KR20130067550A - Apparatus for detecting electroencephalogram having shape of eyeglasses and electroencephalogram detecting system having the same - Google Patents

Abstract

PURPOSE: A spectacle type electroencephalogram device and an electroencephalogram system thereof are provided to be conveniently wearable and to reduce strained sensation when the device is put on. CONSTITUTION: A spectacle type electroencephalogram device(100) includes electroencephalogram terminals(110a,...,110n) which measure brain waves of a wearer; standard(REF) terminals(120a,120b) which measure reference potentials when the brain waves are measured; and a gyro sensor(130) which senses a rotatory motion; a signal processing circuit(140) which processes and receives a brain wave signal which is measured and output by the electroencephalogram terminal, a reference signal which is output by the reference terminal, and a rotatory motion signal which is measured and output by the gyro sensor; and spectacles which is installed with the electroencephalogram terminals, the reference terminals, and the signal processing circuit.

Description

Apparatus for Detecting Electroencephalogram Having Shape of Eyeglasses and Electroencephalogram Detecting System Having the Same}

The present invention relates to an EEG acquisition apparatus and an EEG measurement system including the same.

The waveform obtained by attaching several electrode pads to the human head and amplifying the electric signal obtained therein is called an electro-encephalogram (EGE). The waveform of the EEG signal varies greatly depending on the head region, subject's thoughts or mental state. In general, the magnitude of the EEG is from several uV to several hundred uV, the frequency is from 0 to infinity, but in the existing research cases it is known that the frequency of 0 to 50Hz contains a lot of characteristic information (meaning). Five waveforms of δ waveform, θ waveform, α waveform, β waveform, and γ waveform, which are classified according to the magnitude and frequency of the voltage, are observed in normal persons. Among these, α waveform is a waveform of 50 μV magnitude at 8 to 14 Hz frequency, which occurs when a normal adult is in a stable mental state, and is particularly observed in the larynx and the head. The β waveform has a frequency of 14 to 30 Hz and is well observed in the head and temporal region with mental concentration or increased brain activity. θ waveforms have a frequency of 4 to 8 Hz and are observed in the head and temporal region of children, and in adults when they have stress such as sleep or deep disappointment, or when they have brain diseases. The δ waveform is a frequency signal below 4 Hz and is also observed in infants and may appear in deep sleep or in severe brain diseases in adults. The γ waveform is a frequency signal of 31 to 50 Hz and occurs frequently in a strong stress state of anxiety and excitement. In addition, since the cerebral cortex appears to be separated from the lower brain tissue, it can be seen that the waveform appears independently of the cortex itself. In addition, brain waves, which capture the activity of the brain in spatio-temporal mode, are widely used in clinical and brain function research as representative bio signals. Recently, EEG is used for biofeedback, which improves the mental state of the user through the modulation of EEG by external stimuli, and directly interfaces with humans and machines through EEG without going through language or body movements. It is also applied to the field of brain-computer interface (BCI) to achieve the

Since most conventional devices for measuring EEG are bulky and need to be placed on a desk or installed on a separate carrier, patients who require EEG must go to a hospital equipped with such a device to record the EEG diagnosis and its status. It is possible. Therefore, until now, the EEG measuring apparatus has a problem that its use is very inconvenient because the psychiatrist should move the patient whenever the psychiatrist periodically performs EEG measurement to diagnose the patient's condition.

In order to solve such a problem, the hair band type, the hat type, the headset type, the headphone type, and the like have been developed in the case of the portable EEG acquisition apparatus disclosed so far according to the wearing type. However, conventional devices have disadvantages such as inconvenience or pressure when worn. Specifically, the hair band-type and hat-shaped EEG acquisition apparatus can acquire the EEG of the forehead region, but it may be inconvenient to wear because the reference terminal (REF terminal) must be attached separately to the region behind the ear. The headset type EEG acquisition device can acquire EEG of various parts of the head, but it can be pressed when worn, causing severe pain when worn for a long time. The headphone type EEG acquisition device can acquire the EEG of the forehead area, but the EEG signal acquired as the structure located in the EEG acquisition area instead of the structure in which the reference terminal (REF terminal) is located behind the ear as an international standard is the international standard acquisition method. There is a problem that is different.

The present invention is to solve the problems of the prior art described above, it is one of the main objectives to provide a portable EEG acquisition device that can be easily worn, and can reduce the feeling of pressure when worn.

The spectacle type EEG measuring apparatus according to the present invention includes at least one EEG measuring terminal for measuring an EEG of a wearer, a reference (REF) terminal for measuring a reference potential which is a reference for measuring EEG, and a gyro for detecting a rotational motion. A signal processing circuit for processing and transmitting a sensor, an EEG signal measured and output by the EEG measurement terminal, a reference signal measured and output by the reference terminal, and a rotational motion signal measured and output by a gyro sensor and the EEG measurement terminal And spectacles provided with a reference terminal, a gyro sensor, and a signal processing circuit.

In one example, the at least one brain wave measuring terminal may move the installed position according to a position to measure the brain wave.

In one example, the reference terminal is formed in the contact portion of the wearer's ear in the spectacles leg.

In an example, the signal processing circuit may include a filter and amplification unit that removes and amplifies noise from a signal measured by an EEG measurement terminal, a signal from which the noise is removed, and the gyro sensor is output. MCU (Micro Controller Unit) including an analog to digital converter subunit (Analog to Digital Converter Subunit) for receiving a rotational motion signal and converts it into a digital signal, and serializes the converted digital signal to the outside by a predetermined protocol It includes a communication unit for transmitting.

In one example, the filter and the amplifying unit, a differential amplifier for receiving a signal of the EEG measurement signal, a signal of the reference terminal and amplifies a differential signal, and the frequency of the EEG signal in the amplified differential signal A filter subunit that filters only a band and an amplifier subunit that amplifies the filtered signal.

In one example, the filter sub-unit is a band pass filter that passes only a specific frequency band, or is cascaded with a high pass filter having a first cutoff frequency, and the first cutoff frequency At least one of a low pass filter having a second cutoff frequency greater than.

In one example, the first cutoff frequency is any one of 0 to 1 Hz, and the second cutoff frequency is any one of 50 Hz to 59 Hz.

In one example, the band pass filter has a low pass cutoff frequency of any one of 0 to 1 Hz and a high pass cutoff frequency of a pass band of any one of 50 Hz to 59 Hz.

In one example, the predetermined protocol includes a short range of any one of Bluetooth, Infra Red (IR), Near Field Communication (NFC), Zigbee, Ultra Wideband (UWV), and IEEE 802.15 standard. Wireless communication protocol.

The EEG measuring system according to the present invention includes a spectacle type EEG measuring apparatus mounted on the glasses to measure, process and transmit the EEG and rotation of the spectacle wearer, and a terminal for receiving and processing signals from the EEG measuring apparatus. .

In one example, the spectacle type EEG measuring apparatus, at least one EEG measuring terminal, a reference terminal formed on at least one eyeglass leg of the glasses to contact behind the wearer's ear, a gyro sensor for detecting whether the eyeglasses rotate; A signal processing circuit for processing and transmitting the brain wave measured by the brain wave measuring terminal and the signal detected by the gyro sensor is mounted on the glasses.

In one example, the terminal, a mobile phone, a smart phone (Smart Phone), PC (Personal Computer), Tablet PC (Tablet PC), which receives and processes the EEG signal and the rotation signal transmitted by the spectacle type EEG measuring device, and One of the PDAs (Personal Digital Assistants).

The present invention provides a brain wave measuring device that can be easily worn.

The present invention provides an EEG measuring apparatus capable of obtaining an EEG signal conforming to international standards.

The EEG measuring apparatus according to the present invention provides an EEG acquiring device that can be easily carried, and provides an effect of reducing a feeling of pressure when worn.

1 is a perspective view showing the outline of the spectacle type EEG measuring apparatus according to an embodiment of the present invention.
2 is a block diagram illustrating an outline of a signal processing circuit mounted on the spectacle type EEG measuring apparatus according to an embodiment of the present invention.
3 is a schematic view for explaining the operation of the MCU according to an embodiment of the present invention.
4 is a diagram illustrating an outline of a terminal according to an embodiment of the present invention.

Hereinafter, exemplary embodiments disclosed herein will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements, unless the context clearly indicates otherwise. The illustrative embodiments described in the detailed description, drawings, and claims are not meant to be limiting, other embodiments may be utilized, and other changes may be made without departing from the spirit or scope of the technology disclosed herein. Those skilled in the art can arrange, configure, combine, and design the elements of the present disclosure, that is, the components generally described herein and described in the figures, in various other configurations, all of which are expressly devised and It will be readily understood that they form part. In the drawings, the width, length, thickness or shape of an element, etc. may be exaggerated in order to clearly illustrate the various layers (or films), regions and shapes.

When one component is referred to as "connecting with" another component, the component may directly connect with the other component as well as an additional component interposed therebetween. have.

Where one component is said to be arranged, positioned, or formed in another component, it may include the case in which one component is directly disposed in the other component, as well as the case where additional components are interposed therebetween. have.

1 is a perspective view showing the outline of the spectacle type EEG measuring apparatus according to an embodiment of the present invention. Referring to FIG. 1, the EEG measuring terminals 110a, ..., 110n are terminals for measuring the EEG of the measurer wearing the spectacle type EEG measuring apparatus according to an embodiment of the present invention, as many as the number of channels to be measured. It is mounted on the glasses (110a), when the brain wave measurement can be removed (110n). EEG measuring terminal (110a, ..., 110n) measures the brain wave and outputs an EEG signal. In one embodiment, the EEG measurement terminal (110a, ..., 110n) is easily attached to the upper portion of the spectacle frame according to the position to measure the EEG. In addition, the EEG measurement terminal (110a, ..., 110n) is formed of a material that is easily bent to be in close contact with the EEG measurement site. In the EEG measurement terminals 110a, ..., 110n, the terminals directly contacting the skin of the head are made of metal materials such as gold, silver, and tin with low electrical resistance, but may cause abnormalities on the skin. Do not use materials such as lead.

The reference terminals 120a and 120b output a reference potential signal by measuring a reference potential as a reference when measuring EEG. The international standard stipulates the measurement of the reference potential at which the EEG is measured at the region behind the ear. Therefore, the measurement of the reference potential at other sites differs from the EEG signal obtained by the international standard method. According to one embodiment of the invention, the reference terminals (120a, 120b) is formed in the contact portion of the eyeglasses of the glasses and the back of the ear of the measurer. In one example, the reference terminal is formed in the contact portion behind the ear on the left and right eyeglasses. In one example, the portion of the reference terminal that is in direct contact with the skin is formed of a metal material such as gold, silver, tin, and the like having low electrical resistance, but a material such as lead, which may cause abnormalities on the skin, is not used.

The gyro sensor 130 is a sensor for detecting a rotational movement using a predetermined axis as a rotation axis, and outputs an angular velocity by measuring rotation about a predetermined axis. In one embodiment, the gyro sensor 130 mounted on the spectacle type EEG measuring apparatus of the present invention outputs a rotational motion signal by measuring the rotation of the head about a predetermined axis during EEG measurement. For example, the rotational motion signal may be an angular velocity value of the rotational motion based on a predetermined axis.

The signal processing circuit 140 includes an EEG signal measured and output by the EEG measurement terminals 110a, ..., 110n, a reference potential signal measured and output by the reference terminals 120a and 120b, and a gyro sensor 130. Receives the rotation signal measured and output and processes it and sends it to the outside.

The power supply unit 150 supplies power to the EEG acquisition device. In one embodiment, the power supply unit 150 includes a battery mounted therein. In another embodiment, the power supply unit includes an external battery. The battery is applied considering the power consumption and usage time of the device. In one embodiment, the power supply unit includes a power on / off button and an LED formed on an outer side of one of the glasses legs, and power is applied or cut off by manipulation of the power on / off button. LEDs indicate the device's operating status as either lit or flashing. In one embodiment, the external power supply can be solved by the Micro USB method and the like currently used in smartphones. The location of the external power supply terminal is located under the glasses leg close to the part where the right glasses leg is folded so that it does not touch the skin when worn. When using an external battery, the external circuit supplies power to the entire circuit. If you use a built-in battery, use the built-in battery to power the entire circuit. As such, the external power supply terminal is used to supply power to the entire circuit and to charge the built-in battery. In one embodiment, when the signal processing circuit 140 is located on one of the left or right eyeglasses, the power supply unit 150 is located on the opposite eyeglasses for equal distribution of the left and right weights of the glasses.

2 is a block diagram showing an outline of a signal processing circuit according to the present invention. 1 and 2, the signal processing circuit 140 includes a filter and amplification unit 142, a microcontroller unit 144, and a communication unit 146. The filter and amplifying unit 142 includes three subunits of the differential amplifier 142a, the filter subunit 142b, and the amplifier subunit 142c. The MCU 144 includes two subunits, an analog to digital coverter (ADC) 144a and a serializer subunit 144b.

The differential amplifier 142a is, in one embodiment, an EEG signal that is an output signal of the EEG measurement terminals 110a, ..., 110n, and a reference signal ref that is an output signal of the reference terminals 120a and 120b. ) To suppress amplification of the common mode signal and to amplify the differential mode signal. Noise is introduced into the reference signal and the EEG signal, and this noise is generally introduced into the common mode. Since the EEG signal to be measured is a differential signal between the reference signal and the EEG signal, the amplification of the common mode is suppressed as much as possible. It is necessary to amplify only differential mode signals.

The filter subunit 142b filters only the frequency band of the EEG signal in the signal output from the differential amplifier 142a. In one embodiment, the filter subunit 142b uses a band pass filter to make the frequency of the EEG signal the pass band. In one example, the low pass cutoff frequency of the band pass filter is any one of 0 to 1 Hz, and the high pass cutoff frequency is any one of 50 Hz to 59 Hz. In another embodiment, the filter subunit 142b is a filter in which a high pass filter having a first cutoff frequency and a low pass filter having a second cutoff frequency are cascaded. The first cutoff frequency has a lower value than the second cutoff frequency. In one example, the first cutoff frequency is any one of 0 to 1 Hz, and the second cutoff frequency is any one of 50 Hz to 59 Hz.

The amplifier subunit 142c amplifies with a constant gain so as to have a level sufficient to digitally convert the EEG signal filtered by the filter subunit 142b. In one example, the gain of the amplifier subunit 142c is set such that the output signal is in the range of 2.5Vpp, 3.3Vpp, 5Vpp. In another example, the gain of the amplifier subunit is set to be 10 ³ to 10 ⁵ .

See FIGS. 1, 2 and 3. 3 is a flowchart of A / D conversion and data transmission according to an embodiment of the present invention. After initializing 310 the ADC subunit 144a and the serialization subunit 144b of the MCU 144, the ADC subunit 144a outputs an EEG signal output from the amplifier subunit 142c. And receives the signal (rot) of the gyro sensor and converts it to a digital signal. In one embodiment, the EEG measurement terminal is composed of a total of n channels, and when the gyro sensor senses rotation about m axes, A / D conversion is performed on all n + m channels. It is determined whether or not the conversion is completed for the n + m channels (320), and when completed, the header and the transform data of the n + m channels are inserted into the frame (330). The serialization subunit 144b of the MCU 144 transmits the completed frame data to the communication unit (340). In one example, the serialization subunit transmits to the communication unit 146 using an interface such as a universal asynchronous receiver / transmitter (UART), an I-Square-C (I2C), a serial peripheral interface (SPI), or the like (340).

The communication unit 146 receiving the data from the MCU 144 transmits the brain wave signal and the rotation signal received to the external terminal. In one embodiment, the communication unit 146 is a short-range wireless communication included in Bluetooth, InfraRed, Near Field Communication (NFC), Zigbee, Ultra Wide Band (UWB), and IEEE 802.15 standards. The information is transmitted to an external terminal using a protocol.

The external terminal receiving the information transmitted by the spectacle type EEG measuring apparatus receives the received EEG signal and the rotation signal, and extracts the EEG signal and the rotation signal.

FIG. 4 is an EEG acquisition terminal that displays EEG waveforms of one part (channel) and energy changes of one part (channel) by receiving EEG data in real time from a smart phone. Includes key features of real-time EEG and Gyro information measurement, EEG data storage and display. The field of application can be applied to various applications of smart phone by using EEG acquired anywhere and anytime.

 In one embodiment, the terminal is a mobile phone, a smart phone, a personal computer (PC), a tablet PC (PC), and a personal digital assistant (PDA) capable of processing information transmitted by the spectacle type EEG measuring device. It is one of the information processing terminals.

The above-described spectacle type EEG measuring device provides an advantage that EEG information can be obtained easily and simply by measuring EEG, and various portable EEG obtaining devices using EEG from EEG information provided, EEG game, EEG medical treatment, EEG using the same It can be used for applications such as diagnosis and brain wave learning, and further, it is possible to activate the BCI (Brain Computer Interface) research.

Although the above-described technology has been described in detail with reference to various embodiments as described above, a person having ordinary skill in the art to which the disclosed technology belongs will appreciate the spirit and scope of the disclosed technology as defined in the appended claims. Various modifications may be made to the disclosed technology without departing from it. Therefore, changes in the future embodiments of the disclosed technology will not be able to escape the technology of the disclosed technology.

100: spectacle type EEG measuring device 110a, ..., 110n: EEG measuring terminal
120a, 120b: Reference terminal 130: Gyro sensor
140: signal processing circuit section 142: filter and amplification section
142a: differential amplifier 142b: filter subunit
142c: amplifier subunit 144: MCU
144a: ADC subunit 144b: serialization sub unit
146: communication unit
310 to 350: ADC subunit, and each step of serialization subunit operation

Claims (12)

At least one EEG measuring terminal for measuring the EEG of the wearer;
A reference (REF) terminal for measuring a reference potential which is a reference for the EEG measurement;
A gyro sensor for detecting a rotational movement;
A signal processing circuit for processing and transmitting an EEG signal measured and output by the EEG measurement terminal, a reference signal measured and output by the reference terminal, and a rotational motion signal measured and output by a gyro sensor; And
Spectacles-type EEG measuring apparatus comprising a pair of glasses, the EEG measuring terminal, a reference terminal, a gyro sensor, and a signal processing circuit. The method of claim 1,
The at least one brain wave measuring terminal,
Glasses type EEG measuring device that can be attached to the upper part of the spectacle frame according to the position to measure the EEG. The method of claim 1,
The reference terminal,
Eyeglass type EEG measuring device formed in the contact portion of the wearer's ear back of the glasses leg. The method of claim 1,
The signal processing circuit,
A filter and amplification unit which removes and amplifies noise from the signal measured by the EEG measurement terminal;
A microcontroller unit (MCU) including an analog to digital converter subunit (Analog to Digital Converter Subunit) for receiving the signal from which the noise is removed and the rotary motion signal output from the gyro sensor, and converting the digital signal into a digital signal;
Glasses-type EEG measuring apparatus comprising a communication unit for serializing the converted digital signal (serialize) and transmits to the outside in a predetermined protocol. 5. The method of claim 4,
The filter and amplification unit,
A differential amplifier for receiving the signal from the EEG measurement terminal and the signal from the reference terminal and amplifying the differential signal;
A filter subunit for filtering only the frequency band of the EEG signal in the amplified differential signal,
An spectacle-shaped EEG measuring apparatus including an amplifier subunit for amplifying the filtered signal. The method of claim 5,
The filter subunit is a band pass filter that passes only a specific frequency band, or is cascaded with a high pass filter having a first cutoff frequency and is larger than the first cutoff frequency. The spectacle type EEG measuring apparatus which is at least one of the low pass filter which has 2 cut-off frequencies. The method according to claim 6,
The first cutoff frequency is any one of 0 to 1 Hz,
The second cut-off frequency is any one of 50Hz to 59Hz spectacle-type EEG measuring apparatus. The method according to claim 6,
The band pass filter, the low-pass cut-off frequency of the band to pass any one of 0 to 1Hz, the high pass cutoff frequency of the band is passed any one of 50Hz to 59Hz spectacle-type EEG measurement device. 5. The method of claim 4,
The predetermined protocol is
Glasses type EEG measuring device, which is a short range wireless communication protocol of any one of Bluetooth, Infra Red (IR), Near Field Communication (NFC), Zigbee (Zigbee), Ultra Wideband (UWV), and IEEE 802.15 standard. A spectacle type EEG measuring apparatus mounted on spectacles to measure, process, and transmit brain waves and rotation of the spectacle wearer;
EEG measuring system comprising a terminal for receiving the signal of the brain wave measuring device and processing it. The method of claim 10,
The spectacle type EEG measuring apparatus,
At least one EEG measurement terminal,
A reference terminal formed on at least one pair of spectacles legs of the spectacles to contact behind the wearer's ear,
Gyro sensor for detecting whether the glasses rotate,
EEG measuring system equipped with a signal processing circuit for processing and transmitting the brain wave measured by the brain wave measuring terminal and the signal detected by the gyro sensor. The method of claim 10,
The terminal,
Any one of a mobile phone, a smart phone, a personal computer (PC), a tablet PC, and a personal digital assistant (PDA) that receive and process an EEG signal and a rotation signal transmitted by the spectacle type EEG measuring device. One brain wave measuring system.

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