Disclosure of Invention
The invention aims to provide an acousto-optic brain vision inducing device which can realize brain frequency resonance.
In order to achieve the purpose, the invention provides the following scheme:
an acousto-optic induced brain vision device, comprising: a support member, an isolation device and a light-emitting body;
the luminous body is arranged at a first set position of the supporting member, and the first set position comprises a position which is just opposite to the eyes of a user after the user wears the supporting member; the luminous bodies comprise a left eye luminous body and a right eye luminous body, the brightness change of light emitted by the left eye luminous body corresponds to the waveform amplitude change of a left ear audio signal, the brightness change of light emitted by the right eye luminous body corresponds to the waveform amplitude change of a right ear audio signal, and the left ear audio signal and the right ear audio signal are binaural beat effect audio signals;
each luminous body is provided with one isolating device, each isolating device comprises an annular baffle, and the annular baffle extends from the edge of the luminous body to the eye direction of a human body; the human eye direction is as follows: after the user wears the supporting component, the luminous body points to the direction corresponding to the eyeball.
Optionally, the support member is an eyeglass frame.
Optionally, the support member is an eye-mask type member.
Optionally, the light emitter is a high-brightness white LED light emitter.
Optionally, the acousto-optic induced brain vision device further includes a light-emitting driving signal generating module, configured to generate a light brightness change driving signal corresponding to a change in waveform amplitude of the binaural beat effect audio signal.
Optionally, the light-emitting driving signal generating module includes an audio player and an audio power amplifier connected to the audio player, and an output end of the audio power amplifier is connected to the light emitter; the audio player is used for playing binaural beat effect audio signals, and the audio power amplifier is used for performing power amplification on the signals output by the audio player to obtain the light-emitting driving signals of the luminous body.
Optionally, the acousto-optic induced brain vision device further includes a power module, and the power module is respectively connected to the audio power amplifier and the audio player.
Optionally, the audio player is a two-channel audio player.
According to the specific embodiment provided by the invention, the invention discloses the following technical effects: the invention provides a device for inducing brain vision by acousto-optic, comprising: a support member, an isolation device and a light-emitting body; the luminous body is arranged at a first set position of the supporting member, and the first set position comprises a position which is just opposite to the eyes of a user after the user wears the supporting member; the luminous bodies comprise a left eye luminous body and a right eye luminous body, the brightness change of light emitted by the left eye luminous body corresponds to the waveform amplitude change of a left ear audio signal, the brightness change of light emitted by the right eye luminous body corresponds to the waveform amplitude change of a right ear audio signal, and the left ear audio signal and the right ear audio signal are binaural beat effect audio signals; each luminous body is provided with one isolating device, each isolating device comprises an annular baffle, and the annular baffle extends from the edge of the luminous body to the eye direction of a human body; the human eye direction is as follows: after the user wears the supporting component, the luminous body points to the direction corresponding to the eyeball. The invention generates a binocular beat effect similar to a binaural beat effect in the visual channels of the left and right eyes of a human by the change of the brightness of the light emitted by the luminous body and irradiating the eyes along with the amplitude change of the brain wave music audio signal, thereby forming brain vision and realizing brain frequency resonance.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive exercise.
FIG. 1 is a schematic view of an acousto-optic brain vision inducing apparatus;
FIG. 2 is a schematic view of the support member being an eyeglass frame;
FIG. 3 is a schematic view of the support member being an eye shield;
fig. 4 is a schematic diagram of an anti-parallel connection of light emitters.
Description of the symbols:
the LED voice-frequency audio player comprises a supporting member-1, an LED luminous body-2, an audio power amplifier-3, an audio player-4, an audio output connecting wire-5, an audio amplifier driving connecting wire-6, a power module-7, a power connecting wire-8, an isolating device-9, a reflecting layer-10 and a head band-11.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
The invention aims to provide an acousto-optic brain vision inducing device which can realize brain frequency resonance.
In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in further detail below.
As shown in fig. 1, the acousto-optically induced brain vision device includes: support member 1, isolation device 9 and a light emitter.
Specifically, the support member 1 is a spectacle frame or eyeshade type member; the spectacle frame is a spectacle frame of the spectacles; the eyeshade type component is an eyeshade; the luminophor is a high-brightness white light LED luminophor 2; the high-brightness white light LED luminous body 2 is a high-power LED which can emit white light; further, the power of the high-brightness white light LED luminous body 2 is 0.1W-3W.
The luminous body is arranged at a first set position of the support member 1, and the first set position comprises a position which is just opposite to the eyes of a user after the user wears the support member 1; the luminous bodies comprise a left eye luminous body and a right eye luminous body, the brightness change of light emitted by the left eye luminous body corresponds to the waveform amplitude change of the left ear audio signal, the brightness change of light emitted by the right eye luminous body corresponds to the waveform amplitude change of the right ear audio signal, and the left ear audio signal and the right ear audio signal are binaural beat effect audio signals.
Each luminous body is provided with an isolating device 9, the isolating device 9 comprises an annular baffle plate, and the annular baffle plate extends from the edge of the luminous body to the eye direction of a human body; the human eye direction is as follows: after wearing the support member 1, the light emitter points to the direction corresponding to the eyeball. When the user wears the support member 1, the end of the isolation device 9 extending toward the eyes of the user is attached to the skin of the user.
Specifically, as shown in fig. 2 and 3, the invention is a pair of glasses frame or eye cover which is respectively provided with two groups of high-brightness white light LED luminous bodies 2 at the positions opposite to and close to the left and right eyeballs of a person; a reflective layer 10 is arranged on the glasses frame or the eyeshade, and the reflective layer 10 is used for converging and projecting light emitted by the high-brightness white light LED luminous body 2 to eyes; further, when the support structure is a lens frame, the lens frame is provided with opaque lenses, and the reflective layer 10 is arranged on the inner side surfaces of the opaque lenses; the high-brightness white light LED luminous body 2 is positioned between the opaque lens and the eyes; when the supporting structure is an eye mask, the reflecting layer is arranged on the inner side surface of the mask body of the eye mask; the high-brightness white light LED luminous body 2 is arranged between the eye mask body and eyes.
The light emitting areas of the left eye and the right eye are mutually optically isolated, and each group of high-brightness white light LEDs is composed of a single high-power LED or a plurality of high-power LED arrays; the isolation device 9 is arranged on the spectacle frame or the eye shield; the separating means 9 forms a closed space with the lens or the eye-mask body and the skin shielded by the separating means 9 and the lens or the eye-mask body. The isolation device 9 is used for isolating the left eye and the right eye of the light emitting area of the high-brightness white light LED luminous body 2, so that the mutual interference of the left eye and the right eye is avoided, and the materials are all materials capable of blocking light transmission. The isolation means 9 prevents the light waves emitted by the luminaries from illuminating the other eye without affecting the illumination of the eye by the luminaries directly opposite the user's eye.
The acousto-optic induced brain vision device also comprises a light-emitting driving signal generating module which is used for generating a light brightness change driving signal corresponding to the change of the waveform amplitude of the binaural beat effect audio signal.
As an embodiment, the light-emitting driving signal generating module includes an audio player 4 and an audio power amplifier 3 connected to the audio player 4, wherein an output end of the audio power amplifier 3 is connected to the light-emitting body; the audio player 4 is used for playing binaural beat effect audio signals, and the audio power amplifier 3 performs power amplification on the signals output by the audio player 4 to obtain light-emitting driving signals of the luminous body.
Specifically, the audio player 4 is a two-channel audio player 4; furthermore, the audio player 4 is a dual-channel music player capable of playing audio of various formats by decoding the read memory card. The audio player 4 may also be an MP3 card player; the high-brightness white light LED luminous bodies 2 are connected to the left and right sound channel output ends of the audio power amplifier 3, the audio player 4 plays specific brain wave music in the memory, brain wave music signals of the left and right sound channels are output to the audio power amplifier 3 to be amplified in power, and then the brightness of the left and right high-brightness white light LED luminous bodies 2 is respectively driven to change linearly according to the waveform amplitude of the audio signals (instead of nonlinear stroboscopic change in a non-switching mode).
Further, the audio signal output by the audio player 4 is amplified by the audio power amplifier 3; the audio power amplifier 3 works in a linear amplification state; the output end of the audio power amplifier 3 outputs a current signal, and the stronger the audio signal output by the audio player 4 is, the stronger the current signal output after passing through the audio power amplifier 3 is; audio signals of brain wave music played and output by the audio player 4 are amplified by the audio power amplifier 3 and then converted into current signals with different magnitudes along with the change of the audio signals; the current signal output by the audio power amplifier 3 is used to drive the high-brightness white light LED luminous body 2, and the high-brightness white light LED luminous body 2 can be a high-power LED light emitting diode, so that the high-power LED light emitting diode truly reflects the waveform change of the brain wave music played by the audio player 4 in a linear change mode of light intensity.
Furthermore, as shown in fig. 4, the light-emitting body is formed by two high-power LED light-emitting diodes connected in parallel in the reverse direction or an even number of high-power LED light-emitting diodes larger than two; when the luminous body is composed of even number of high power LED more than two, half of the high power LED is connected in parallel in the forward direction to form a first LED, the other half of the high power LED is connected in parallel in the forward direction to form a second LED, and the first LED and the second LED are connected in parallel in the reverse direction to form the luminous body. When the audio signal of brain wave music played and output by the audio player 4 passes through the luminous body in the positive cycle of the sine wave current signal output by the audio power amplifier 3, the first LED is turned on, the second LED is turned off, and the first LED of the luminous body emits light; when the audio signal of the brain wave music played and output by the audio player 4 passes through the luminous body through the negative cycle of the sine wave current signal output by the audio power amplifier 3, the first LED is turned off, the second LED is turned on, and the second LED of the luminous body emits light; so that the sine wave current signal output from the audio power amplifier can drive the luminous body to emit light no matter in the positive period or the negative period.
The acousto-optic induction brain vision device also comprises a power module 7, and the power module 7 is respectively connected with the audio power amplifier 3 and the audio player 4; the power supply module 7 supplies electric energy to the audio power amplifier 3 and the audio player 4; the power module 7 comprises an external power management part and a battery charging and discharging management part; the external power supply management is an external power supply interface which can supply power to the audio power amplifier 3 and the audio player 4 through the external power supply; the battery charge and discharge management comprises a rechargeable battery and a charge and discharge management protection board, wherein the charge and discharge management protection board is used for avoiding overcharge, overdischarge, overcurrent, short circuit and ultrahigh-temperature charge and discharge of the rechargeable battery.
The brightness change frequency of the two groups of high-brightness white light LED luminous bodies 2 is in the eye closing state of the left and right eyes of a person, the optic nerves in the eyeball are subjected to indirect non-image visual light-sensitive stimulation through the eye curtain skin and are transmitted to the visual imaging areas of the left and right half-brains through the visual nerve channels, and due to the fact that the optical isolation of the left and right eyes is carried out, the optical signals of brain wave music signals can be generated in the visual areas of the left and right half-brains to generate a 'binocular beat effect' similar to a 'binaural beat effect', and the complete optical brain wave frequency images are directly synthesized in the brains to form brain vision, so that the brain waves of the person can quickly resonate with the specific brain wave music frequency, the person can quickly enter a specific brain wave state with stable depth and enter a deep subconscious state. The brain wave frequency images with different shapes, colorful colors and gorgeous colors appear in the brain.
The application method of the acousto-optic brain vision induction device provided by the invention comprises the following steps:
the audio player converts the brain wave music into brain wave music audio signals.
The brain wave music audio signal is amplified by the linear power of the audio power amplifier and then drives the luminous body to work.
According to the invention, brain wave music is converted into brain wave music audio signals through the audio player, the brain wave music audio signals are amplified through the linear power of the audio power amplifier and then drive the luminous body to irradiate the eyes of a human, the brightness of light irradiated by the luminous body changes along with the amplitude change of the brain wave music analog signals, and a binocular beat effect similar to a binaural beat effect is generated in the left and right eye visual channels of the human, so that brain vision is formed, and brain frequency resonance is realized.
The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.
The principles and embodiments of the present invention have been described herein using specific examples, which are provided only to help understand the method and the core concept of the present invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, the specific embodiments and the application range may be changed. In view of the above, the present disclosure should not be construed as limiting the invention.