JP6888355B2 - EEG measuring device, EEG measuring method and EEG measuring program - Google Patents

Description

The present invention relates to an electroencephalogram measuring device, an electroencephalogram measuring method, and an electroencephalogram measuring program.

Conventionally, when performing electroencephalogram measurement, it is necessary to arrange the electrode at an appropriate position on the head of the person to be measured. For example, for the purpose of easily arranging the electrode at the appropriate position, the electrode is placed at a predetermined position. The headset or the like provided in is used. Specifically, a headset that sandwiches the user's head at three locations, a first headband portion, a second headband portion, and a third headband portion, is disclosed (for example, a patent). Reference 1). This headset is provided with electrodes in each headband portion.

Japanese Unexamined Patent Publication No. 2013-85621

However, even if the headset disclosed in Patent Document 1 is used, the shape and size of the head of the person to be measured vary from person to person. Therefore, depending on the person to be measured, the head may be positioned at an appropriate position. There was a problem that it was not possible to measure the brain waves of.

The present invention has been made in view of such a problem, and an object of the present invention is to enable measurement of an electroencephalogram at an appropriate position of the head.

In order to solve the above problems, the electroencephalogram measuring device according to the present invention is used.
A first detector that detects an electrical signal emitted from a specific part of the user,
A second detection unit that detects an electrical signal emitted from at least one part of the user's head, which is different from the specific part.
A control device that calculates the correlation coefficient between the electric signal detected by the first detection unit and the electric signal detected by the second detection unit and outputs information based on the correlation coefficient.
Equipped with a,
The first detection unit detects an electric signal emitted from the cochlea of the user as the specific site, and detects the electric signal.
The second detection unit detects an electric signal emitted from the auditory cortex of the user's head at a specific place having the relatively largest correlation coefficient among the plurality of places of the user's head. To do,
It is characterized by that.

According to the present invention, it is possible to measure an electroencephalogram at an appropriate position on the head.

It is a figure which shows the appearance of the electroencephalogram measuring device which concerns on this embodiment, and is the perspective view which shows the state which the said electroencephalogram measuring device is attached to the head of a user. It is a figure which shows the structure of the adjustment part. It is a functional block diagram which shows the structure of the electroencephalogram measuring apparatus of FIG. 1 for each function. It is a flowchart which shows an example of the correlation mode processing. It is a figure which shows the display example of a level meter. (A) is a figure which shows an example of the electric signal detected by the sensor in an ear canal, (b) is a figure which shows an example of an electric signal detected by a head sensor. It is a perspective view which shows the head sensor unit which comprises the electroencephalogram measuring apparatus of the modification 1. It is a figure which shows the appearance of the electroencephalogram measuring apparatus of Embodiment 2, and is the perspective view which shows the state which the electroencephalogram measuring apparatus is attached to the head of a user.

Hereinafter, embodiments of the electroencephalogram measuring device, the electroencephalogram measuring method, and the electroencephalogram measuring program of the present invention will be described with reference to the drawings.

[Embodiment 1]
FIG. 1 is a view showing the appearance of the electroencephalogram measuring device 100 of the embodiment to which the present invention is applied, and is a perspective view showing a state in which the electroencephalogram measuring device 100 is attached to the user's head.
As shown in FIG. 1, the electroencephalogram measuring device 100 has a neckband type, and includes two sensor units 1, a neckband 2, and a controller unit 3. The neckband 2 is formed in a U shape, and a sensor unit 1 is provided at each end thereof, and a controller unit 3 is provided in the middle of the band.

As shown in FIG. 1, the two sensor units 1 are composed of a sensor unit 1A worn on the user's left ear and a sensor unit 1B worn on the right ear. Since the sensor unit 1A and the sensor unit 1B have substantially the same configurations except that the shape of the unit body 13 described later is symmetrical, the sensor unit 1A for the left ear will be described below, and the sensor unit 1A for the right ear will be described. The description of the sensor unit 1B will be omitted.

The sensor unit 1A includes an intraoural sensor (first detection unit) 11, a head sensor (second detection unit) 12, and a unit body (support member) 13.
The intraoural sensor 11 includes an electrode E, and when the electrode E is inserted into the user's ear canal, it is possible to detect an electric signal (see FIG. 6A) emitted from a cochlea (receptor). It has become. The electrode E is made of a conductive sponge.
Like the in-ear sensor 11, the head sensor 12 includes an electrode E made of a conductive sponge, and the electrode E is brought into contact with a predetermined position (near the temporal region) of the user's head. As a result, it is possible to detect an electric signal (see FIG. 6B) emitted from the contacted position.

The unit body 13 has an ear hook type so that it can be hung on the user's ear. The unit main body 13 holds the sensor 11 in the ear canal at one end thereof. Further, the unit main body 13 is provided with a grounding portion (earth) 131 at the other end, and noise such as static electricity is removed by bringing the grounding portion 131 into contact with the user's earlobe. Further, the unit main body 13 is provided with an adjusting portion 132 in the upper part in the middle of the hook, and holds the head sensor 12 via the adjusting portion 132.

FIG. 2 is a diagram illustrating the structure of the adjusting unit 132.
As shown in FIG. 2, the adjusting unit 132 includes a rotating mechanism ST1 that rotates the adjusting unit 132 itself with one end thereof as a fulcrum, and a slide mechanism ST2 that slides the head sensor 12 at the other end. .. The position of the head sensor 12 that comes into contact with the user's head can be adjusted by rotating the adjusting unit 132 itself by the rotating mechanism ST1 and sliding the head sensor 12 by the slide mechanism ST2. You can do it.

Further, the adjusting unit 132 is provided with a magnet m1 on the support portion of the rotating mechanism ST1 and has a Hall element at a position where the magnetism of the magnet m1 can be detected (for example, the lower part of the substrate built in the adjusting portion main body). h1 is provided so that the position (rotational position) of the adjusting unit 132 can be detected. Further, in the adjusting unit 132, a magnet m2 is provided in a guide (slide mechanism ST2) for guiding the slide of the head sensor 12, and a position where the magnetism of the magnet m2 can be detected (for example, built in the adjusting unit main body). A Hall element h2 is provided on the upper part of the substrate) so that the position (slide position) of the head sensor 12 can be detected. The magnets m1 and m2 and the Hall elements h1 and h2 provided in the adjusting unit 132 are provided to detect the position of the head sensor 12, but detect the position of the head sensor 12. The configuration for this is not limited to these magnets and Hall elements, and may be configured by using, for example, a rotary encoder or a linear encoder. Further, it may be configured by combining a magnet or a Hall element with a rotary encoder, a linear encoder or the like.

FIG. 3 is a functional block diagram showing the configuration of the electroencephalogram measuring device 100 for each function.
As shown in FIG. 3, the electroencephalogram measuring device 100 includes a control device 101, a storage device 102, an operation unit 103, a display unit 104, a sensor unit 105, a position detection unit 106, and a communication unit 107. ing. The control device 101, the storage device 102, the operation unit 103, the display unit 104, and the communication unit 107 are provided in the controller unit 3 shown in FIG.

The control device 101 controls the operation of each part of the electroencephalogram measuring device 100 by reading a program from the storage device 102 and executing the program. The control device 101 can be configured by a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like.

The storage device 102 stores a program that can be read by the control device 101. As the storage device 102, for example, a medium such as a flash memory can be used.
Further, the storage device 102 can write data or the like processed by the control device 101.

The operation unit 103 includes a power button (not shown) for switching the power ON / OFF of the controller unit 3, a cursor button related to a selection instruction such as a mode (for example, a correlation mode described later) and a function, and decision button data (all shown). The control device 101 controls each unit based on the instruction from the operation unit 103.

The display unit 104 performs various displays according to the display information instructed by the control device 101. The display unit 104 can be configured by, for example, an LCD (Liquid Crystal Display) or the like.

The sensor unit 105 includes an intraoural sensor 11 and a head sensor 12 according to the sensor unit 1A for the left ear, and an intraoural sensor 11 and a head sensor 12 according to the sensor unit 1B for the right ear. Each sensor detects the potential at predetermined intervals. Then, the detection data of the potential detected by each sensor is output to the control device 101.

The position detection unit 106 detects the position (adjustment position) of the head sensor 12. Specifically, the position detection unit 106 is composed of two Hall sensors (the above-mentioned Hall element h1 and magnet m1 and Hall element h2 and magnet m2), and the head is determined by the magnitude of magnetism detected by each Hall sensor. The rotation position and slide position of the Hall sensor 12 are detected.

The communication unit 107 outputs the acquired data to an external information terminal under the control of the control device 101. For example, a wired communication unit such as a USB terminal or a short distance such as Bluetooth (registered trademark). It is a communication unit that adopts the wireless communication standard.

Next, the correlation mode processing executed by the electroencephalogram measuring device 100 will be described with reference to FIG.
The correlation mode processing is started when the operation signal related to the transition instruction to the correlation mode output from the operation unit 103 based on the user operation is input to the control device 101. Here, the correlation mode is a mode used when adjusting the contact position of the head sensor 12 with respect to the head so that an electric signal (brain wave) emitted from the auditory cortex can be detected with high accuracy.

First, the control device 101 determines whether or not the operation signal related to the calculation instruction of the correlation coefficient output from the operation unit 103 is input based on the user operation (step S1).
If it is determined in step S1 that the operation signal related to the correlation coefficient calculation instruction has not been input (step S1; NO), the control device 101 skips steps S2 to S4 and proceeds to step S5. ..
On the other hand, when it is determined in step S1 that the operation signal related to the correlation coefficient calculation instruction has been input (step S1; YES), the control device 101 has the electrical signals of the intra-ear hole sensor 11 and the head sensor 12. (Step S2). Here, it is assumed that the electric signal is taken from the sensor 11 in the ear canal and the head sensor 12 of at least one of the sensor unit 1A for the left ear and the sensor unit 1B for the right ear. ..

Next, the control device 101 calculates the correlation coefficient of the electrical signals of the in-ear hole sensor 11 and the head sensor 12 captured in step S2 (step S3). Here, the correlation coefficient of the electrical signals of the intraoural sensor 11 and the head sensor 12 is calculated between the cochlea (receptor) and the auditory cortex via the neural network (auditory conduction path). This is because they are connected and have an influential relationship with each other. Since the method of calculating the correlation coefficient is a known technique, detailed description thereof will be omitted here.

Next, the control device 101 complements the calculated value of the correlation coefficient with the reference value of the level meter displayed on the display unit 104 and displays the value (step S4). Specifically, as shown in FIG. 5, the level for the left ear represents the level of the correlation coefficient of each other's electrical signals taken from each of the sensor 11 and the head sensor 12 related to the sensor unit 1A for the left ear. The meter L1 and the right ear level meter L2 indicating the level of the correlation coefficient of each other's electrical signals taken from each of the sensor 11 related to the right ear sensor unit 1B and the head sensor 12 are displayed on the display unit 104. It is supposed to be displayed. Both the level meter L1 for the left ear and the level meter L2 for the right ear can display from level 0 to level 10, and when the value of the correlation coefficient (hereinafter referred to as │r│) is 0, the level is 0. Level 1 when 0 <│r│≤0.1, level 2 when 0.1 <│r│≤0.2, ..., Level 10 when 0.9 <│r│≤1.0 It is complemented with and displayed. That is, the contact position of the head sensor 12 with respect to the head can accurately detect the electric signal (brain wave) emitted from the auditory cortex according to the degree of the level displayed on the level meters L1 and L2. Whether or not it is.

Next, the control device 101 determines whether or not the operation signal related to the end instruction of the correlation mode output from the operation unit 103 is input based on the user operation (step S5).
If it is determined in step S5 that the operation signal related to the end instruction of the correlation mode has not been input (step S5; NO), the control device 101 shifts to step S1.
On the other hand, when it is determined in step S5 that the operation signal related to the end instruction of the correlation mode has been input (step S5; YES), the control device 101 ends the correlation mode processing.

As described above, the brain wave measuring device 100 of the present embodiment includes an intraoural sensor (first detection unit) 11 that detects an electric signal emitted from a specific part (cochlear (receptor)) of the user and the specific part. The control device 101 includes a head sensor (second detection unit) 12 for detecting an electric signal emitted from at least one part of the user's head, which is different from the part of the control device 101, and a control device 101. The correlation coefficient between the electric signal detected from the in-ear sensor 11 and the electric signal detected from the head sensor 12 is calculated, and the calculation result (level meter) of the correlation coefficient is displayed on the display unit (display means) 104. It means that it is displayed.

Therefore, based on the calculation result of the correlation coefficient, it is determined whether or not the contact position of the head sensor 12 with respect to the head is a position where an electric signal (brain wave) emitted from the auditory cortex can be detected with high accuracy. You can judge. As a result, the position of the head sensor 12 capable of accurately detecting the electric signal emitted from the auditory cortex can be derived, so that the brain wave at an appropriate position corresponding to the auditory cortex of the head can be derived. Can be measured.
As a result, the electric signal emitted from the auditory cortex can be detected with high accuracy, and the electric signal emitted from the cochlea connected to the auditory cortex can also be detected. Therefore, it becomes possible to understand how the sound (external stimulus) is converted into the electric signal based on the electric signal emitted from the cochlea, and the sound is transmitted in the auditory cortex based on the electric signal emitted from the auditory cortex. You will be able to see how it will be processed in the end.
Furthermore, since the electrical signal emitted from the cochlea and the electrical signal emitted from the auditory cortex can be detected at the same time, it is possible to guess how the electrical signal emitted from the cochlea will be converted before reaching the auditory cortex. You will be able to.

Further, in the electroencephalogram measuring device 100 of the present embodiment, the unit body (support member) 13 that holds the head sensor 12 in a state where the head sensor 12 is in contact with a predetermined position of the head, and the unit body 13 It is provided with an adjusting unit 132 that adjusts the position of the head sensor 12 held by the user based on a user operation.
Therefore, by bringing the head sensor 12 into contact with a predetermined position on the head, an appropriate position can be estimated in advance. Then, since the position of the head sensor 12 is adjusted by the adjusting unit 132, the position where the electric signal emitted from the auditory cortex can be detected with high accuracy can be efficiently derived.

[Modification 1]
In the electroencephalogram measuring device 100, instead of providing the adjusting unit 132 on the unit main body 13, a head sensor unit 133 in which a plurality of head sensors 12, ... Are integrated may be provided.
Specifically, as shown in FIG. 7, for example, a T-shaped head sensor unit 133 in which four head sensors 12 are arranged in a horizontal row is provided on the upper part of the hook of the unit main body 13. In the case of this modification 1, one head sensor 12 is designated from the four head sensors 12 based on the user operation, and the electric signal emitted from the head is detected by the designated one head sensor 12. .. That is, by switching one head sensor 12 designated based on the user operation, the detection position of the electric signal can be adjusted without adjusting the position of the head sensor 12 by the adjusting unit 132.
The head sensor unit 133 shown in FIG. 7 is only an example, and the number and layout of the head sensors 12 arranged in this unit can be changed as appropriate.

[Embodiment 2]
Next, the second embodiment will be described. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.
The electroencephalogram measuring device 200 of the second embodiment calculates a correlation coefficient between an electric signal emitted from the retina (receptor) and an electric signal emitted from a predetermined position (near the occipital region) of the head, and the correlation coefficient is calculated. Is different from the first embodiment in that the calculation result of the above is displayed on the display unit 104.

FIG. 8 is a diagram showing the appearance of the electroencephalogram measuring device 200 of the second embodiment, and is a perspective view showing a state in which the electroencephalogram measuring device 200 is attached to the user's head.
As shown in FIG. 8, the electroencephalogram measuring device 200 has a spectacle shape, and includes two retinal sensors 14, a head sensor 12 paired with each retinal sensor 14, a frame 202, and a controller unit 3. I have.

The frame 202 is formed in a spectacle shape, and each retinal sensor 14 is provided at a position facing the user's eyes, and each head sensor 12 is provided at a predetermined position (near the back of the head) of the user's head. Further, a controller unit 3 is provided in the middle of the temple on the left side (the vine of the frame 202).

Like other sensors, the retina sensor 14 includes an electrode E, and when the electrode E comes into contact with the user's eyelids or the like, it is possible to detect an electric signal emitted from the retina.
The head sensor 12 can detect an electric signal emitted from the visual cortex when the electrode E is brought into contact with a predetermined position (near the back of the head) of the user's head.

As described above, the brain wave measuring device 200 of the present embodiment includes a retinal sensor (first detection unit) 14 that detects an electric signal emitted from a specific part (retina (receptor)) of the user and the specific part. A head sensor (second detection unit) 12 for detecting an electric signal emitted from at least one part of the user's head, which is different from the part, and a control device 101 are provided, and the control device 101 is a retina. The correlation coefficient between the electric signal detected by the sensor 14 and the electric signal detected by the head sensor 12 is calculated, and the calculation result (level meter) of the correlation coefficient is displayed on the display unit (display means) 104. It means that.
Therefore, based on the calculation result of the correlation coefficient, it is determined whether or not the contact position of the head sensor 12 with respect to the head is a position where an electric signal (brain wave) emitted from the visual cortex can be detected with high accuracy. You can judge. As a result, the position of the head sensor 12 capable of accurately detecting the electric signal emitted from the visual cortex can be derived, so that the brain wave at an appropriate position corresponding to the visual cortex of the head can be derived. Can be measured.

Although the embodiments of the present invention have been described above, it goes without saying that the present invention is not limited to such embodiments and can be variously modified without departing from the gist thereof.

For example, in the first embodiment, the electric signal generated from the cochlear is detected, and in the second embodiment, the electric signal generated from the retina is detected. May be a receptor, for example, an electrical signal emitted from an olfactory cell, which is an olfactory receptor, or a taste bud, which is a taste receptor.

Further, in the first and second embodiments, the calculation result (level meter) of the correlation coefficient calculated by the control device 101 is displayed on the display unit 104, but the external information terminal is displayed via the communication unit 107. The calculation result (level meter) may be displayed on the display unit of. As a result, for example, the person to be measured can also confirm the calculation result.

Further, in the first and second embodiments, when an appropriate position for bringing the head sensor 12 into contact with the head is derived in the correlation mode processing, for example, the head is headed by the operation unit 103 based on the user operation. When the operation signal related to the storage instruction of the adjustment position of the unit sensor 12 is input, the control device 101 acquires the adjustment position information indicating the adjustment position of the head sensor 12 from the position detection unit 106 and stores it in the storage device 102. You may let it. Further, in the first modification, when the operation signal related to the memory instruction of the adjustment position of the head sensor 12 is input from the operation unit 103 based on the user operation, the control device 101 is designated at this time. The designated information indicating the head sensor 12 is acquired and stored in the storage device 102.
As a result, in the first and second embodiments, the head sensor 12 can be easily adjusted to an appropriate position based on the adjustment position information stored in the storage device 102 the next time the user measures the brain wave. it can. Further, in the first modification, one head sensor 12 capable of accurately detecting an electric signal based on the designated information stored in the storage device 102 can be easily selected from the head sensor unit 133. ..

When the electroencephalogram measuring device is expected to be used by a plurality of users, the identification information (for example, the user ID) that identifies the user when the adjustment position information and the designated information are stored in the storage device 102. ) May be associated and stored. Further, in the above-mentioned electroencephalogram measuring device, an actuator is provided, and the next time the user measures the electroencephalogram, the actuator is operated based on the adjustment position information stored in the storage device 102, and the head sensor 12 is appropriately used. It may be possible to automatically set the position.

Further, in the first and second embodiments and the first modification, the display unit 104 may display a message according to the calculation result of the correlation coefficient together with or instead of the display by the level meter. .. For example, if the calculated correlation coefficient value │r│ is greater than or equal to a predetermined threshold value (for example, 0.5), a message such as "It is an appropriate position" is displayed, but it is less than the predetermined threshold value. If so, display a message such as "Please change the position of the head sensor."
As a result, even an inexperienced user can use the electroencephalogram measuring device appropriately and easily.

Further, in the first and second embodiments and the first modification, a sound output unit is provided, and a sound according to the calculation result of the correlation coefficient is output together with or instead of the display by the level meter. It may be output from. For example, the volume of the above sound is changed and output in proportion to the calculated value of the correlation coefficient │r│.

Further, in the first embodiment and the first modification, a sound output unit capable of outputting a sound having a predetermined frequency (for example, 1 kHz) is provided, and in the correlation mode processing, when an electric signal is taken from the sensor 11 in the ear canal. , The sound of the above-mentioned predetermined frequency may be output from the sound output unit under the control of the control device 101. The sound output unit is provided, for example, in the vicinity of the sensor 11 in the ear canal at one end of the unit body 13.
As a result, the cochlea can be stimulated to easily generate an electric signal from the cochlea, so that the correlation coefficient can be preferably calculated. As a result, it is possible to easily derive an appropriate position for bringing the head sensor 12 into contact with the head.
The sound of a predetermined frequency to be output from the sound output unit may be provided with a plurality of sounds having different frequencies from each other, and a sound having a frequency that is easy for the user to hear may be specified so that the sound is output from the sound output unit. May be good.

Further, in the first and second embodiments, in the correlation mode processing, for example, the control device 101 calculates the correlation coefficient each time the contact position of the head sensor 12 is adjusted by the user, and the correlation coefficient is calculated. The value is temporarily stored in association with the adjustment position of the head sensor 12. Then, when the adjustment of the contact position is completed, the control device 101 selects the maximum value from the values of the correlation coefficient stored at this time and associates it with the maximum value. The adjustment position of the head sensor 12 may be displayed on the display unit 104.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited to the above-described embodiments, and the scope of the invention described in the claims includes the equivalent scope thereof.
The inventions described in the claims originally attached to the application of this application are added below. The claims in the appendix are as specified in the claims originally attached to the application for this application.

[Additional Notes]
<Claim 1>
A first detector that detects an electrical signal emitted from a specific part of the user,
A second detection unit that detects an electrical signal emitted from at least one part of the user's head, which is different from the specific part.
A control device that calculates the correlation coefficient between the electric signal detected by the first detection unit and the electric signal detected by the second detection unit and outputs information based on the correlation coefficient.
An electroencephalogram measuring device characterized by comprising.
<Claim 2>
Equipped with a display
The electroencephalogram measuring device according to claim 1, wherein the control device is controlled so that the display unit displays information corresponding to the correlation coefficient.
<Claim 3>
A support member that holds the second detection unit in a state where the second detection unit is in contact with a predetermined position on the head, and
An adjustment unit that adjusts the position of the second detection unit held by the support member based on user operation, and an adjustment unit.
The electroencephalogram measuring device according to claim 1 or 2, wherein the device comprises.
<Claim 4>
A position detection unit that detects the adjustment position of the second detection unit adjusted by the adjustment unit, and
A storage device that stores adjustment position information indicating the adjustment position detected by the position detection unit, and
The electroencephalogram measuring device according to claim 3, further comprising.
<Claim 5>
The second detection unit is composed of a plurality of parts.
A support member that holds the plurality of second detection portions in a state where the plurality of second detection portions are brought into contact with a predetermined position on the head.
A designation unit that designates one second detection unit to be detected of the electric signal from the plurality of second detection units based on a user operation, and a designation unit.
The electroencephalogram measuring device according to any one of claims 1 to 4, wherein the electroencephalogram measuring device is provided.
<Claim 6>
The electroencephalogram measuring device according to claim 5, further comprising a storage device that stores designated information indicating the first and second detection units designated by the designated unit.
<Claim 7>
The first detection unit detects an electric signal emitted from the cochlea of the user as the specific site, and detects the electric signal.
The second detection unit detects an electric signal emitted from the auditory cortex of the user's head at a specific place having the relatively largest correlation coefficient among the plurality of places of the user's head. The electroencephalogram measuring device according to any one of claims 1 to 6, wherein the electroencephalogram measuring device is characterized.
<Claim 8>
The electroencephalogram measuring device according to claim 7, further comprising a sound output unit that outputs a sound having a predetermined frequency when the first detection unit detects the electric signal.
<Claim 9>
It is an electroencephalogram measuring method in an electroencephalogram measuring device.
The electroencephalogram measuring device is
A first detector that detects an electrical signal emitted from a specific part of the user,
A second detection unit that detects an electric signal emitted from at least one part of the user's head, which is different from the specific part, is provided.
The correlation coefficient between the electric signal detected from the first detection unit and the electric signal detected from the second detection unit is calculated, and the correlation coefficient is calculated.
Output information based on the correlation coefficient,
An electroencephalogram measurement method characterized by this.
<Claim 10>
It is an electroencephalogram measurement program in an electroencephalogram measuring device.
The electroencephalogram measuring device is
A first detector that detects an electrical signal emitted from a specific part of the user,
A second detection unit that detects an electric signal emitted from at least one part of the user's head, which is different from the specific part, is provided.
On the computer
The correlation coefficient between the electric signal detected from the first detection unit and the electric signal detected from the second detection unit is calculated.
Output information based on the correlation coefficient,
An electroencephalogram measurement program characterized by this.

100 Brain wave measuring device 1 Sensor unit 11 In-ear sensor 12 Head sensor 13 Unit body 131 Grounding unit 132 Adjustment unit 2 Neckband 3 Controller unit 101 Control device 102 Storage device 103 Operation unit 104 Display unit 105 Sensor unit 106 Position detection unit 107 Communication unit 200 Brain wave measuring device 202 Frame 14 Retinal sensor

Claims (9)

A first detector that detects an electrical signal emitted from a specific part of the user,
A second detection unit that detects an electrical signal emitted from at least one part of the user's head, which is different from the specific part.
A control device that calculates the correlation coefficient between the electric signal detected by the first detection unit and the electric signal detected by the second detection unit and outputs information based on the correlation coefficient.
Equipped with a,
The first detection unit detects an electric signal emitted from the cochlea of the user as the specific site, and detects the electric signal.
The second detection unit detects an electric signal emitted from the auditory cortex of the user's head at a specific place having the relatively largest correlation coefficient among the plurality of places of the user's head. To do,
An electroencephalogram measuring device characterized in that. Equipped with a display
The electroencephalogram measuring device according to claim 1, wherein the control device is controlled so that the display unit displays information corresponding to the correlation coefficient. A support member that holds the second detection unit in a state where the second detection unit is in contact with a predetermined position on the head, and
An adjustment unit that adjusts the position of the second detection unit held by the support member based on user operation, and an adjustment unit.
The electroencephalogram measuring device according to claim 1 or 2, wherein the device comprises. A position detection unit that detects the adjustment position of the second detection unit adjusted by the adjustment unit, and
A storage device that stores adjustment position information indicating the adjustment position detected by the position detection unit, and
The electroencephalogram measuring device according to claim 3, further comprising. The second detection unit is composed of a plurality of parts.
A support member that holds the plurality of second detection portions in a state where the plurality of second detection portions are brought into contact with a predetermined position on the head.
A designation unit that designates one second detection unit to be detected of the electric signal from the plurality of second detection units based on a user operation, and a designation unit.
The electroencephalogram measuring device according to any one of claims 1 to 4, wherein the electroencephalogram measuring device is provided. The electroencephalogram measuring device according to claim 5, further comprising a storage device that stores designated information indicating the first and second detection units designated by the designated unit. The electroencephalogram measuring device according to any one of claims 1 to 6, further comprising a sound output unit that outputs a sound having a predetermined frequency when the first detection unit detects the electric signal. It is an electroencephalogram measuring method in an electroencephalogram measuring device.
The electroencephalogram measuring device is
A first detector that detects an electrical signal emitted from a specific part of the user,
A second detection unit that detects an electric signal emitted from at least one part of the user's head, which is different from the specific part, is provided.
The correlation coefficient between the electric signal detected from the first detection unit and the electric signal detected from the second detection unit is calculated, and the correlation coefficient is calculated.
Output information based on the correlation coefficient
The first detection unit detects an electric signal emitted from the cochlea of the user as the specific site, and detects the electric signal.
The second detection unit detects an electric signal emitted from the auditory cortex of the user's head at a specific place having the relatively largest correlation coefficient among the plurality of places of the user's head. To do,
An electroencephalogram measurement method characterized by this. It is an electroencephalogram measurement program in an electroencephalogram measuring device.
The electroencephalogram measuring device is
A first detector that detects an electrical signal emitted from a specific part of the user,
A second detection unit that detects an electric signal emitted from at least one part of the user's head, which is different from the specific part, is provided.
On the computer
The correlation coefficient between the electric signal detected from the first detection unit and the electric signal detected from the second detection unit is calculated.
Output information based on the correlation coefficient
The first detection unit detects an electric signal emitted from the cochlea of the user as the specific site, and detects the electric signal.
The second detection unit detects an electric signal emitted from the auditory cortex of the user's head at a specific place having the relatively largest correlation coefficient among the plurality of places of the user's head. To do,
An electroencephalogram measurement program characterized by this.

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