JP2010088539A - Eyesight recovery training apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress the individual difference of effects in eyesight recovery training and to achieve the maximum effect, regarding an eyesight recovery training apparatus. <P>SOLUTION: The eyesight recovery training apparatus includes an image display means 2, and first and second optical means 3 and 4 disposed in the horizontal direction toward the display means 2. The first and second optical means 3 and 4 include eyepieces 3b and 4b provided on the side of a trainee, objective lenses 3c and 4c provided on the display side, and optical axis adjustment means 17 and 18 for adjusting the incidence angle of light to a training eye between the trainee and the eyepieces 3b and 4b. To the objective lenses, a moving means for moving the objective lenses 3c and 4b between the eyepieces 3b and 4b and the display means 2 is connected. The optical axis adjustment means 17 and 18 are provided with a driving means for driving the optical axis adjustment means 17 and 18. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a vision recovery training apparatus.

  The conventional vision recovery training apparatus has the following configuration.

That is, an eyepiece viewing hole is provided on one end side of the main body case, and a movable display portion is provided inside the main body case. An optical system is provided between the display unit and the trainee, and the display unit moves back and forth toward the trainee. Thereby, the convergence angle of the left eye and the right eye can be adjusted (for example, Patent Document 1 below).
JP 2007-097673 A

  The problem in the above-described conventional example is that the angle of convergence cannot be adjusted optimally according to the trainee, so that individual differences occur in the effect of the vision recovery training. That is, in this conventional example, the convergence angle between the left eye and the right eye is determined by conditions set in advance during the design of the device, such as the positional relationship between the eyepiece viewing hole and the display unit. For each trainer, for example, if the trainee has individual differences such as strabismus, training cannot be performed with the convergence angle optimized for that trainee, resulting in a training effect. There was a big difference.

  Therefore, the object of the present invention is to suppress individual differences in the effect in visual acuity recovery training and obtain the maximum effect.

  In order to achieve this object, the present invention comprises an image display means, and first and second optical means arranged in the horizontal direction toward the display means, and the first and second optical means. Has an eyepiece lens provided on the trainee side, an objective lens provided on the display side, and an optical axis adjusting means for adjusting an incident angle of light to the training eye between the trainee and the eyepiece lens, The objective lens is connected to a movable means for moving the objective lens between the eyepiece lens and the display means, and the optical axis adjusting means includes a driving means for driving the optical axis adjusting means, This achieves the intended purpose.

  As described above, the present invention includes the image display means and the first and second optical means arranged in the horizontal direction toward the display means. The first and second optical means are trainees. An eyepiece lens provided on the side, an objective lens provided on the display side, and an optical axis adjusting means for adjusting an incident angle of light to the training eye between the trainee and the eyepiece lens. Is connected to a movable means for moving the objective lens between the eyepiece lens and the display means, and the optical axis adjusting means includes a driving means for driving the optical axis adjusting means. Therefore, it is possible to suppress the individual difference in the effect in the vision recovery training and obtain the maximum effect.

  That is, in the present invention, the display unit is fixedly arranged, the objective lens is moved between the display unit and the eyepiece, and the incident angle of light to the training eye is adjusted between the trainee and the eyepiece. By appropriately adjusting the angle of the light incident on the training eye by the optical axis adjustment means, for example, the convergence angle can be adjusted to the optimum state according to the individual difference of the trainer, such as strabismus, thereby effectively displaying to the trainer It is possible to visually recognize a sense of distance that moves so that the display displayed on the means approaches or moves away.

  In other words, according to the present invention, the convergence angle can be adjusted optimally individually according to the trainee, so that the individual difference in the effect can be suppressed and the maximum effect can be obtained in the visual acuity recovery training.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

(Embodiment)
In FIG. 1, reference numeral 1 denotes a main body case. Inside the main body case 1, a display means 2 using liquid crystal is arranged as shown in FIG. As shown in FIG. 2, the display unit 2 is arranged on the inner side of the main body case 1.

  As shown in FIG. 2, first and second optical means 3 and 4 are arranged in the horizontal direction on the front side of the main body case 1. Each of the first and second optical means 3 and 4 has a configuration in which the eyepieces 3b and 4b and the objective lenses 3c and 4c are arranged in the lens barrels 3a and 4a in a state of being separated by a predetermined distance. .

  A configuration in which optical axis adjusting means 17 and 18 made of a reflector such as a mirror are disposed at a predetermined angle with respect to the eyepieces 3b and 4b on the front side of the eyepieces 3b and 4b. It has become. The optical axis adjusting means 17 and 18 will be described in detail later.

  Further, as is apparent from FIG. 2, the eyepieces 3b and 4b of the first and second optical means 3 and 4 are disposed outside the main body case 1, and the objective lenses 3c and 4c are disposed on the main body case 1. It is the composition arranged inside.

  In other words, the trainee presses his eyes against the front openings 3d and 4d of the lens barrels 3a and 4a protruding outside the main body case 1, and in this state, the optical axis adjusting means 17 and 18, the eyepieces 3b and 4b, and The display of the display means 2 is seen through the objective lenses 3c and 4c.

  At this time, a linear actuator 6 is connected to the objective lenses 3c and 4c arranged in the main body case 1 via the rod 5, and the objective lens 3c is driven by driving the linear actuator 6 with a motor 7. 4c moves within the lens barrels 3a and 4a between the eyepieces 3b and 4b and the display means 2.

  FIG. 3 is an electrical block diagram, and the control circuit 8 is supplied with power via an AC / DC power supply unit 9.

  The AC / DC power supply unit 9 and the AC power supply 10 are connected via a power switch 11.

  The control circuit 8 to which power is supplied starts control by the start switch 12 and drives the display means 2 via the drive circuit 13. At this time, the objective lenses 3 c and 4 c are also slid in conjunction with the image displayed on the display unit 2.

  Specifically, the image displayed on the display means 2 is also operated so that an object in the vicinity of the objective lenses 3c and 4c moves far, and this point will be described in detail next.

  4 and 5 show a state in which the image displayed on the display means 2 is visually in the vicinity of the trainee.

  As shown in FIG. 4, the objective lenses 3c and 4c are housed in holders 3e and 4e, respectively, and the holders 3e and 4e are provided with cylindrical rod-like protrusions 3f and 4f facing vertically downward.

  The first and second optical means 3 and 4 are provided with guide grooves 3g and 4g, and the rod-shaped protrusions 3f and 4f are slidably held.

  The guide grooves 3g and 4g are elongated holes or recesses having parallel side wall portions on which the cylindrical side surfaces of the rod-like protrusions 3f and 4f slide, and the focal position in the display portion of the display means 2 and the center of the eyepieces 3b and 4b. It is formed parallel to a straight line that forms an angle θ of the optical axis to be connected.

  The first and second optical means 3 and 4 are provided with holder holding portions 3h and 4h in parallel with the guide grooves 3g and 4g. The outer walls of the holders 3e and 4e on the holding portions 3h and 4h side are It has a shape along the holding portions 3h and 4h. The holders 3e and 4e are moved along the guide grooves 3g and 4g and the holder holding portions 3h and 4h, and the objective lenses 3c and 4c are also moved along the guide grooves 3g and 4g.

  As shown in FIG. 4, the trainee 14 presses the right eye 15 and the left eye 16 against the left and right openings 3d and 4d, and presses the start switch 12 in this state. Although not shown, shutters are provided on the side of the openings 3d and 4d of the eyepieces 3b and 4b of the left and right lens barrels 3a and 4a. By opening and closing the shutters, the right eye 15 and the left eye 16 are individually provided. However, the following explanation will explain the situation where both the right eye 15 and the left eye 16 are trained simultaneously (therefore, in the following explanation, The shutter is open for both eyes and is therefore not shown).

  Now, FIG. 5 shows a state in which the image displayed on the display means 2 is in the vicinity in the training of the right eye 15 and the left eye 16. In FIG. 5, a circle 2 a indicates the outermost periphery that can be seen by the trainee 14 (that is, a state similar to a state of viewing the scenery with binoculars with both eyes).

  In FIG. 5, a reference display 2b and a variable display 2c whose size is variable with respect to the reference display 2b are displayed in a circle 2a. Among these, the reference display 2b is provided to make the trainer 14 visually recognize whether the variable display 2c is in front or far away. As shown in FIG. 5, a perspective method is used. , A central square frame A and diagonal lines B connected to the four corners of the square frame A. Although not shown, the reference display 2b may be provided with black and white or colored shades that allow the trainer 14 to visually recognize light and dark from the vicinity of the square frame A toward the circle 2a. Thereby, it is possible to make the trainee 14 visually recognize the perspective.

  Here, in a state where the variable display 2c is in the vicinity, the variable display 2c is visually recognized by the trainee 14 as shown in FIG.

  Thus, in order to visually recognize that the variable display 2c is in the vicinity, as shown in FIG. 4, the objective lenses 3c and 4c are moved to the most eyepieces 3b and 4b side, and as shown in FIG. The display means 2 performs display in the size indicated as the variable display 2c.

  In this case, first, the circle 2a shown in FIG. 5 is incident on the objective lenses 3c and 4c because the objective lenses 3c and 4c moved to the front side are concave lenses as shown in FIG. As a result, there is an inclination (negative refraction) spreading outward, and the light (refracted light beam) resulting from this inclination then enters the right eye 15 and the left eye 16 via the eyepieces 3b and 4b. .

  Since the eyepieces 3b and 4b are convex lenses, the light from the objective lenses 3c and 4c is focused (positive refraction) so as to be focused on the right eye 15 and the left eye 16.

  If the angle of light entering the right eye 15 and the left eye 16 from the eyepieces 3b and 4b via the optical axis adjusting means 17 and 18 is wide, the variable display 2c visually recognizes that it is nearby, and conversely If the angle of light entering the right eye 15 and the left eye 16 from the eyepieces 3b and 4b via the optical axis adjusting means 17 and 18 is narrow, the variable display 2c is visually recognized as being far away.

  That is, if the light from the objective lenses 3c and 4c is incident on the outer periphery of the eyepieces 3b and 4b, the variable display 2c visually recognizes that it is close, and conversely, the objective lens is placed on the inner periphery of the eyepieces 3b and 4b. If the light from 3c and 4c is incident, the variable display 2c visually recognizes that it is far away.

  In FIG. 5, the state in which the variable display 2c is displayed largely up to the vicinity of the circle 2a is to visually recognize the trainee 14 as shown in FIG. 4, and at this time, the right eye 15, The trainee 14 who presses the left eye 16 visually recognizes that the variable display 2c exists in the virtual image position portion (not shown).

  On the other hand, FIG. 6 and FIG. 7 show a state where the image displayed on the display means 2 is visually far from the trainee.

  At this time, as shown in FIG. 7, the objective lenses 3c and 4c are moved in the lens barrels 3a and 4a from the eyepieces 3b and 4b to a position farthest away from the display means 2 side.

  At this time, as can be understood from FIG. 6, the variable display 2c is displayed in a small size. After the variable display 2c displayed in a small size is expanded by the objective lenses 3c and 4c, the eyepieces 3b and 4b are displayed. In FIG. 7, as the light of the eyepieces 3b and 4b, the part reaching the eyepieces 3b and 4b is far inward from the outer periphery of the eyepieces 3b and 4b. It will be incident.

  From this position, the angle of the light that is focused by the eyepieces 3b and 4b and reaches the right eye 15 and the left eye 16 via the optical axis adjusting means 17 and 18 is narrow. 7 is visually recognized as if the variable display 2c moved to a distance of 7, that is, the trainee 14 visually recognizes the state of FIG.

  As shown in FIG. 5, the training is performed by repeating the movement of the variable display 2c gradually from the state where the variable display 2c is in the vicinity to the state where the variable display 2c is located far away as shown in FIG. No. 14 is trained to view the image from near to far, thereby trying to perform vision recovery training.

  As one of the feature points in this embodiment, the eyepieces 3b and 4b are fixed, the objective lenses 3c and 4c are moved, and the sizes of the reference display 2b and the variable display 2c of the display unit 2 are appropriately adjusted. Thus, when the variable display 2c moves from the near side to the far side, it is possible to suppress a focus shift between the right eye 15 and the left eye 16 of the trainee 14.

  Here, the optical axis adjusting means for adjusting the incident angle of the light to the right eye 15 and the left eye 16 (training eye) of the trainee 14 which is the greatest feature of the present invention will be described in detail.

  FIG. 8 is a perspective view showing an optical axis adjusting means which is a main part of the visual acuity recovery training apparatus of the present invention. Reference numerals 17 and 18 denote optical axis adjusting means, in which the first and second mirrors 17a and 17b for the left eye and the first and second mirrors 18a and 18b for the right eye, which are reflectors, are arranged substantially parallel to each other. It has become.

  Then, as shown in FIG. 8, one end surface of the first and second mirrors 17a and 17b for the left eye and the first and second mirrors 18a and 18b for the right eye is rotationally driven such that a servo motor or the like can be positioned. The first and second mirrors 17a and 17b for the left eye and the first and second mirrors 18a and 18b for the right eye can be rotated independently of each other, fixed to the rotation shafts (not shown) of the means 19 and 20. Yes.

  The rotation driving means 19 and 20 are connected to the control circuit 8, and the drive amount of the rotation driving means 19 and 20 is controlled by a control signal from the control circuit 8, and the first and second mirrors 17 a and 17 b for the left eye and the right eye The angles of the first and second mirrors 18a and 18b can be appropriately adjusted in an independent state.

  Further, as shown in FIG. 2, the rotation driving means 19 and 20 are fixed to the first and second optical means 3 and 4 so that the rotation axes thereof are directed vertically upward, and the left eye first and second The mirrors 17a and 17b and the first and second mirrors 18a and 18b for the right eye have one end face fixed to the rotation shafts of the rotation driving means 19 and 20, and can be rotated in a horizontal direction while positioning control is possible. It has become.

  Next, the operation of the optical axis adjusting means 17 and 18 will be described with reference to FIGS. As described above, FIG. 4 shows a state in which the image displayed on the display means 2 is visually in the vicinity of the trainee.

  As shown in FIG. 4, the first and second mirrors 17a and 17b for the left eye and the first and second mirrors 18a and 18b for the right eye, which are optical axis adjusting means, are provided for the first and second optical means 3 and 4, respectively. It is rotated by the rotation drive means 19 and 20 toward the outer peripheral side in the horizontal direction, and positioning control is appropriately performed at a desired angle.

  And when set in this way, the light from the display part of the display means 2 passes through the objective lenses 3c and 4c and the eyepieces 3b and 4b, and is first caused by the first left eye mirror 17a and the first right eye mirror 18a. Then, the light is reflected by the second mirror 17b for the left eye and the second mirror 18b for the right eye.

  The reflected light is incident on the left eye 14 and the right eye 15 of the trainee 14 at an angle Φ1 formed by the optical axis. That is, the convergence angle is set to be Φ1 as shown in FIG. 4 at the near point.

  On the other hand, FIG. 7 shows a state in which the image displayed on the display means 2 is visually far from the trainee.

  As shown in FIG. 7, the first and second mirrors 17a and 17b for the left eye and the first and second mirrors 18a and 18b for the right eye, which are optical axis adjusting means, are provided for the first and second optical means 3 and 4, respectively. It is rotated by the rotation driving means 19 and 20 toward the inner peripheral side in the horizontal direction, and positioning control is appropriately performed at a desired angle.

  In this case, the light reflected by the second mirror 17b for the left eye and the second mirror 18b for the right eye is, as shown in FIG. 7, the left eye of the trainee 14 at an angle Φ2 formed by the optical axis. 14 enters the right eye 15. That is, the convergence angle is set to be Φ2 as shown in FIG. 7 at the far point.

  Therefore, the convergence angle is Φ1 as shown in FIG. 4 at the near point and Φ2 as shown in FIG. 7 at the far point, and the convergence angle can be adjusted to a desired angle as appropriate. As a result, it is possible to cause the trainee 14 to visually recognize a sense of distance that moves so that the display displayed on the display unit 2 moves away from the vicinity.

  The greatest feature of the present invention is that the convergence angle can be appropriately adjusted to a desired angle by the optical axis adjusting means 17 and 18 as described above.

  That is, when there are individual differences among trainers, such as strabismus, first, the degree of strabismus is measured for each individual trainee, and the data is collected. Then, based on the collected data, according to the individual difference of each trainer, the convergence angle Φ1 at the near point and the convergence angle Φ2 at the far point are set to be optimal for each trainer, and the information Is input to the control circuit 8 shown in FIG. Then, as shown in FIG. 3, based on the information input to the control circuit 8, the control circuit 8 causes the left eye first and second mirror driving means 19a and 19b and the right eye first and second mirror driving means 20a. , 20b are driven independently. The left eye first and second mirror driving means 19a and 19b and the right eye first and second mirror driving means 20a and 20b allow the left eye to continuously change the convergence angle from Φ1 to Φ2 in the vision recovery training. This means that the first and second mirrors 17a and 17b and the first and second mirrors 18a and 18b for the right eye can be positioned and rotated.

  Accordingly, it is possible to visually recognize a sense of distance that moves so that the display displayed on the display unit 2 is approaching or moving away effectively for each trainer.

  That is, in the present invention, the convergence angle can be adjusted optimally individually according to the trainee, so that individual differences in effects can be suppressed and the maximum effect can be obtained in the visual acuity recovery training.

  Further, in the present invention, the display means 2 can be moved from near to far from the trainee 14 and at the same time, it is not necessary to move the display means 2 inward and outward in the horizontal direction. Can be achieved. Furthermore, since the display means 2 comprised by an electrical component etc. can be fixed, there exists an effect that the reliability of an apparatus improves.

  In the present embodiment, the first and second mirrors 17a and 17b for the left eye and the first and second mirrors 18a and 18b for the right eye have been described as the optical axis adjusting units 17 and 18. It is not limited. Using a prism having a reflecting surface facing substantially parallel as a reflector, the light enters from the display means 2 in the same manner as the first and second mirrors 17a and 17b for the left eye and the first and second mirrors 18a and 18b for the right eye. It goes without saying that the same effect as in the present embodiment can be obtained by reflecting the light to be incident and making the light enter the training eye.

  Further, the first and second mirrors 17a and 17b for the left eye, and the first and second mirrors 18a and 18b for the right eye, as shown in FIG. 19b) and 20 (20a and 20b) are described as being driven, but the present invention is not limited to this. For example, the first and second mirrors 17a and 17b for the left eye and the first and second mirrors for the right eye on the end surface opposite to the end surface fixed to the rotation driving means 19 (19a, 19b) and 20 (20a, 20b). The first and second mirrors 17a for the left eye are provided by providing a link mechanism in which 18a and 18b are substantially parallel to each other so that the angle of one mirror is rotated in conjunction with the angle of the other mirror. 17b and the first and second mirrors 18a and 18b for the right eye need only be provided with one rotation driving means, respectively, and the configuration can be simplified and the apparatus can be miniaturized.

  Moreover, although the example which the holders 3e and 4e move along the holder holding parts 3h and 4h was demonstrated, it is not limited to this. The rod-like protrusions 3f and 4f are formed in a substantially rectangular shape extending in the longitudinal direction of the guide grooves 3g and 4g so that the holders 3e and 4e are held and moved only by the guide grooves 3g and 4g. A similar cylindrical rod-shaped protrusion may be provided on the other end side where the rod-shaped protrusions 3f and 4f of the holders 3e and 4e are provided.

  The first and second optical means 3 and 4 are further provided with guide grooves parallel to the guide grooves 3g and 4g, respectively, so that cylindrical holders 3e and 4e can be moved from the holders 3e and 4e. By inserting, the holders 3e and 4e may be guided and moved.

  Further, the objective lenses 3c and 4c and the holders 3e and 4e may be integrally formed. In this case, the displacement due to the combination of the objective lenses 3c and 4c and the holders 3e and 4e is eliminated, and processing of individual members is performed. Since accumulation of variation can be reduced, the positional accuracy of the objective lenses 3c and 4c in the first and second optical means 3 and 4 can be increased, and further, the performance of the vision training recovery device can be improved. At the same time, the configuration can be simplified.

  In the present embodiment, as shown in FIG. 5, in this training, the variable display 2c gradually moves from a state where the variable display 2c is in the vicinity to a state where the variable display 2c is located far away as shown in FIG. However, the present invention is not limited to this. However, the present invention is not limited to this.

  As shown in FIG. 6, the variable display 2c is gradually moved from the state where the variable display 2c is in the vicinity to the state shown in FIG. It is also possible to perform training to see an image up to a distance, and thereby try to perform vision recovery training. In this case, vision recovery training can be performed for hyperopia and presbyopia.

  As described above, the present invention includes the image display means and the first and second optical means arranged in the horizontal direction toward the display means. The first and second optical means are trainees. An eyepiece lens provided on the side, an objective lens provided on the display side, and an optical axis adjusting means for adjusting an incident angle of light to the training eye between the trainee and the eyepiece lens. Is connected to a movable means for moving the objective lens between the eyepiece lens and the display means, and the optical axis adjusting means includes a driving means for driving the optical axis adjusting means. Therefore, it is possible to suppress the individual difference in the effect in the vision recovery training and obtain the maximum effect.

  That is, in the present invention, the display unit is fixedly arranged, the objective lens is moved between the display unit and the eyepiece, and the incident angle of light to the training eye is adjusted between the trainee and the eyepiece. By appropriately adjusting the angle of the light incident on the training eye by the optical axis adjustment means, for example, the convergence angle can be adjusted to the optimum state according to the individual difference of the trainer, such as strabismus, thereby effectively displaying to the trainer It is possible to visually recognize a sense of distance that moves so that the display displayed on the means approaches or moves away.

  That is, in the present invention, the convergence angle can be adjusted optimally individually according to the trainee, so that individual differences in effects can be suppressed and the maximum effect can be obtained in the visual acuity recovery training.

  For this reason, since the maximum effect of visual acuity training can be expected regardless of individual differences among trainers, it is expected to be widely used as a visual acuity recovery training apparatus for home use.

The perspective view which shows one Embodiment of this invention Partial cutaway perspective view Its electric circuit block diagram Sectional view showing the display means and optical means Front view of the display means Front view of the display means Sectional view showing the display means and optical means The perspective view which shows the optical axis adjustment means which is the principal part

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Main body case 2 Display means 3 1st optical means 3a, 4a Lens barrel 3b, 4b Eyepiece 3c, 4c Objective lens 3d, 4d Aperture 3e, 4e Holder 3f, 4f Rod-shaped protrusion 3g, 4g Guide groove 4 2nd optical Means 5 Rod 6 Linear actuator 7 Motor 8 Control circuit 9 AC / DC power supply unit 10 AC power supply 11 Power switch 12 Start switch 13 Drive circuit 14 Trainer 15 Right eye 16 Left eye 17, 18 Optical axis adjustment means 17a First mirror for left eye 17b Second mirror for left eye 18a First mirror for right eye 18b Second mirror for right eye 19, 20 Rotation drive means 19a First mirror drive means for left eye 19b Second mirror drive means for left eye 20a First mirror drive means for right eye 20b For right eye Second mirror driving means

Claims (8)

  An image display means, and first and second optical means arranged in a horizontal direction toward the display means, wherein the first and second optical means include an eyepiece provided on the trainee side; An objective lens provided on the display side; and an optical axis adjusting unit that adjusts an incident angle of light to the training eye between the trainee and the eyepiece lens. The objective lens is connected to the eyepiece. A visual acuity recovery training apparatus in which a movable means for moving between a lens and the display means is connected, and the optical axis adjusting means includes a driving means for driving the optical axis adjusting means.   The visual acuity recovery training apparatus according to claim 1, wherein the optical axis adjustment unit is a reflector that can rotate in a horizontal direction independently of the left and right training eyes.   The visual acuity recovery training apparatus according to claim 2, wherein the reflector is a mirror facing substantially parallel.   The visual acuity recovery training apparatus according to claim 2, wherein the reflector is a prism having a reflecting surface facing substantially parallel.   The visual acuity recovery training device according to any one of claims 1 to 4, wherein a diopter of image information directed to the trainee is changed according to a distance between the objective lens and the eyepiece through the eyepiece. .   6. The visual acuity recovery training apparatus according to claim 5, wherein the objective lens is moved between the eyepiece lens and the display unit, and the display unit is configured to change a size of an image to be displayed.   The visual acuity recovery training apparatus according to any one of claims 1 to 6, wherein the display means is configured to display a reference display and a variable display whose size is variable with respect to the reference display. The visual acuity recovery training apparatus according to any one of claims 1 to 7, wherein the first and second optical means are arranged toward one of the display means.

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