrode body 100 for EEG measurement is connected to the socket body 300 using the electric wire 101 which can minimize the signal attenuation for the transmission of EEG signals and can realize a short length to reduce signal attenuation .

That is, in order to minimize signal attenuation due to a minute bio-signal according to the present invention, a wire is adopted as a signal transmission means. When a biological signal is transmitted through a conductive pattern, In particular, a slight loss in the transmission of a fine EEG signal can have a great influence on the EEG restoration signal.

The limit that can be caused by using the electric wire 101 is sensitive to the damage of the joint portion between the electric wire 101 and the circuit board or the like. In order to solve this problem, the present invention includes an electrode mounting body member 110 that can stably fix the end of the electric wire 101 to prevent damage.

The socket body 300 may be connected to the electrode body 100 for measuring EEG using a wire 101 positioned at the back of the headband body 200 and having the shortest length. That is, the electrode body 100 for EEG measurement is connected to the socket body 300 for transmitting the measured signal to the terminal after amplifying and filtering the signal, and is connected to the wire 101 having the shortest length to minimize the loss of the fine EEG signal.

5 and 6 are enlarged perspective views illustrating an example in which an electrode body 100 for EEG measurement in a brain wave measuring apparatus according to the present invention is movably coupled to an electrode moving rail part 201 of a headband main body 200 .

5 and 6, the electrode assembly 100 for electroencephalogram measurement, which is separated from the electrode moving rail part 201, is formed by laminating the rail engaging part 112 in the width direction, The rail engaging portion 112 is vertically erected so that both end portions of the rail engaging portion 112 are engaged with the entrance and are held in a state of being coupled to the electrode moving rail portion 201. [

In contrast, the electrode body for electroencephalogram measurement 100 coupled to the electrode moving rail part 201 is rotated at a 90-degree radius to lay down the rail engaging part 112 in the width direction, And is easily separated from the rail coupling portion 112 while passing through the entrance.

The electrode body 100 for EEG measurement can be easily coupled to or separated from the electrode moving rail part 201 by the above-described method.

FIG. 7 is a perspective view illustrating an embodiment of a socket body 300 in the EEG apparatus according to the present invention. FIG. 7 is a perspective view illustrating a socket body 300 in which a socket body 300, (301) is provided.

The socket body 300 is provided with a plurality of socket inserting portions 301 capable of detachably connecting the sockets 310 and has 12 socket inserting portions 301 according to the present invention.

In addition, the socket 310 is provided with a terminal coupling groove 311 which can be detachably coupled to the electric wire 101 connected to the electrode body 100 for EEG measurement. A terminal portion 101a which is coupled to the terminal coupling groove 311 and is electrically connected to the socket 310 is provided at an end of the electric wire 101 connected to the electrode body 100 for EEG measurement.

When the terminal portion 101a is inserted into the terminal fitting groove 311 of the socket 310 and the socket 310 is connected to the socket inserting portion 301, The signal (EEG) is transmitted to the PC after noise and unnecessary signal are removed through the amplification section and the filter section, and it is used for EEG analysis.

The present invention realizes a socket type channel changing system through a socket body 300. In the socket type channel changing system, the number of channels is determined according to the number of electrodes of the electrode body for electroencephalogram measurement 100, One channel per electrode and one amplification filter are required. For example, to implement a four-channel socket-based channel changing system, four electrodes are required, and two sockets each with two amplification filters are required to filter the signals obtained from these electrodes.

The socket body 300 constitutes a two-channel circuit for each socket 310 and can increase or decrease the socket 310 according to the number of channels and can use up to 24 channels to locally measure a part to be measured . Therefore, since the spatial resolution is increased, more accurate and highly reliable information can be obtained.

That is, the socket body 300 is a channel changing system using a socket-type module, and a signal processing circuit is added according to the number of desired channels, thereby eliminating the limit of the number of channels and changing the channel easily.

On the other hand, when the number of channels is fixed, a channel that is not used is unnecessarily provided, which may increase the weight of the headband main body 200 and increase the manufacturing cost.

FIG. 8 is an exploded perspective view illustrating an embodiment of a side band member in the EEG apparatus according to the present invention, FIG. 9 is a view showing an example of assembling the side band member to the headband main body 200 in the EEG apparatus according to the present invention Fig.

The EEG measuring device according to the present invention has both end portions connected to the headband main body 200 and each of which is bent to wrap the upper side of the head of the examinee and has a side band And a band coupling part 500 coupling the main body 400 and the side band body 400 to the headband main body 200.

The band coupling part 500 is a Velcro tape provided on both end sides of the side band body 400 as an example. The other end of the side band body 400 and the other side of the head band main body 200 are provided with a male velcro tape, So that the side band body 400 can be attached to the headband body 200 while the male velcro tape is attached to the arm velcro tape.

In addition, since the side band body 400 is attached to the headband body 200 using Velcro tape, it can be easily separated after use and simply mounted on the headband body 200 only when necessary.

The side band body 400 is provided with an electrode guide rail 401 to which the electrode body 100 for electroencephalogram measurement is movably coupled to the inner surface of the side band body 400. The position of the electrode body 100 for EEG measurement is measured It can be adjusted according to the condition.

The side band body 400 has a first side band member 410 and a second side band member 410. The first side band member 410 is connected to the headband body 200 at both ends thereof and is bent to wrap the upper side of the subject's head. And a second side band member 420 which is connected to the head band body 200 at both ends and which is bent to wrap the upper side of the subject's head.

At least one of the first side band member 410 and the second side band member 420 is provided with the other of the first side band member 410 and the second side band member 420 The side band fitting grooves 411 are provided so that the positions of the first side band member 410 and the second side band member 420 can be more firmly fixed.

In the present invention, the lower side of the first side band member 410 and the upper side of the second side band member 420 are provided with band fitting grooves 411, respectively, so that the first side band member 410 and the second side band The members 420 are firmly coupled to each other at the intersections through the band fitting grooves 411.

The first side band member 410 and the second side band member 420 are each provided with an electrode guide rail 401 on the inner side and a band coupling part 500, .

The electrode body 100 for EEG measurement is moved along the electrode guide rail 401 so that the position can be freely adjusted according to the person to be inspected and the EEG signal required for the examination can be more accurately measured.

The electrode guide rail part 401 is formed with an inlet which can be engaged by inserting the electrode body for electroencephalogram measurement 100 along the inner side surface of the side band body 400 and the electrode body 100 for electroencephalogram measurement is movable For example, a circular space.

The electrode guide rail part 401 is formed in a space in which the inside is hollow, for example, a space narrower than a circular space is formed around the inner surface of the headband main body 200, One end side of the electrode body for electroencephalogram measurement 100 is inserted and engaged.

That is, the electrode guide rail part 401 is formed in the same shape as the electrode moving rail part 201 formed on the headband main body 200, and the electrode body 100 for EEG measurement is formed in the electrode moving rail part 201 They can be joined or separated at the electrode guide rail 401 with the same principle as that of the coupling and separation.

That is, although not shown, the EEG electrode 100 for EEG measurement, which is separated from the electrode guide rail 401, lays the rail coupling part 112 in the width direction, When the rail coupling part 112 is vertically erected, the both ends of the rail coupling part 112 are engaged with the inlet and are coupled to the electrode guide rail part 401 Lt; / RTI >

The electrode body 100 for EEG measurement in a state of being coupled to the electrode guide rail part 401 is rotated at a 90 degree radius so that the rail coupling part 112 is laid down in the width direction, And is easily separated from the rail coupling portion 112 while passing through the entrance.

The electrode body 100 for EEG measurement can be simply coupled to or separated from the electrode guide rail 401 in the same manner as described above.

The side band body 400 allows a plurality of EEG electrodes 100 to be spaced apart from each other over the entire head of the examinee so that the EEG signal can be measured at more positions, It is possible to measure the biological signal and to obtain more information about the body signal of the examinee.

10 is a flowchart illustrating an EEG measurement method using the EEG apparatus according to the present invention. Referring to FIG. 10, the EEG measurement method according to the present invention includes an electrode body 100 for an EEG measurement, A method of measuring EEG using an EEG measurement apparatus including a headband body (200), comprising: positioning an electrode body (100) for adjusting EEG by adjusting an electrode position (S200); And an electroencephalogram measurement step (S300) of measuring an EEG by applying an electric power to an electrode member for EEG measurement after the electrode positioning step (S200).

In addition, the EEG measuring method according to the present invention may further include a band size adjusting step (S100) of adjusting the size of the headband main body 200 according to the head size of the subject before the electrode positioning step S200.

The EEG measurement method according to the present invention is a method for measuring EEG using the EEG apparatus according to the present invention.

That is, in the band size adjustment step S100, the number of the ten or twenty band assemblies 210 detachably coupled to each other is selected and assembled in accordance with the head size of the test subject, The band body 200 is assembled.

The electrode positioning step S200 moves the plurality of EEG electrodes 100 along the electrode moving rail part 201 provided on the inner circumferential surface of the headband main body 200 to form an EEG electrode 100 ) Can freely adjust the examination position for measuring the biological signal.

In the EEG measurement step S300, a signal sensed by the active electrode member 120 of the electrode body 100 for electroencephalogram measurement is transmitted to the socket body 300, and a bio-signal (brain wave) measured by the socket body 300 After removing the noise and unnecessary signals through the amplification part and the filter part, it is transmitted to the PC and used for EEG analysis.

According to the present invention, the position of the electrode for EEG measurement can be changed according to the patient, the channel can be changed, and the accurate EEG according to the patient can be measured, thereby improving the reliability in EEG measurement.

The present invention can be applied to various fields of application, enabling detection of brain waves in various parts of the brain, thereby contributing to research on the mechanism of the brain, and contributing to the convenience of individual users.

In addition, the present invention can reduce the burden of continuously receiving a hospital or a treatment center for diagnosis by receiving information from a home for patients with cranial nerve diseases through popularization of a portable (public) EEG device and a control device, Contributing to society and making it available.

It will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

100: Electrode for EEG 101: Wires
101a: Terminal part 110: Electrode mounting body member
110a: electric wire passage 111: electrode mounting portion
112: rail coupling portion 113: rail penetration portion
120: active electrode member 200: headband body
201: electrode moving rail part 210: band assembly
211: engaging projection 212: engaging groove
300: socket body 301: socket inserting part
310: socket 311: terminal coupling groove
400: Side band body 401: Electrode guide rail part
410: first side band member 411: side band fitting groove portion
420: second side band member 500: band bonding part
510: Velcro tape S100: Band size adjustment step
S200: Electrode positioning step S300: EEG measurement step

Claims (23)

A plurality of electroencephalogram electrodes for measuring brain waves of an EEG measurer; And
And a headband body which is formed in a ring shape surrounding the head circumference of the subject and has an electrode moving rail portion in which a plurality of the electrode-measuring electrodes for movement is coupled to the inner circumferential surface. The method according to claim 1,
Wherein an electrode moving rail part is provided on an inner circumferential surface of the headband main body so that the electrode body for EEG motion is movably coupled. The method of claim 2,
Wherein the electrode moving rail portion has an inlet formed by inserting the electrode body for EEG measurement along the inner circumference of the headband body and an inner space through which the electrode body for EEG measurement can be movably inserted is empty Wherein the one end side of the electrode body for electroencephalogram measurement is formed in a space having an empty space inside and is formed so as to be caught by the entrance. The method according to claim 1,
Wherein the headband body includes a plurality of band assemblies detachably coupled to each other. The method of claim 4,
Wherein the band assembly is provided with a coupling protrusion at one end thereof and a fitting groove into which the coupling protrusion is detachably fitted to the other side of the band assembly. The method of claim 5,
An electrode moving rail portion to which the electrode for electroencephalogram measurement is movably coupled is provided on an inner circumferential surface of the headband main body,
Wherein the coupling protrusions and the fitting grooves are located between the outer surface of the band assembly and the electrode moving rail portion at both end portions of the band assembly. The method of claim 3,
The electrode for electroencephalogram measurement is characterized in that,
An electrode mounting body member having an electrode mounting portion having an electrode at one end and a rail coupling portion movably coupled at the other end to the electrode moving rail;
A plurality of active electrode members provided on the electrode mounting portion; And
And a rail penetrating part provided between the electrode mounting part and the rail coupling part and having a diameter capable of passing through an entrance of the electrode moving rail part. The method according to claim 1,
Further comprising a socket body provided in the headband main body and in which a plurality of sockets connected to the electrode body for EEG measurement and a wire are detachably coupled,
Wherein the socket is provided with an amplification unit for amplifying a bio-signal measured by the electrode body for electroencephalogram measurement and a filter unit for filtering a bio-signal. The method according to claim 1,
A side band body connected to the headband body at both end sides, each of the side band bodies being bent to wrap the upper side of the head of the examinee and having the electrode body for measuring EEG on the inner side; And
And a band coupling unit coupling the sideband body to the headband body. The method of claim 9,
Wherein the sideband body includes an electrode guide rail portion on an inner surface thereof to which the electrode body for EEG motion is movably coupled. The method of claim 10,
Wherein the electrode guide rail portion has an inlet formed by inserting the electrode body for electroencephalogram measurement along the inner surface of the side band body, Wherein the EEG electrode is formed in an empty space, and the one end side of the electrode body for EEG measurement is inserted into the space of the empty space. The method of claim 9,
The side band body includes:
A first side band member which is connected to the head band body at both end sides and which is bent to wrap the upper side of the subject's head; And
And a second side band member positioned to intersect with the first side band member and connected to the head band body at both end sides and bent to wrap the upper side of the subject's head. A plurality of electroencephalogram electrodes for measuring brain waves of an EEG measurer; And
And a headband main body formed in a ring shape surrounding the head circumference of the subject to be examined and having a plurality of the electrode-measuring electrodes for the brain wave measurement,
Wherein the headband body includes a plurality of band assemblies detachably coupled to each other. 14. The method of claim 13,
Wherein the band assembly is provided with a coupling protrusion at one end and a fitting groove into which the coupling protrusion is detachably fitted to the other end. 14. The method of claim 13,
Further comprising a socket body provided in the headband main body and in which a plurality of sockets connected to the electrode body for EEG measurement and a wire are detachably coupled,
Wherein the socket is provided with an amplification unit for amplifying a bio-signal measured by the electrode body for electroencephalogram measurement and a filter unit for filtering a bio-signal. 16. The method of claim 15,
Wherein the socket body is provided with a plurality of socket inserting portions capable of detachably connecting the socket. 14. The method of claim 13,
A side band body connected to the headband body at both end sides, each of the side band bodies being bent to wrap the upper side of the head of the examinee and having the electrode body for measuring EEG on the inner side; And
And a band coupling unit coupling the sideband body to the headband body. 18. The method of claim 17,
Wherein the sideband body includes an electrode guide rail portion on an inner surface thereof to which the electrode body for EEG motion is movably coupled. 19. The method of claim 18,
Wherein the electrode guide rail portion has an inlet formed by inserting the electrode body for electroencephalogram measurement along the inner surface of the side band body, Wherein the EEG electrode is formed in an empty space, and the one end side of the electrode body for EEG measurement is inserted into the space of the empty space. 19. The method of claim 18,
Wherein the side band body is connected to the headband body at both ends thereof and is bent to wrap the upper side of the subject's head; And
And a second side band member positioned to intersect with the first side band member and connected to the head band body at both end sides and bent to wrap the upper side of the subject's head. The method of claim 20,
Wherein at least one of the first side band member and the second side band member has a side band fitting groove which can be engaged with the other side of the first side band member and the second side band member, Wherein the electroencephalogram measuring device comprises: An electrode positioning step of adjusting and fixing the position of the electrode body for EEG measurement provided on the inner circumferential surface of the headband body surrounding the head circumference of the subject to be examined; And
And measuring an EEG by applying an electric power to the EEG electrode member after the electrode positioning step. 23. The method of claim 22,
Further comprising a band size adjusting step of adjusting a size of the headband body in accordance with a head size of the subject before the electrode positioning step.

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