KR101239838B1 - Vision accomodation training apparatus - Google Patents

Abstract

The present invention relates to a time information processing function training apparatus capable of training a time information processing function. Training apparatus for visual information processing function according to the present invention, a fixed frame worn on the face; A drive module fixed to the fixed frame; And a plurality of prisms or a plurality of frequency lenses are installed to move as the driving module is driven, and a movement module for replacing the prisms or frequency lenses corresponding to the eye as the prisms or the frequency lenses are moved. .

Description

Visual information processing function training device {VISION ACCOMODATION TRAINING APPARATUS}

The present invention relates to a time information processing function training apparatus for training a time information processing function.

The visual information processing function processes information between the eye and the brain and is called vision function. That is, the visual information processing function refers to the information input through tactile, olfactory, and auditory, and the information from the eye to the brain quickly and to integrate and interpret such information in the brain. This visual information processing function makes it possible to recognize a sense of distance, a sense of speed, a three-dimensional feeling, and the like.

The visual information processing function is generated almost irrespective of whether the eyesight is good or bad. If a problem occurs in the visual information processing function, sports or sports activities may be difficult, difficult to read, low attention, or writing problems may occur. Therefore, reading disorder, dyslexia, attention deficit disorder, learning disorder, writing disorder or social life disorder may occur.

The time information processing function may be generated due to the time when the eye is developed or when the time is excessively used (homework, reading, computer and television watching). Such visual information processing functions include binocular abnormalities and control disorders.

The binocular vision abnormality is caused by the fact that the extraocular muscles supporting the pupil do not function normally, and the adjustment disorder may occur when the lens is not shrunk or expanded normally.

However, in the related art, there are few methods for improving or correcting the subjective symptoms or problems of the visual information processing function. However, in the hospital, direct treatment such as visual acuity test, myopia, astigmatism treatment, eyeglasses wearing, etc., or stress relief according to unknown cause were performed.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide a visual information processing function training device that can treat abnormalities in binocular vision by improving or treating the effect of the extraocular muscles.

Another object of the present invention is to provide a visual information processing function training device that can treat a regulatory disorder by improving or treating the action of the lens.

According to an aspect of the present invention for achieving the above object, a fixed frame worn on the face; A drive module fixed to the fixed frame; A plurality of prisms or a plurality of frequency lenses are installed to move as the driving module is driven, and a movement module which allows the prism or frequency lenses corresponding to the eye to be replaced as the prisms or the frequency lenses are moved. Provide training equipment for visual information processing function.

The moving module may be reciprocally installed in the driving module, and prisms or power lenses may be arranged in the linear direction.

The moving module may be rotatably installed in the driving module, and prisms or power lenses may be arranged in a circular shape in the moving module.

In the moving module, one resting lens may be disposed for at least one prism or at least one frequency lens.

The fixed frame may include first and second eye corresponding parts corresponding to both eyes; And an earring part extending from the first and second eye corresponding parts to hang on the ear.

A moving module and a driving module may be installed in the first eye corresponding part.

When a plurality of prisms are installed in the moving module, a transparent window may be installed in the second eye corresponding part.

When a plurality of power lenses are installed in the moving module, a blind window may be installed in the second eye corresponding part.

The drive module, the motor unit for moving the moving module; A signal providing unit for receiving a driving signal transmitted from an operation unit and driving the motor unit according to the received driving signal to replace a prism or a power lens corresponding to an eye; And a power supply unit supplying power to the motor unit and the signal providing unit.

According to the present invention, the effect of the extraocular muscles is normally performed to improve or treat binocular abnormalities.

According to the present invention, it is possible to improve or treat a control disorder by allowing the lens to work normally.

1 is a perspective view showing a first embodiment of a visual information processing function training apparatus for treating binocular vision abnormality according to the present invention.
FIG. 2 is a front view illustrating a moving module constituting the visual information processing function training device of FIG. 1.
FIG. 3 is a block diagram illustrating the visual information processing function training device and the visual information processing function training system of FIG. 1.
4 is a schematic diagram illustrating a training course stored in the time information processing function training system of FIG. 3.
5 is a flowchart illustrating a training method of the time information processing function of FIG. 3.
6 is a flowchart illustrating a training step of the training method of the time information processing function of FIG. 3.
7 is a perspective view showing a second embodiment of a visual information processing function training device for treating binocular vision abnormality according to the present invention.
8 is a perspective view showing a third embodiment of a time information processing function training apparatus for the treatment of a control disorder according to the present invention.
FIG. 9 is a front view illustrating a mobile module constituting the visual information processing function training device of FIG. 8.
FIG. 10 is a flowchart illustrating a training method of the time information processing function of FIG. 8.
FIG. 11 is a flowchart illustrating a training step of the training method of the time information processing function of FIG. 8.
12 is a perspective view showing a fourth embodiment of a time information processing function training apparatus for the treatment of a control disorder according to the present invention.

Specific embodiments of the time information processing function training apparatus according to the present invention for achieving the above object will be described.

In general, the problem of visual information processing function occurs when the adjustment of the extraocular muscles of the eye or the lens is not performed normally. Disorders of the visual information processing function include binocular abnormalities and control disorders.

The binocular abnormality refers to a phenomenon in which an image formed on the retina overlaps or appears blurred when the ocular muscles, which are the muscles of the eye, are not normally contracted and relaxed. At this time, if the contraction or relaxation of the extraocular muscles is not balanced, the congestion force or the estimated force is excessive or insufficient and the line of sight does not coincide. Therefore, the image formed on the retina overlaps or becomes blurred.

Here, the congestion means that the two eyes gather toward the nose when looking closer, and the approximation means that the two eyes move away from each other so that the two eyes are parallel when viewed far.

In addition, the dysregulation refers to a phenomenon in which an object becomes blurred when the lens is not contracted and expanded normally. This dysregulation causes problems with focal length control.

Such binocular abnormalities or dysregulations are known to be caused by genetic causes, by trauma, or by an imbalance in neurological responses involved in eye movement.

The following describes the visual information processing function training device (first and second embodiments) capable of treating abnormalities in binocular vision, and then describes the visual information processing function training device (third and fourth embodiments) capable of treating a control disorder. Shall be.

[First Embodiment]

First, a first embodiment of a time information processing function training device according to the present invention will be described.

1 is a perspective view showing a first embodiment of a visual information processing function training apparatus for treating binocular vision abnormality according to the present invention, Figure 2 is a front view showing a mobile module constituting the visual information processing function training apparatus.

1 and 2, the visual information processing function training device 100 includes a fixed frame 110 worn on a face, a drive module 120 fixed to the fixed frame 110, and the drive module. The movement module 130 is moved as the 120 is driven.

The fixing frame 110 includes first and second eye corresponding parts 111 and 113 corresponding to both eyes, and earring parts 115 and 117 extending from the first and second eye corresponding parts 111 and 113, respectively, to be worn on the ears. It may include. The fixed frame 110 may be formed in a frame-like structure as a whole, as shown in FIG.

In addition, the fixing frame 110 has first and second eye corresponding parts 111 and 113 in both eyes, and earring parts 115 and 117 extending from the first and second eye corresponding parts 111 and 113, respectively, in the ear or the head. It can be formed of a stretchable member that can be hooked. In this case, the elastic member may be applied in various forms such as rubber bands, rubber bands.

The fixed frame 110 is not limited to the two examples described above may be formed in various forms. Hereinafter, the fixing frame formed in the shape of the spectacle frame will be described as an example.

The driving module 120 and the moving module 130 may be installed in the first eye corresponding part 111, and the transparent window 119 may be installed in the second eye corresponding part 113. In this case, the transparent window 119 refers to a transparent lens without a degree. The transparent window 119 is formed of plastic or glass and performs a function of opening one eye of the trainee 1.

The movement module 130 is provided with a plurality of prisms 135 to be moved as the drive module 120 is driven. In this case, the plurality of prisms 135 may be arranged in a line in a linear direction. The prism 135 is manufactured by using an optical technique to refract light in a specific direction to compensate for disparity in the line of sight.

In addition, one rest lens 137 may be disposed in each of the plurality of prisms 135 in the movement module 130. In this case, the resting lens 137 allows the trainee 1 to rest for a predetermined time while performing the time information processing function training to be described below. The relaxation lens 137 may be made of transparent plastic or glass.

Accordingly, the trainee 1 may open his / her eyes simultaneously and watch the avatar to be described below through the prism 135 and the resting lens 137. In addition, the trainee may take a break through the resting lens 137 and the resting lens 137 when training.

The driving module 120 receives a driving signal transmitted by the operation of the motor unit 121 and the operation unit 10 (see FIG. 3) for moving the moving module 130, and according to the received driving signal. A signal providing unit 125 for driving the motor unit 121 to replace the prism 135 corresponding to the eye, and a power supply unit supplying power to the motor unit 121 and the signal providing unit 125 ( 126).

The driving module 120 may further include a guide bar 127 to move the moving module 130 in a stable state. The cross-section of the guide bar 127 may be formed in a substantially "⊃" shape so that the moving module 130 is coupled to the reciprocating and does not fall out.

The motor unit 121 may include a driving motor 122 and a gear 123 coupled to the rotation shaft of the driving motor 122 to be engaged with the moving module 130. In this case, a stepping motor with an accurate rotation speed may be applied to the driving motor 122. In addition, the gear 123 may be a circular gear 123 having a tooth formed on the outer peripheral surface.

The signal providing unit 125 may be driven by a wireless communication method or by a wired communication method. Various forms may be applied to the signal providing unit 125.

An electric wire or a battery may be connected to the power supply unit 126.

As the driving motor 122 is driven, the driving module 120 may raise and lower the moving module 130 by one pitch or by a plurality of pitches. In this case, the pitch has a distance equal to the length of one prism 135. Therefore, whenever the moving module 130 is moved by one pitch, the adjacent prism 135 corresponds to the eye. As a result, as the moving module 130 is moved by one pitch by the driving module 120, the prism 135 corresponding to the eye is replaced.

However, the driving module 120 may be formed in a structure capable of manually operating the moving module 130.

For example, the driving module 120 may be configured to be geared only to be engaged with the moving module 130 and may be manually rotated by a user. The gear 123 of the drive module 120 may be formed in a form exposed to the outside to allow access from the outside.

In addition, the driving module 120 may be formed in a lever structure to move the moving module 130 by a predetermined pitch every time it is operated. At this time, the drive module 120 of the lever structure may be installed in a form exposed to the outside to be accessible from the outside.

The driving module 120 may be automatically or manually driven as described above. 2 illustrates a driving module 120 that is automatically driven. Hereinafter, a case in which the driving module 120 is automatically driven will be described as an example.

The moving module 130 is installed to be reciprocated as the driving module 120 is driven. The moving module 130 may be formed in a rectangular plate shape as a whole.

The moving module 130 may include a support frame 131 having a rectangular frame shape to fix the circumferences of the prism 135 and the resting lens 137. One side of the support frame 131 may be formed with a spur gear portion 132 along the longitudinal direction of the support frame 131. The gear 123 of the driving module 120 meshes with the spur gear 132.

As the driving module 120 is driven, the moving module 130 may be formed in a structure in which the plurality of prisms 135 and the rest lens 137 may be moved indefinitely. For example, the plurality of prisms 135 and the rest lens 137 are arranged in the form of a belt (belt) to form a belt structure, the pulley is fitted to both sides of the belt structure, one side of the pulley in the form of the motor is fitted Can be formed. Here, the belt-shaped prism 135 and the resting lens 137 may correspond to the moving module 130, and the pulleys and the motors on both sides may correspond to the driving module 120.

The moving module 130 may be formed in various structures as long as the plurality of prisms 135 and the rest lenses 137 are moved in a line.

The prisms 135 arranged in the moving module 130 may be selected as prisms 135 having an appropriate refractive index according to an optometrist or an optometrist's optometrist. The moving module 130 may be detachably coupled to the driving module 120 to change the arranged set of prisms 135 according to the optometry of the trainee 1.

The time information processing function training apparatus configured as described above may be applied to the time information processing function training system.

The training of the time information processing function may be classified into short-range training for training at a close distance and far-field training for training at a long distance. The short distance training is performed at a position where the distance between the display apparatus 40 and the time information processing training device 100 is approximately 40 cm away. In addition, the long distance training is performed at a position where the distance between the display apparatus 40 and the time information processing function training device 100 is approximately 3 m away.

Trainee (1) is examined by a professional optometrist or an ophthalmologist. At this time, the prism 135 having an appropriate range of congestion and estimate power may be selected according to the optometry of the trainee 1. In addition, the prism 135 of the moving module 130 may be arranged so that the runaway force or the estimated force may be improved in stages. In addition, the prism 135 of the mobile module 130 may be selectively injected according to the training area to be described below, so that the congestion force or the estimated force of the trainee 1 may have a normal ratio.

The moving module 130 is arranged in the near training prism or the distance training prism according to the state of the optometrist of the trainee (1). The above-mentioned short distance training prism and long distance training prism may be applied with various diopter prisms.

An example of the prism 135 installed in the moving module 130 is as follows. 10, 12, 15, 16, 18 prisms are used as the near-field training prism 135, and 4, 6, 8, 10, 15 prisms are used as the prism 135 for the distance training. At this time, the prism 135 is preferably selected individually by the optometrist of the trainee 1, it is possible to select the general prism 135 according to the eye state of the trainee 1 to perform the training.

3 is a block diagram showing a city information processing function training apparatus and a city information processing function training system.

Referring to FIG. 3, the time information processing function system is a system that can be used to improve the time information processing function of the trainee 1.

The time information processing system includes an operation unit 10, a processor 20, a storage device 30, a display device 40, and a moving mechanism 50.

The operation unit 10 is a device for the trainee 1 or the training leader 5 to operate the visual information processing system and the visual information processing function training device 100. As the manipulation unit 10, a mouse, a keyboard, a joy team, a remote controller, or the like may be applied. In addition, the operation unit 10 may be a device capable of being wired or wirelessly connected to the city information processing system and the city information processing function training device 100 by wire or remotely.

The processor 20 executes a time information processing training program. In addition, the display device 40 displays a training program executed by the processor 20. In addition, the movement mechanism 50 is a device for moving the display device 40 to an appropriate position according to the training mode.

The time information processing training program is set in the storage device 30. Various programs such as bicycle riding, skiing, boarding, flight driving or inline skating may be applied to the time information training program.

In the above-described visual information processing function system, the trainee 1 wears the visual information processing function training device 100 and then performs the visual information processing training while watching the avatar 7 displayed through the display device 40. At this time, it is displayed that the avatar 7, which is the alter ego of the trainee 1, performs cycling, skiing, boarding, flight driving, or inline skating, and the trainee 1 is driven by the avatar 7. In the process of overcoming obstacles or overcoming obstacles, visual information processing training is performed.

The visual information processing function is improved as the binocular vision function of the eye is enhanced. In general, binocular function is a function of integrating the images formed on the retina of both eyes into a single object. The binocular function is improved by repeatedly training the approximation function to open the eyes of both eyes and the congestion function to collect the eyes of both eyes. The reason for this is that repeated training of the estimated and congested function of the pupil strengthens the extraocular muscles that control the contraction and relaxation of the eyeball.

Here, the approximation means that the two eyes move away from each other so that both eyes are parallel when viewed from a distance, and the congestion means that the two eyes gather toward the nose when viewed close.

The visual information processing function training according to the present invention is training to strengthen the extraocular muscle that controls the contraction and relaxation of the eye by observing the movement of the avatar 7 through the prism 135. Such visual information processing skills training can improve the congestion power and the calculation power of both eyes. Therefore, it is possible to improve or treat abnormalities in binocular vision.

4 is a schematic diagram showing a training course stored in the time information processing function training system.

Referring to FIG. 4, the training course 70 may be represented as an image of riding a bicycle in the display device 40. The training course 70 is set a plurality of obstacle input section (TD / TC). When the avatar 7 reaches the obstacle injection section TD / TC, the moving module 130 is moved one pitch as the driving module 120 is driven. At this time, the prism 135 corresponding to the eye is changed to another prism 135.

The obstacle injection section TD / TC may be set to about 2-15 minutes or about 5-10 minutes. At this time, the trainee 1 performs the congestion force or the estimated force training while the avatar 7 is driving the obstacle injection section (TD / TC). The time setting of the obstacle input section TD / TC may be arbitrarily set again within the preset range in the storage device 30 when the trainee 1 or the training leader 5 sets the avatar 7.

At this time, when the avatar 7 does not pass the obstacle injection section (TD / TC) for a set time, the avatar 7 is no longer able to control the training course 70 by adjusting the operation unit 10 of the training system. The vehicle returns to the initial position (start section in FIG. 4) without traveling. In addition, the movement module 130 is moved by the training leader 5 or the trainee 1 by operating the operation unit 10. At this time, the prism 135 lower than the prism 135 corresponding to the current eye corresponds to the eye. Then, it returns to the initial position and resumes training while gradually increasing the stage in the low stage prism 135.

In addition, in the present invention, the avatar 7 may be configured as an image or video imaged, and can be executed through on / off line. That is, the avatar 7 may be made by moving picture information through a program or a real shot image by a camcorder or the like. In addition, the avatar 7 can be easily implemented offline through online, a projector, and an enlarger using a communication network such as the Internet.

The process of training the city information processing function using the city information processing function training device and the city information processing function training system according to the present invention configured as described above will be described.

5 is a flowchart illustrating a training method of the time information processing function, and FIG. 6 is a flowchart illustrating a training step of the training method of the time information processing function.

5 and 6, the optometrist or the ophthalmologist who is the training leader 5 grasps the eye state of the trainee 1. The training leader 5 operates and stores the operation unit 10 in the storage device 30 in accordance with the information on the examination of the trainee 1 regarding the personal information of the trainee 1 or the state and preference of the binocular function. . Therefore, when the training leader 5 selects the recognition information about the trainee 1, the process identifies the trainee 1 based on the information stored in the storage device 30 and fits the trainee 1. The training course 70 is selected (S101).

The training course 70 is represented by an image of riding on a bicycle in the display device 40 as shown in FIG. The training course 70 is set a plurality of obstacle input section (TD / TC). When the avatar 7 reaches the obstacle injection section TD / TC, the moving module 130 is moved one pitch as the driving module 120 is driven. At this time, the prism 135 corresponding to the eye is changed to another prism 135.

The obstacle injection section TD / TC may be set to about 2-15 minutes or about 5-10 minutes. At this time, the trainee 1 performs the congestion force or the estimated force training while the avatar 7 is driving the obstacle injection section (TD / TC). The time setting of the obstacle input section TD / TC may be arbitrarily set again within the preset range in the storage device 30 when the trainee 1 or the training leader 5 sets the avatar 7.

Further, the trainee 1 sets the avatar 7 which is the alter ego of the trainee 1 (S102). At this time, the characteristics of the trainee 1 are reflected on the avatar 7 so as to have a sense of identity with the avatar 7. That is, the avatar 7 reflects the age, cognition level, and experience level of the trainee 1 through the manipulation unit 10. In addition, the progress of the trainee 1 can fully recognize and learn may be provided as a story (story). For example, the story is structured so that you can go on and enjoy the journey with tools that allow you to use balancing techniques such as cycling, skiing, and boarding.

In addition, the training leader 5 may select the near prism 135 or the remote prism 135 to maintain the normal ratio and the bursting force of the trainee 1 (S103). For example, the short distance prisms 135 may select 10, 12, 15, 16, and 18 prisms 135. In addition, 4, 6, 8, 10, and 15 prisms 135 may be selected as the remote prisms 135. The selected prism 135 is installed in the drive module 120 of the time information processing function training device 100.

Subsequently, when the training leader 5 or the trainee 1 operates the manipulation unit 10, the processor 20 displays the training course 70 and the avatar 7 on the display device 40. Then, the avatar 7 performs the visual information processing function training by driving the training course 70. Hereinafter, the bicycle training course 70 of the training course 70 will be described as an example.

In the first course driving step, the avatar 7 rides the first course while riding the bicycle (S104). The trainee 1 performs the first training step while the avatar 7 runs on the first course (S105).

In the first training step, when the trainee 1 corresponds to the eye of the first prism 135, the screen of the first course is blurred. In addition, the trainee 1 performs the visual information processing function training while trying to clearly see the object and the avatar 7 through the first prism 135.

At this time, when the trainee 1 does not see the object and the avatar 7 clearly for a predetermined time, the trainee 1 cannot operate the manipulation unit 10 and thus cannot pass the first course. If the avatar 7 fails to pass the first course, the avatar 7 returns to the beginning of the training course 70 and is replaced with the lowest prism 135 as the moving module 130 is moved. do. In this case, training is performed again from the beginning of the training course 70.

In addition, when the trainee 1 clearly sees the object and the avatar 7 within a predetermined time, the trainee 1 selects the manipulation unit 10. At this time, as the moving module 130 is moved one pitch, it is replaced with a high prism 135.

When the avatar 7 has passed through the first course, the avatar 7 moves to the second course where the training is repeated with the second prism 135 having a higher level (S106-S108).

 After the avatar 7 enters the second course driving step (S109), the avatar 7 travels the second course (S110). While driving the second course, when the obstacle is injected, the operation unit 10 is operated to move the moving module 130 by one pitch to replace the second prism 135 having a higher level (S112). . When the prism 135 of the moving module 130 is replaced at a higher level, the trainee 1 trains to clearly see the object (avatar) superimposed by the second prism 135, and thus estimates or congestion force. You will be training.

When the first and second course driving steps are completed as described above, the training leader 5 or the trainee 1 operates the manipulation unit 10 so that the resting lens 137 corresponds to the eye. Move). At this time, when the eye corresponds to the rest lens 137, the trainee 1 has a rest time for a predetermined time by looking at the rest lens 137 or closing the eyes (S113).

When the rest time elapses or when the manipulation unit 10 is operated, the above-described course training steps are repeated again (S114).

Meanwhile, as illustrated in FIG. 4, each training step includes a stop step (S21) of stopping the progress of the avatar 7 by the timing of obstacle injection, and the visual information processing when the progress of the avatar 7 is stopped. The trainee 1 gazes at the step S22 of replacing the prism 135 by operating the functional training device 100 and the image of the object on the display device 40 blurred by the replaced prism 135. In step S23, the training leader 5 or the trainee 1 operates the operation unit 10 to advance the avatar 7 as the congestion force / calculation force is improved. S24).

In the stopping step, the progress of the avatar 7 is automatically stopped by the elapse of the set time of the obstacle input section TD / TC. In this case, the obstacle input section (TD / TC) may be automatically set according to the trainer arbitrarily selected or preset in the program.

The prism 135 replacement step is to replace the prism 135 as the story progresses according to the avatar 7. That is, when the operation unit 10 is operated, the driving module 120 is driven to move the moving module 130 to replace the prism 135 of the moving module 130.

In the prism 135 replacement step, the manipulation unit 10 is operated to replace the prism 135 with an appropriate prism 135 according to the training course 70 of the display device 40 and the obstacle insertion section TD / TC. At this time, the prism 135 of the moving module 130 is gradually replaced with the prism 135 of the high diopter value as the avatar 7 moves the training course 70. That is, at the beginning of the training course 70, the training is performed by replacing the diopter prism 135 having a low value, and the diopter prism 135 having a higher value is inputted toward the later stage of the training course 70. As you increase the intensity of your training gradually, you increase your training intensity.

The runaway force / calculation force improvement step is a training process in which the trainee 1 clearly sees an object image overlapped or blurred by the prism 135. That is, when the prism 135 is replaced, an object of the display device 40 is overlaid or blurred on the eyes of the trainee 1. At this time, the trainee 1 is trained to concentrate on clearly seeing the superimposed or faintly visible object image. Therefore, the extraocular muscles supporting the pupils can be strengthened to improve the congestion power and the estimated power.

If the trainer continues to train to clearly see the image of the overlapping or faint object, the trainee 1 operates the operation unit 10 to advance the avatar 7. This step is a progression step.

In the training step, the avatar 7 progresses while the obstacle is injected, and the avatar 7 proceeds for a predetermined time only when the signal is transmitted by the operation unit 10.

This training step is designed to shorten the time for the trainee 1 to clearly see the image of the overlapping object by repeating the runaway / estimated power improvement step and the prism 135 replacement. At this time, it is preferable that the time to clearly see the object image satisfies the range within 0.5-1 second.

By the repetition of the training step, the story development of the avatar 7 proceeds, thereby improving the binocular function of the trainee 1. As the binocular vision function is improved, the visual information processing function may be improved.

[Second Embodiment]

Next, a second embodiment of the time information processing function training apparatus according to the present invention will be described.

7 is a perspective view showing a second embodiment of a time information processing function training apparatus according to the present invention.

Referring to FIG. 7, the visual information processing function training device 200 includes a fixed frame 210 worn on a face, a drive module 220 fixed to the fixed frame 210, and the drive module 220. It includes a moving module 230 is moved as it is driven.

The fixing frame 210 includes first and second eye corresponding parts 211 and 213 corresponding to both eyes, and earring parts 215 and 217 extending from the first and second eye corresponding parts 211 and 213, respectively, to be worn on the ear. It may include. The fixed frame 210 may be formed in a frame-like structure as a whole, as shown in FIG.

In addition, the fixing frame 210 is an elastic member that can be worn on the ear or the head by extending from the first and second eye corresponding parts 211 and 213 and the first and second eye corresponding parts 211 and 213 to both eyes, respectively. The earrings 215 and 217 may be formed. In this case, the elastic member may be applied in various forms such as rubber bands, rubber bands.

The fixed frame 210 is not limited to the above two examples and may be formed in various forms. Hereinafter, the fixing frame formed in the shape of the spectacle frame will be described as an example.

The driving module 220 and the moving module 230 may be installed in the first eye corresponding part 211, and the transparent window 219 may be installed in the second eye corresponding part 213. In this case, the transparent window 219 functions to make an alien object visible to one eye. The transparent window 219 may be formed of a plastic or glass material.

In addition, one resting lens 237 may be disposed in each of the plurality of prisms 235 in the moving module 230. In this case, the resting lens 237 allows the trainee 1 to rest for a predetermined time while performing the time information processing function training to be described below.

The movement module 230 may also be formed in a disc shape in which a plurality of prisms 235 and a rest lens 237 are arranged in a circular shape.

Prisms 235 arranged in the movement module 230 may be selected as prisms 235 having an appropriate refractive index according to an optometrist or an optometrist's optometrist. The moving module 230 may be detachably coupled to the driving module 220 to change the arranged prism set according to the optometry of the trainee 1.

The driving module 220 receives the driving signal transmitted by the operation of the motor unit 121 (see FIG. 2) and the operation unit 10 (see FIG. 3) for rotating the moving module 230, and receives the received driving. The signal providing unit 125 (see FIG. 2) for driving the motor unit 121 according to the signal so that the prism 235 corresponding to the eye is replaced, and the motor unit 121 and the signal providing unit 125. It may include a power supply unit 126 (see Fig. 2) for supplying power.

The motor unit 121 may include a driving motor 122 (see FIG. 2). In this case, a stepping motor with an accurate rotation speed may be applied to the driving motor 122.

The signal providing unit 125 may be driven by a wireless communication method or by a wired communication method. Various forms may be applied to the signal providing unit 125.

An electric wire or a battery may be connected to the power supply unit 126.

The driving module 220 may rotate the moving module 230 by a predetermined angle as the driving motor 122 is driven. Therefore, whenever the moving module 230 is rotated by a predetermined angle, the adjacent prism 135 corresponds to the eye. As a result, the prism 235 corresponding to the eye is replaced as the moving module 230 is rotated by a predetermined angle by the driving module 220.

However, the driving module 220 may be formed in a structure capable of manually manipulating the moving module 230.

The drive module 220 may be automatically or manually driven as described above. 2 shows a driving module 220 that is automatically driven. Hereinafter, a case in which the driving module 220 is automatically driven will be described as an example.

The moving module 230 is rotatably installed as the driving module 220 is driven. The moving module 230 may include a plurality of ribs 231 extending radially from the rotation axis of the driving motor 122. In this case, one prism 235 and a rest lens 237 may be coupled to the end of each rib 231. The plurality of prisms 235 and the resting lens 237 may be arranged along the circumferential direction. These prisms 235 are fabricated using optical technology.

According to the second embodiment of the visual information processing function training device as described above, the movement module 230 is rotatably disposed, and the prism 235 and the resting lens 237 are arranged in a circular shape on the movement module 230. There is a difference from the first embodiment. This second embodiment is substantially the same as the training process of the first embodiment except that the moving module 230 rotates in the time information processing function training process. Therefore, a detailed description of the time information processing function training process according to the second embodiment will be omitted.

[Third Embodiment]

Next, a third embodiment of the time information processing function training apparatus according to the present invention will be described.

8 is a perspective view showing a third embodiment of a visual information processing function training device for the treatment of a control disorder according to the present invention, Figure 9 is a front view showing a mobile module constituting the visual information processing function training device.

8 and 9, the visual information processing function training device 300 includes a fixed frame 310 worn on a face, a drive module 320 fixed to the fixed frame 310, and the drive module. The movement module 330 is moved as the 320 is driven.

The fixing frame 310 includes first and second eye corresponding parts 311 and 313 corresponding to both eyes, and earring parts 315 and 317 extending from the first and second eye corresponding parts 311 and 313, respectively, to be worn on the ears. It may include. As shown in FIG. 1, the fixing frame 310 may be formed in a frame-like structure as a whole.

In addition, the fixing frame 310 has first and second eye corresponding parts 311 and 313 on both eyes, and earring parts 315 and 317 extending from the first and second eye corresponding parts 311 and 313 respectively. It can be formed of a stretchable member that can be hooked. In this case, the elastic member may be applied in various forms such as rubber bands, rubber bands.

The fixed frame 310 is not limited to the above-described example may be formed in various forms. Hereinafter, the fixing frame formed in the shape of the spectacle frame will be described as an example.

A driving module 320 and a moving module 330 may be installed in the first eye corresponding part 311, and a blind window 319 may be installed in the second eye corresponding part 313. At this time, the blind window 319 functions to hide one eye of the trainee. The blind window 319 may be formed of plastic, glass, or metal.

The movement module 330 is provided with a plurality of spectacle lenses 335 to be moved as the driving module 320 is driven. In this case, the plurality of spectacle lenses 335 may be arranged in a line in a linear direction. This power lens 335 is manufactured using optical technology.

In addition, one rest lens 337 may be disposed in each of the plurality of frequency lenses 335 in the movement module 330. In this case, the rest lens 337 allows the trainee 1 to rest for a predetermined time while performing the time information processing function training to be described below. The relaxation lens 337 may be made of transparent plastic or glass.

Accordingly, the trainee 1 may engage in training while watching the avatar to be described below through the power lens 335 and the resting lens 337 with only one eye. In addition, the trainee can take a break through the resting lens 335 when training, but cannot see through the blind window 319.

In addition, as the driving module 320 is driven, the moving module 330 may have a structure in which a plurality of power lenses 135 and a resting lens 337 may be driven in an infinite track. For example, the plurality of power lenses 335 and the resting lens 337 are arranged in a belt form to form a belt structure, and pulleys are fitted to both sides of the belt structure, and a motor is fitted to one pulley. It can be formed as. Here, the belt-shaped prism 335 and the resting lens 337 may correspond to the moving module 130, and the pulleys and the motors at both sides may correspond to the driving module 320.

The moving module 330 may be formed in various structures as long as the plurality of power lenses 335 and the resting lens 337 are moved in a line.

The power lenses 335 arranged in the movement module 330 may be selected as power lenses 335 having an appropriate power according to an optometrist or an optometrist's optometry. The moving module 330 may be detachably coupled to the driving module 320 to change the arranged set of the lens 335 according to the optometry of the trainee 1.

The driving module 320 receives the driving signal transmitted by the operation of the motor unit 321 and the operation unit 10 (see FIG. 3) for moving the moving module 330, and according to the received driving signal. A signal supply unit 325 for driving the motor unit 321 to replace the power lens 335 corresponding to the eye, and a power supply unit for supplying power to the motor unit 321 and the signal provider 325. 326 may be included.

The drive module 320 may further include a guide bar 327 to move the moving module 330 in a stable state. The cross section of the guide bar 327 may be formed in a substantially "⊃" shape so that the moving module 330 is reciprocally coupled and does not fall out.

The motor unit 321 may include a drive motor 322 and a gear 323 coupled to the rotation shaft of the drive motor 322 and installed to mesh with the moving module 330. In this case, a stepping motor with an accurate rotation speed may be applied to the driving motor 322. In addition, the gear 323 may be a circular gear 323 having a tooth formed on the outer peripheral surface.

The signal providing unit 325 may be driven by a wireless communication method or by a wired communication method. Various forms may be applied to the signal providing unit 325.

The power supply unit 326 may be connected to a wire or a battery (battery).

As the driving motor 322 is driven, the driving module 320 may raise and lower the moving module 330 by one pitch or by a plurality of pitches. In this case, the pitch has a distance equal to the length of one prism 335. Therefore, whenever the moving module 330 is moved by one pitch, the adjacent prism 335 corresponds to the eye. As a result, as the moving module 330 is moved by one pitch by the driving module 320, the frequency lens 335 corresponding to the eye is replaced.

However, the driving module 320 may be formed in a structure capable of manually manipulating the moving module 330.

For example, the driving module 320 may be configured to be geared only to be engaged with the moving module 330 and to be manually rotated by a user. The gear 323 of the drive module 320 may be formed to be exposed to the outside to allow access from the outside.

In addition, the driving module 320 may be formed in a lever structure so as to move the moving module 330 by a predetermined pitch every time it is operated. At this time, the drive module 320 of the lever structure may be installed in the form exposed to the outside to be accessible from the outside.

The driving module 320 may be automatically or manually driven as described above. 9 illustrates a driving module 320 that is automatically driven. Hereinafter, a case in which the driving module 320 is automatically driven will be described as an example.

The moving module 330 is installed to be reciprocated as the driving module 320 is driven. The moving module 330 may be formed in a rectangular plate shape as a whole.

The moving module 330 may include a support frame 331 having a rectangular frame shape to fix the circumferences of the power lens 335 and the resting lens 337. One side of the support frame 331 may be formed with a spur gear portion 332 in the longitudinal direction of the support frame 331. The gear 323 of the driving module 320 is engaged with the spur gear 332.

The time information processing function training apparatus configured as described above may be applied to the time information processing function training system.

The training of the time information processing function may be classified into short-range training for training at a close distance and far-field training for training at a long distance. The short distance training is performed at a position where the distance between the display apparatus 40 and the time information training apparatus 300 is about 40 cm away. In addition, the long distance training is performed at a position where the distance between the display device 40 and the time information processing function training device 300 is approximately 3 m away.

Trainee (1) is examined by a professional optometrist or an ophthalmologist. At this time, the frequency lens 335 having the frequency may be selected according to the optometry state of the trainee 1. In addition, the frequency lens 335 of the moving module 330 may be arranged so that the frequency can be improved step by step. In addition, the power lens 335 of the moving module 330 is selectively put in accordance with the training area to be described below, so that the lens of the trainee 1 can finally be contracted and expanded at a normal rate.

The moving module 330 is arranged near the power training lenses or distance training lenses according to the state of the optometrist of the trainee (1). Various prisms may be applied to the above-mentioned range training frequency lens and the range training frequency lens.

At this time, the power lenses 335 are preferably selected individually by the optometrist of the trainee 1, but can be trained by selecting a general-purpose power lens 335 according to the eye state of the trainee (1) have.

3 is a block diagram showing a city information processing function training apparatus and a city information processing function training system.

Referring to FIG. 3, the time information processing function system is a system that can be used to improve the time information processing function of the trainee 1.

The time information processing system includes an operation unit 10, a processor 20, a storage device 30, a display device 40, and a moving mechanism 50.

The operation unit 10 is a device for the trainee 1 or the training leader 5 to operate the visual information processing system and the visual information processing function training device 300. As the manipulation unit 10, a mouse, a keyboard, a joy team, a remote controller, or the like may be applied. In addition, the operation unit 10 may be a device which is connected to the time information processing system and the time information processing function training device 300 by wire or remotely to enable wired communication or wireless communication.

The processor 20 executes a time information processing training program. In addition, the display device 40 displays a training program executed by the processor 20. In addition, the movement mechanism 50 is a device for moving the display device 40 to an appropriate position according to the training mode.

The time information processing training program is set in the storage device 30. Various programs such as bicycle riding, skiing, boarding, flight driving or inline skating may be applied to the time information training program.

In the above-described visual information processing function system, the trainee 1 wears the visual information processing function training device 300 and then performs the visual information processing training while watching the avatar 7 displayed through the display device 40. At this time, it is displayed that the avatar 7, which is the alter ego of the trainee 1, performs cycling, skiing, boarding, flight driving, or inline skating, and the trainee 1 is driven by the avatar 7. In the process of overcoming obstacles or overcoming obstacles, visual information processing training is performed.

The visual information processing function is improved in the ability to adjust the contraction and expansion of the lens. In general, the regulating function is to adjust the contraction and expansion of the lens at an appropriate ratio.

The visual information processing function training according to the present invention is a training for controlling the contraction and relaxation of the lens by observing the movement of the avatar 7 through the power lens 335. This visual training function improves or treats the control disorder so that the blurred object is clearly visible.

4 is a schematic diagram showing a training course stored in the time information processing function training system.

Referring to FIG. 4, the training course 70 may be represented as an image of riding a bicycle in the display device 40. The training course 70 is set a plurality of obstacle input section (TD / TC). When the avatar 7 reaches the obstacle injection section TD / TC, the moving module 330 is moved one pitch as the driving module 320 is driven. At this time, the frequency red 335 corresponding to the eye is changed to another frequency lens 335.

The obstacle injection section TD / TC may be set to about 2-15 minutes or about 5-10 minutes. In this case, the trainee 1 performs contraction and expansion of the lens while the avatar 7 travels the obstacle injection section TD / TC. The time setting of the obstacle input section TD / TC may be arbitrarily set again within the preset range in the storage device 30 when the trainee 1 or the training leader 5 sets the avatar 7.

At this time, when the avatar 7 does not pass the obstacle injection section (TD / TC) for a set time, the avatar 7 is no longer able to control the training course 70 by adjusting the operation unit 10 of the training system. The vehicle returns to the initial position (start section in FIG. 11) without traveling. In addition, the movement module 330 is moved by the training leader 5 or the trainee 1 by operating the operation unit 10. At this time, the frequency lens 335 which is lower than the frequency lens 335 corresponding to the current eye corresponds to the eye. Then, it returns to the initial position and resumes training while gradually increasing the level in the low-frequency power lens 335.

In addition, in the present invention, the avatar 7 may be configured as an image or video imaged, and can be executed through on / off line. That is, the avatar 7 may be made by moving picture information through a program or a real shot image by a camcorder or the like. In addition, the avatar 7 can be easily implemented offline through online, a projector, and an enlarger using a communication network such as the Internet.

The process of training the city information processing function using the city information processing function training device and the city information processing function training system according to the present invention configured as described above will be described.

10 is a flowchart illustrating a training method of the time information processing function, and FIG. 11 is a flowchart illustrating a training step among the training methods of the time information processing function.

10 and 11, the optometrist or the ophthalmologist who is the training leader 5 grasps the eye state of the trainee 1. The training leader 5 operates and stores the operation unit 10 in the storage device 30 according to the information on the examination of the trainee 1 regarding the personal information, the adjustment function state, the preference, and the like of the trainee 1. Therefore, when the training leader 5 selects the recognition information about the trainee 1, the process identifies the trainee 1 based on the information stored in the storage device 30 and fits the trainee 1. Select a training course 70 (S301).

The training course 70 is represented by an image of riding on a bicycle in the display device 40 as shown in FIG. The training course 70 is set a plurality of obstacle input section (TD / TC). When the avatar 7 reaches the obstacle injection section TD / TC, the moving module 330 is moved one pitch as the driving module 120 is driven. At this time, the frequency lens 135 corresponding to the eye is changed to another frequency lens 335 by operating the operation unit 10.

The obstacle injection section TD / TC may be set to about 2-15 minutes or about 5-10 minutes. In this case, the trainee 1 is trained to control the contraction and expansion of the lens while the avatar 7 is driving the obstacle injection section (TD / TC). The time setting of the obstacle input section TD / TC may be arbitrarily set again within the preset range in the storage device 30 when the trainee 1 or the training leader 5 sets the avatar 7.

Further, the trainee 1 sets the avatar 7 which is the alter ego of the trainee 1 (S302). At this time, the characteristics of the trainee 1 are reflected on the avatar 7 so as to have a sense of identity with the avatar 7. That is, the avatar 7 reflects the age, cognition level, and experience level of the trainee 1 through the manipulation unit 10. In addition, the progress of the trainee 1 can fully recognize and learn may be provided as a story (story). For example, the story is structured so that you can go on and enjoy the journey with tools that allow you to use balancing techniques such as cycling, skiing, and boarding.

In addition, the training leader 5 may select near-field power lenses 335 or long-range control lenses 335 to maintain the normal ratio of the lens. The selected power lenses 335 are installed in the drive module 320 of the time information processing function training device 300.

Subsequently, when the training leader 5 or the trainee 1 operates the manipulation unit 10, the processor 20 displays the training course 70 and the avatar 7 on the display device 40. Then, the avatar 7 performs the visual information processing function training by driving the training course 70. Hereinafter, the bicycle training course 70 of the training course 70 will be described as an example.

In the first course driving step, the avatar 7 rides the first course while riding the bicycle (S304). The trainee 1 performs the first training step while the avatar 7 travels on the first course (S305).

In the first training step, the trainee 1 blurs the screen of the first course when the frequency lens 135 corresponds to the eye. The trainee 1 performs the visual information processing function training while trying to clearly see the object and the avatar 7 through the power lens 335.

At this time, when the trainee 1 does not see the object and the avatar 7 clearly for a predetermined time, the trainee 1 cannot operate the manipulation unit 10 and thus cannot pass the first course. When the avatar 7 fails to pass the first course, the avatar 7 returns to the beginning of the training course 70 and moves to the lowest level power lens 335 as the moving module 330 is moved. Replaced. In this case, training is performed again from the beginning of the training course 70.

In addition, when the trainee 1 clearly sees the object and the avatar 7 within a predetermined time, the trainee 1 selects the manipulation unit 10. At this time, as the moving module 330 is moved 1 pitch, it is replaced with the high-frequency power lens 335.

When the avatar 7 passes the first course in this manner, the avatar 7 moves to the second course where the training is repeated with the higher frequency lens 335 (S306-S308).

 After the avatar 7 enters the second course driving step (S309), the avatar 7 travels the second course (S310). While driving the second course, when the obstacle is injecting time, the operation unit 10 is operated to move the moving module 330 by one pitch to be replaced with the higher frequency lens 335 (S312). When the frequency lens 335 of the moving module 330 is replaced at a higher level, the trainee 1 clearly sees a blurred object (avatar) by the frequency lens 335.

When the first and second course driving steps are completed as described above, the training leader 5 or the trainee 1 operates the operation unit 10 so that the resting lens 337 corresponds to the eye. Move). At this time, when the eye corresponds to the rest lens 337, the trainee 1 has a rest time for a predetermined time by looking at the rest lens 337 or closing the eyes (S313).

When the rest time elapses or when the manipulation unit 10 is operated, the above-described course training steps are repeated again (S314).

Meanwhile, as illustrated in FIG. 11, each training step includes a stop step S31 of stopping the progress of the avatar 7 by the timing of obstacle insertion, and the visual information processing when the progress of the avatar 7 is stopped. Step (S32) of operating the functional training device 300 to replace the frequency lens 335, and the image of the object (image) on the display device 40 blurred by the replaced frequency lens 335 trainee (1) Step (S33) to improve the adjusting ability of the lens gaze stare, the progress of the training leader (5) or trainee (1) to advance the avatar 7 by operating the operation unit 10 as the image of the object becomes clear Step S34 is included.

In the stopping step, the progress of the avatar 7 is automatically stopped by the elapse of the set time of the obstacle input section TD / TC. In this case, the obstacle input section (TD / TC) may be automatically set according to the trainer arbitrarily selected or preset in the program.

The step of replacing the frequency lens 335 is to replace the frequency lens 335 as the story progresses according to the avatar 7. That is, when the operation unit 10 is operated, the driving module 320 is driven to move the moving module 330 to replace the frequency lens 335 of the moving module 330.

In the step of replacing the power lens 335, the power lens 335 is replaced with an appropriate power lens 335 according to the training course 70 and the obstacle input period TD / TC of the display device 40 by operating the manipulation unit 10. At this time, the power lens 335 of the moving module 330 is gradually replaced with the high power lens 335 as the avatar 7 runs the training course 70. That is, in the early stage of the training course 70, the training is performed by replacing with a low frequency power lens 335, and a higher frequency power lens 335 is inputted toward the later stage of the training course 70. As you increase the intensity of your training gradually, you increase your training intensity.

The adjusting step is a training process in which the trainee 1 clearly sees an object image overlapped or blurred by the frequency lens 135. That is, when the frequency lens 135 is replaced, the object of the display device 40 is overlaid or blurred on the eyes of the trainee 1. At this time, the trainee 1 is trained to concentrate to see clearly visible object image. Thus, the ability of contraction and expansion of the lens can be improved.

If the trainer continues to train to clearly see the image of the overlapping or faint object, the trainee 1 operates the operation unit 10 to advance the avatar 7. This step is a progression step.

In the training step, the avatar 7 progresses while the obstacle is injected, and the avatar 7 proceeds for a predetermined time only when the signal is transmitted by the operation unit 10.

This training step is designed to shorten the time for the trainee 1 to clearly see the image of the superimposed object by repeating the adjustment capability improvement step and the replacement of the frequency lens 335. At this time, it is preferable that the time to clearly see the object image satisfies the range within 0.5-1 second.

By the repetition of the training step, the story development of the avatar 7 proceeds to improve the lens control ability of the trainee 1. As the adjusting capability is improved, the time information processing function can be improved.

[Fourth Embodiment]

Next, a fourth embodiment of the time information processing function training apparatus according to the present invention will be described.

12 is a perspective view showing a fourth embodiment of a time information processing function training apparatus according to the present invention.

Referring to FIG. 12, the visual information processing function training device 400 includes a fixed frame 410 worn on a face, a drive module 420 fixed to the fixed frame 410, and the drive module 420. It includes a moving module 430 is moved as it is driven.

The fixed frame 410 includes first and second eye corresponding parts 411 and 413 corresponding to both eyes, and earring parts 415 and 417 that extend from the first and second eye corresponding parts 411 and 413, respectively, to be worn on the ear. It may include. The fixed frame 410 may be formed as a frame-like structure as a whole, as shown in FIG.

In addition, the fixing frame 410 is an elastic member which can be worn on the ear or the head by extending from the first and second eye corresponding parts 411 and 413 and the first and second eye corresponding parts 411 and 413 to both eyes, respectively. The earrings 415 and 417 may be formed. In this case, the elastic member may be applied in various forms such as rubber bands, rubber bands.

The fixed frame 410 is not limited to the above-described example may be formed in various forms. Hereinafter, the fixing frame formed in the shape of the spectacle frame will be described as an example.

A driving module 420 and a moving module 430 may be installed in the first eye corresponding part 411, and a blind window 419 may be installed in the second eye corresponding part 413. In this case, the blind window 419 serves to shield an object from the outside world in one eye.

In addition, one rest lens 437 may be disposed in each of the plurality of frequency lenses 435 in the movement module 430. In this case, the resting lens 437 allows the trainee 1 to rest for a predetermined time while performing the time information processing function training to be described below.

The moving module 430 may also be formed in a disc shape in which a plurality of power lenses 435 and a resting lens 437 are arranged in a circular shape.

The power lenses 435 arranged in the movement module 430 may be selected as power lenses 435 having an appropriate refractive index according to an optometrist or an optometrist's optometrist. The moving module 430 may be detachably coupled to the driving module 420 so that the set of the arranged power lens 435 can be changed according to the optometry of the trainee 1.

The driving module 420 receives the driving signal transmitted by the operation of the motor unit 421 and the operation unit 10 (see FIG. 9) to rotate the moving module 430, and according to the received driving signal. Power is supplied to the signal providing unit 125 (see FIG. 3) for driving the motor unit 421 so that the power lens 435 corresponding to the eye is replaced, and the motor unit 421 and the signal providing unit 125. And a power supply unit 126 (see FIG. 3).

The motor unit may include a driving motor. In this case, a stepping motor with an accurate rotation speed may be applied to the drive motor.

The signal providing unit 125 may be driven by a wireless communication method or by a wired communication method. Various forms may be applied to the signal providing unit.

The power supply unit 426 may be connected to a wire or a battery (battery).

The driving module 420 may rotate the moving module 430 by a predetermined angle as the driving motor is driven. Therefore, whenever the moving module 430 is rotated by a predetermined angle, the adjacent lens 435 corresponds to the eye. As a result, as the moving module 430 is rotated by a predetermined angle by the driving module 420, the frequency lens 435 corresponding to the eye is replaced.

However, the driving module 420 may be formed in a structure capable of manually manipulating the moving module 430.

The driving module 420 may be automatically or manually driven as described above. 9 illustrates a driving module 420 that is automatically driven. Hereinafter, a case in which the driving module 420 is automatically driven will be described as an example.

The moving module 430 is rotatably installed as the driving module 420 is driven. The moving module 430 may include a plurality of ribs 431 extending radially from the rotation axis of the driving motor 422. In this case, one end lens 435 and the rest lens 437 may be coupled to the end of each rib 431. The plurality of power lenses 435 and the resting lens 437 may be arranged along the circumferential direction. These power lenses 435 are manufactured using optical technology.

In the fourth embodiment of the training apparatus for visual information processing function as described above, the moving module 430 is rotatably disposed, and the power lens 435 and the resting lens 437 are circularly disposed on the moving module 430. There is a difference from the third embodiment in that respect. This fourth embodiment is substantially the same as the training process of the third embodiment except that the moving module 430 rotates in the time information processing function training process. Therefore, a detailed description of the time information processing function training process according to the fourth embodiment will be omitted.

Since the present invention can improve and improve the time information processing function, there is a marked applicability in industry.

10: operation unit 40: display device
100: visual information processing function training device 110: fixed frame
119: transparent window 120: drive module
130: moving module 131: support frame
135: prism 137: relaxation lens

Claims (9)

A fixed frame worn on the face;
A drive module fixed to the fixed frame; And
A plurality of prisms or a plurality of frequency lenses are installed to be moved as the driving module is driven, and a movement module which allows the prism or frequency lenses corresponding to the eye to be replaced as the prisms or the frequency lenses are moved. Training aids. The method of claim 1,
The moving module is installed to the reciprocating drive module,
And a prism or a power lens arranged in a linear direction in the moving module. The method of claim 1,
The moving module is rotatably installed in the drive module,
Prism or frequency lenses are arranged in a circular motion information processing device training device. The method according to claim 2 or 3,
And one rest lens for each of the one or more prisms or one or more power lenses. The method of claim 1,
The fixed frame is:
First and second eye corresponding parts corresponding to both eyes; And
And a earring part extending from the first and second eye corresponding parts to hang on the ear. The method of claim 5, wherein
The first eye corresponding part is provided with a movement module and a driving module. The method of claim 5, wherein
When a plurality of prisms are installed in the moving module,
Training device for visual information processing function that the transparent window is installed in the second eye corresponding unit. The method of claim 5, wherein
When a plurality of frequency lenses are installed in the moving module,
And a blind window is installed in the second eye corresponding part. The method of claim 1,
The drive module is:
A motor unit for moving the moving module;
A signal providing unit for receiving a driving signal transmitted from an operation unit and driving the motor unit according to the received driving signal to replace a prism or a power lens corresponding to an eye; And
And a power supply unit supplying power to the motor unit and the signal providing unit.

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