KR20150036958A - Led illumination system interworking with brain wave generating apparatus - Google Patents

Abstract

Disclosed is an LED lighting system interworking with a brain wave measuring device, wherein an LED light is synchronized with brain wave of a human body and turned on and off to provide a comfortable studying environment and atmosphere of a rest area for a user. To this end, provided is the LED lighting system, comprising: the brain wave measuring device for measuring brain wave and transmitting a signal corresponding to the measured brain wave; a switching unit for receiving the signal transmitted from the brain wave measuring device so as to analyze the transmitted signal, extracting a light control mode corresponding to a type of analyzed brain wave, and transmitting a light control signal set in the light control mode; and an LED light unit for emitting light according to the light control signal transmitted from the switching unit. According to the present invention, brain wave of a user is induced to alpha waves, thereby maximizing learning efficiency of the user.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an LED illumination system,

The present invention relates to an LED lighting system interlocked with an electroencephalogram measuring instrument, and more particularly, to an LED lighting system in which LED light is synchronized with a brain wave of a human body and blinks to thereby provide a pleasant and comfortable learning environment, Illumination system.

Generally, EEG is a physical value that reflects human consciousness as a wavelength with a potential difference of tens of microvolts measured in human scalp and a frequency of mainly 50 hertz or less. Electroencephalogram (EEG) can be divided into 6 types according to the frequency: delta wave (δ), theta wave (θ), alpha wave (α), SMR wave, beta wave (β) and gamma wave (σ).

The delta wave is an EEG with a frequency of 0.5 to 3.5 hertz, which is related to a state of almost unconsciousness or deep sleep, and theta wave is an electroencephalogram having a frequency of 4 to 7 hertz, .

In addition, the alpha wave is associated with a stable and relaxed state as an EEG having a frequency of 8 to 11 Hertz, and the SMR wave is related to a state of attention as an EEG having a frequency of 12 to 15 Hertz.

Also, the beta wave is an EEG having a frequency of 16 to 30 Hertz, which is related to a state where a person is slightly tense and concentrating at the time of opening the eye. The σ wave is an EEG having a frequency of 30 to 50 hertz, which is related to a state of concentrating on deep thought or higher order logic.

In recent years, researches have been actively conducted to control objects by applying such EEG waves. In particular, the development of EEG electrodes for 20 to 30 medical EEGs continues to be developed, and programs for computer programs such as running a car, There are simple on-and-off devices that detect the EEG signal by only playing a game and a few EEG electrodes, blowing up a ping pong ball by the rotation of the fan, or running a toy car forward.

The EEG measurement and control apparatus according to the related art basically has a complicated method of measuring what kind of brain waves the user outputs and is difficult to visually confirm. It is difficult to conduct systematic concentration learning training for the general public. Furthermore, in the method of controlling EEG related devices using EEG, its application is very limited, simple control systems are common, and compatibility with other electronic devices is difficult.

Korean Patent No. 10-0868026 (published Nov. 10, 2008) Korean Patent No. 10-0943396 (published on Feb. 18, 2010) Korean Patent Publication No. 10-2013-0067550 (published on June 25, 2013)

Accordingly, it is a first object of the present invention to provide a brain wave measuring device capable of maximizing learning efficiency by guiding a beta wave of the brain to an alpha wave whose relaxation is relaxed by converting illumination installed in a reading room or a library into a learning mode Illumination system.

The second object of the present invention is to provide a brain wave measuring apparatus and a brain wave measuring apparatus which convert illumination of an EEG set in an area assigned to a brain wave measuring instrument in a reading room or a library to a learning mode, And an LED lighting system interlocked with the brain wave measuring device.

According to another aspect of the present invention, there is provided a brain wave measuring apparatus comprising: an EEG measuring unit for measuring an EEG and transmitting a corresponding signal; A switching unit for extracting an illumination control mode corresponding to the type of EEG and transmitting an illumination control signal set in the illumination control mode and an LED illumination unit for emitting light in accordance with the illumination control signal transmitted from the switching unit Illumination system.

According to another aspect of the present invention, there is provided a brain wave measuring apparatus including a plurality of brain wave measuring apparatuses for measuring brain waves and transmitting signals corresponding thereto, and a controller for receiving and analyzing signals transmitted from the brain wave measuring apparatuses, A switching unit that extracts a lighting control mode corresponding to the analyzed type of EEG and transmits an illumination control signal set in the illumination control mode and an LED illumination unit that emits light according to the illumination control signal transmitted from the switching unit And the switching unit selectively controls an LED illumination unit installed in an area assigned to the brain wave measuring device.

According to the present invention, it is possible to maximize the learning efficiency of the user by guiding the user's brain waves to the alpha wave.

In addition, even when the present invention is not used for induction of alpha waves, it can be utilized as lighting in an indoor space such as a living room, thereby helping the user to recover stress and fatigue.

In this way, the present invention can provide compatibility between the two different devices by using the switching unit in providing the signals of the brain waves detected from the brain-wave measuring device to the LED illumination.

In addition, the present invention can minimize preparation time for inducing EEG activation before learning, and it is unnecessary to separately provide an expensive EEG induction learning device, thereby reducing costs and improving concentration ability continuously during learning time By being exposed to a helpful lighting environment, a better learning effect can be expected.

1 is a block diagram illustrating an LED lighting system according to an embodiment of the present invention.

Hereinafter, an LED illumination system (hereinafter, referred to as 'LED illumination system') interlocked with the brain-wave measuring device according to the preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating an LED lighting system according to an embodiment of the present invention.

1 and 2, an LED illumination system according to the present invention includes at least one brain wave measuring device 100 for measuring brain waves and transmitting signals corresponding thereto, And a LED lighting unit 300 that emits light in accordance with the control of the switching unit 200. The LED lighting unit 300 may be an LED lighting unit,

Hereinafter, each component will be described in more detail with reference to the drawings.

Referring to FIG. 1, the LED illumination system according to the present invention includes an EEG 100.

The brain wave measuring apparatus 100 measures a brain wave and transmits a signal corresponding to the measured brain wave to the switching unit 200, and may be installed at a designated position of a reading room or a library.

The brain wave measuring apparatus 100 may be formed in any form as long as it can measure the vibration of brain waves, but it may be formed to have a headset type or a spectacle type outline.

In a specific aspect, the brain wave measuring apparatus 100 according to the present invention includes an EEG measurement terminal and a reference terminal.

The EEG terminal is a terminal for measuring an EEG of a user wearing the EEG 100, and outputs EEG signals by measuring the EEG. It is preferable that the EEG measurement terminal is formed of a material that can be easily bent so as to be adhered to the EEG measurement site.

In the EEG measurement terminal, the terminal which directly contacts the skin of the head of the head is formed of a metal material such as gold, silver, or tin having a low electrical resistance, but it is preferable not to use a material such as lead which may cause an abnormality to the skin Do.

On the other hand, the reference terminal measures the reference potential, which is a standard for measuring brain waves, and outputs a reference potential signal. The reference terminal is installed in the brain wave measuring device 100 at a position capable of directly contacting the skin of the head of the head. At this time, when the brain-wave measuring apparatus 100 is used as a brain-type EEG measuring device, a reference terminal is provided at a portion contacting the back of the ear at the left and right eyeglasses legs.

It is preferable that the portion of the reference terminal which is in direct contact with the skin is formed of a metal material such as gold, silver, or tin having a low electrical resistance, but not a material such as lead which may cause an abnormality to the skin.

In addition, the brain-wave measuring apparatus 100 according to the present invention may further include a filter and an amplifying unit, an MCU (Micro Controller Unit), and a communication unit.

More specifically, the filter and amplification section comprises three sub-units: a differential amplifier, a filter sub-unit, and an amplifier sub-unit. The MCU includes two subunits, an analog to digital converter (ADC) and a serializer subunit.

The differential amplifier receives the EEG signal, which is the output signal of the EEG measurement terminal, and the reference signal, which is the output signal of the reference terminal, and suppresses the amplification of the common mode signal and amplifies the differential mode signal. Since noise is introduced into the reference signal and the EEG signal, the noise generally enters 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 the differential mode signal.

The filter sub-unit filters only the frequency band of the EEG signal from the signal output from the differential amplifier.

In one embodiment, the filter sub-unit is a Band Pass Filter that allows the frequency of the EEG signal to pass band. More specifically, the low-cutoff frequency of the band-pass filter is any one of 0 to 1 Hz, and the high-cutoff frequency is any of 50 Hz to 59 Hz.

In another embodiment, the filter sub-unit comprises a filter having a cascade connection of a high pass filter having a first cutoff frequency and a low pass filter having a second cutoff frequency, Has a value lower than the second cut-off frequency. More specifically, the first cutoff frequency may be any one of 0 to 1 Hz, and the second cutoff frequency may be specified to any one of 50 Hz to 59 Hz.

The amplifier sub-unit amplifies the EEG signal at a predetermined gain so as to have a level sufficient to convert the EEG signal filtered in the filter sub-unit to digital. More specifically, the gain of the amplifier subunit can be set such that the output signal is in the range of 2.5Vpp, 3.3Vpp, 5Vpp.

After the EEG 100 initializes the ADC subunit 144a and the serialization subunit of the MCU, the ADC subunit receives the EEG signal output from the amplifier subunit and converts it into a digital signal do.

Subsequently, the serialization subunit of the MCU transmits the completed frame data to the communication unit.

Then, the communication unit receiving the data from the MCU transmits the EEG signal to the switching unit 200. [ The communication unit transmits information to the switching unit 200 using a short range wireless communication protocol included in Bluetooth, infrared communication, NFC (Near Field Communication), Zigbee, UWB (Ultra Wide Band), and IEEE 802.15 standards do.

Referring to FIG. 1, the LED lighting system according to the present invention includes a switching unit 200.

The switching unit 200 is connected to a single or a plurality of EEG 100, receives and analyzes signals transmitted from the EEG 100, extracts an illumination control mode corresponding to the analyzed EEG types, The LED lighting unit 300 is controlled by the lighting control signal set in the lighting control mode.

As a specific aspect, the switching unit 200 according to the present invention may be configured with an analysis module, a storage module, and a control module.

More specifically, the analysis module analyzes the signal received from the brain wave measuring device 100 to specify the type of the brain wave. For this purpose, the analysis module is connected to the brain wave measuring device 100 by wire or wirelessly.

The storage module stores a lighting control mode to be matched according to the type of brain waves connected to the classification module and designated by the analysis module, and a memory or the like can be used.

Such a storage module may store an? -Wave induction lighting control mode for inducing an EEG wave into an EEG wave and a basic illumination control mode for providing a general illumination environment.

The control module is connected to the storage module and extracts an illumination control mode corresponding to the type of EEG from the storage module and controls the output of the LED illumination unit 300 according to the illumination control mode. To a wired or wireless connection.

For example, the control module may be configured to extract, from the storage module, an? -Wave induction lighting control mode for inducing an EEG wave into an? -Wave when the EEG type is designated as a? -Wave through the analysis module.

The control module may be configured to extract, from the storage module, a basic illumination control mode for providing a general illumination environment when the type of the brain wave is designated as? Wave through the analysis module.

Referring to FIG. 1, an LED illumination system according to the present invention includes an LED illumination unit 300.

The LED illumination unit 300 is connected to the switching unit 200 and emits light in accordance with the illumination control signal transmitted from the switching unit 200. Any LED illumination can be used as long as it can achieve this purpose .

The LED illumination unit 300 may be installed separately from the indoor illumination providing the general illumination to the indoor space such as the reading room or the library. However, the LED illumination unit 300 may be installed alone in the indoor space, have.

In addition, the LED illumination unit 300 may include an LED illumination group for each of the areas allocated to the EEPROM 100, so that only the LED illumination group installed in a specific area under the control of the switching unit 200 can independently It is possible to output the? -Wave induction light so as to induce the user's brain wave in the specific region to? -Wave.

In other words, when a user who is seated in an arbitrary first region measures his / her brain wave using the brain wave measuring device 100 disposed in the first region, the brain wave measuring apparatus 100 transmits a signal for a user's brain wave to a switching unit (200). Then, the switching unit 200 analyzes the type of brain waves and extracts an illumination control mode corresponding to the type of brain waves from the built-in memory. In accordance with the illumination control signal set in the illumination control mode, .

Through this process, the user can be provided with a predetermined lighting environment according to the kind of the brain waves of the user, thereby maximizing the learning efficiency.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the appended claims. It can be understood that it is possible.

100: EEG 200: Switching unit
300: LED lighting part

Claims (5)

An EEG measuring device for measuring an EEG and transmitting a corresponding signal;
A switching unit for receiving and analyzing a signal transmitted from the brain wave measuring device, extracting an illumination control mode corresponding to the analyzed type of brain waves, and transmitting an illumination control signal set in the illumination control mode; And
And an LED illumination unit that emits light in accordance with the illumination control signal transmitted from the switching unit. 2. The apparatus of claim 1, wherein the switching unit
An analysis module for analyzing a signal received from the brain wave measuring device and designating a type of an EEG;
A storage module storing an illumination control mode to be matched according to a type of brain waves designated by the analysis module,
And a control module for extracting an illumination control mode corresponding to the type of the EEG from the storage module and controlling an output of the LED illumination unit according to the illumination control mode. 3. The apparatus of claim 2, wherein the control module
Wherein the controller is configured to extract, from the storage module, an? -Wave induction lighting control mode for inducing an EEG wave into an? -Wave when the type of EEG is designated as? -Ray through the analysis module. 3. The apparatus of claim 2, wherein the control module
Wherein the controller is configured to extract, from the storage module, a basic illumination control mode for providing a general illumination environment when the type of the brain waves is designated as? Wave through the analysis module. A plurality of brain wave measuring devices for measuring brain waves and transmitting signals corresponding thereto;
A switching unit receiving and analyzing a signal transmitted from each brain wave measuring device, extracting an illumination control mode corresponding to the analyzed type of brain waves, and transmitting an illumination control signal set in the illumination control mode; And
And an LED illumination unit for emitting light according to the illumination control signal transmitted from the switching unit,
Wherein the switching unit selectively controls an LED illumination unit installed in an area assigned to the brain wave measuring device.

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