KR20240028745A - Inspection device of the opticla device and inspection method of the opticla device - Google Patents

Abstract

An inspection device for a light guide according to an embodiment includes a light source member that emits light; A view angle control member, a reflection member, and a light guide arranged sequentially based on the light path; a first measuring member that measures characteristics of light emitted from the light guide; a second measuring member that measures characteristics of incident light incident on the light guide; and a third measuring member that measures characteristics of lost light lost in the light guide, wherein the angle of view control member controls the angle of view of light by movement and rotation of the first control member and the second control member, and the reflection member reflects the light incident from the angle of view control member to the light guide.

Description

Inspection device and inspection method of optical guide {INSPECTION DEVICE OF THE OPTICLA DEVICE AND INSPECTION METHOD OF THE OPTICLA DEVICE}

The embodiment relates to a device for inspecting the performance of a light guide and a method for inspecting the light guide.

In detail, the embodiment relates to a device for inspecting the performance of a waveguide and a method for inspecting the waveguide.

With recent advancements in technology, various types of wearable devices that can be worn on the body are coming out. Among them, Augmented Reality (AR) devices are wearable devices in the form of glasses worn on the user's head, and can provide augmented reality services to users by providing visual information through a display.

Augmented reality refers to mixing real world information and virtual images by inserting 3D images into the real environment.

Real-world information includes information that the wearer does not need, and sometimes may lack information that the wearer needs. However, the augmented reality system combines the real world and the virtual world, allowing the wearer to interact with the real world and necessary information in real time.

These augmented reality (AR) devices allow you to see ahead while in use, unlike virtual reality (VR) devices that have an obstructed view. In addition, while wearing it like regular glasses, you can display a wide-screen display in front of your eyes or use various AR contents. In addition, it is possible to support an extended reality experience that combines reality and AR content by utilizing all 360-degree spaces in a user-centered manner. In addition, it is developing as a technology to replace smartphones in that it provides a display optimized for the user's perspective while keeping both hands free.

The augmented reality device includes an optical module to provide augmented reality images to wearers. For example, the augmented reality device may be composed of wearable glasses that are light guides, and a projector that projects images may be coupled to the wearable glasses.

The light emitted from such a projector passes through the light guide and enters the user's eyes, thereby allowing the user to view the augmented reality display.

Meanwhile, the light emitted from the projector may be diffracted in the light guide and then enter the user's eyes. For example, the light guide may include at least one light guide. Alternatively, the light guide may further include a cover glass disposed on the light guide.

The light emitted from the projector is diffracted through a first diffraction pattern, enters the light guide, is totally reflected and moves inside, and is then diffracted and emitted through a second diffraction pattern.

Accordingly, if the performance of the light guide, that is, the intensity and distribution of light, etc., can be measured in each area of the light guide, defects can be minimized before applying the light guide to a wearable device.

Meanwhile, a light guide including such a diffraction pattern is disclosed in Korean Patent Publication KR10-2017-0039655 (April 11, 2017).

The embodiment is intended to provide a light guide inspection device and inspection method that can measure the performance of the light guide before applying the light guide to a wearable device.

An inspection device for a light guide according to an embodiment includes a light source member that emits light; A view angle control member, a reflection member, and a light guide arranged sequentially based on the light path; a first measuring member that measures characteristics of light emitted from the light guide; a second measuring member that measures characteristics of incident light incident on the light guide; and a third measuring member that measures characteristics of lost light lost in the light guide, wherein the angle of view control member controls the angle of view of light by movement and rotation of the first control member and the second control member, and the reflection member reflects the light incident from the angle of view control member to the light guide.

A method for inspecting a light guide according to an embodiment includes the steps of emitting light from a light source member; incident of the light onto a view angle control member; reflecting the light from a reflective member; The light is incident on the light guide; Measuring characteristics of incident light incident on the light guide; The light is emitted from the light guide; and measuring characteristics of emitted light and lost light emitted from the light guide.

The light guide inspection device and inspection method according to the embodiment can inspect the performance of the light guide before applying the light guide to the wearable device.

In detail, the light guide includes a light guide that diffracts light.

The light guide inspection device and inspection method can measure the characteristics of the incident light incident on the light guide, the characteristics of the emitted light emitted from the light guide, and the characteristics of the lost light lost from the light guide.

Accordingly, the characteristics of the light guide can be measured before applying the light guide to a wearable device. Accordingly, if there is a problem with the characteristics of the light guide, the configuration of the light guide can be corrected.

For example, if there is a problem with the light emitted or lost from the light guide, the characteristics of the light guide can be changed by correcting the refractive index of the light guide, the shape and size of the diffraction pattern, etc.

Alternatively, a defective light guide can be discarded before being applied to a wearable device.

Accordingly, a light guide whose performance is secured by the light guide inspection device and inspection method according to the embodiment can be applied to a wearable device. Accordingly, the reliability and driving characteristics of the wearable device can be improved.

Figure 1 is a diagram showing a performance inspection device for a light guide according to an embodiment.
Figure 2 is a diagram for explaining the movement and rotation of the angle of view control member in the light guide performance inspection device according to the embodiment.
Figure 3 is a flowchart of a method for testing the performance of a light guide according to an embodiment.
Figure 4 is a diagram showing a wearable device to which a light guide is applied according to an embodiment.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. However, the technical idea of the present invention is not limited to some of the described embodiments, but may be implemented in various different forms, and as long as it is within the scope of the technical idea of the present invention, one or more of the components may be optionally used between the embodiments. It can be used by combining and replacing.

In addition, terms (including technical and scientific terms) used in the embodiments of the present invention, unless explicitly specifically defined and described, are generally understood by those skilled in the art to which the present invention pertains. It can be interpreted as meaning, and the meaning of commonly used terms, such as terms defined in a dictionary, can be interpreted by considering the contextual meaning of the related technology.

Additionally, the terms used in the embodiments of the present invention are for describing the embodiments and are not intended to limit the present invention. In this specification, the singular may also include the plural unless specifically stated in the phrase, and when described as “at least one (or more than one) of A, B, and C,” it can be combined with A, B, and C. It can contain one or more of all possible combinations.

Additionally, when describing the components of an embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and are not limited to the essence, sequence, or order of the component.

And, when a component is described as being 'connected', 'coupled' or 'connected' to another component, the component is not only directly connected, coupled or connected to that other component, but also is connected to that component. It may also include cases where other components are 'connected', 'coupled', or 'connected' by another component between them.

Additionally, when described as being formed or disposed "above" or "below" each component, "above" or "below" refers not only to cases where two components are in direct contact with each other, but also to one This also includes cases where another component described above is formed or placed between two components.

Additionally, when expressed as “top (above) or bottom (bottom),” it can include the meaning of not only the upward direction but also the downward direction based on one component.

The light guide 1000 described below may include a waveguide.

The light guide 1000 includes a substrate 1100 and a diffraction pattern 1200. The substrate 1100 may include glass. In detail, the substrate 1100 may include glass having a refractive index in a set range. For example, the substrate 1100 may include glass having a refractive index of 1.7 to 2.0.

The substrate 100 may include one side and another side opposite to the one side. The diffraction pattern 1200 is disposed on one surface of the substrate 1100. In detail, a first diffraction pattern 1210 and a second diffraction pattern 1220 are disposed on one surface of the substrate 1100. The first diffraction pattern 1210 and the second diffraction pattern 1220 are arranged to be spaced apart from each other on the same surface of the substrate 1100.

Below, the X-axis, Y-axis, and Z-axis are defined. The Y-axis is defined as the optical axis direction, and the X-axis and Z-axis are each defined as directions perpendicular to the optical axis direction. In detail, the Y-axis is defined as the optical axis of light emitted from the view angle adjustment member described below, and the X-axis and the Z-axis are each defined as directions perpendicular to the optical axis direction.

Figure 1 is a diagram showing a performance inspection device for a light guide according to an embodiment.

Referring to Figure 1, the light guide performance inspection device includes a light source member 100, an optical member 200, an angle of view control member 300, a reflective member 400, a measuring member 510, 520, 530, and a mask. Includes (600).

The light source member 100, the optical member 200, the angle of view control member 300, and the reflective member 400 are sequentially arranged. In detail, the light source member 100, the optical member 200, the angle of view control member 300, and the reflective member 400 are sequentially arranged based on the path of light.

The light source member 100 generates light. The light generated from the light source member 100 moves in the direction of the light guide 1000. In detail, the light is incident on the light guide 1000 through the optical member 200, the view angle control member 300, and the reflective member 400.

The light source member 100 may emit red light, green light, or blue light.

The light source member 100 may emit light of different wavelengths depending on the diffraction pattern of the light guide 1000. For example, when the light guide 1000 includes a diffraction pattern that reacts with red light, the light source member 100 emits red light. Alternatively, when the light guide 1000 includes a diffraction pattern that reacts with blue light, the light source member 100 emits blue light. When the light guide 1000 includes a diffraction pattern that reacts with green light, the light source member 100 emits green light. That is, the light source member 100 emits light of different wavelengths or colors depending on the light guide including the diffraction pattern to be measured.

The light source member 100 may include a laser package or a light emitting diode package.

Light emitted from the light source member 100 may be incident on the optical member 200. The optical member 200 can control the characteristics of light emitted from the light source member 100. The optical member 200 may include a collimator, a condensing lens, a prism, or a mirror. Accordingly, the angle and path of light emitted from the light source member 100 may change through the optical member 200.

Light passing through the optical member 200 may be incident on the angle of view control member 300. The angle of view control member 300 may include a first control member 310 and a second control member 320. The first control member 310 and the second control member 320 are disposed adjacent to each other and spaced apart from each other. Additionally, the first control member 310 and the second control member 320 may be arranged to face each other.

The first control member 310 and the second control member 320 may reflect the light. In detail, light moving in the direction of the angle of view control member 300 may be reflected by the first control member 310 and the second control member 320. That is, light moving in the direction of the angle of view control member 300 is reflected by the first control member 310 and the second control member 320 and moves in the direction of the light guide 1000.

The angle of view control member 300 controls the angle of view of light moving in the direction of the light guide 1000. In detail, the angle of view control member 300 controls the angle of view of the light in the range of 20° to 60°.

The angle of view control member 300 can control the angle of view of the light to an angle within a set range by moving and rotating the first control member 310 and the second control member 320.

Referring to FIG. 2, the first control member 310 and the second control member 320 may move and/or rotate in a set direction.

Referring to (a) of FIG. 2, at least one control member of the first control member 310 and the second control member 320 may move in one direction. In detail, the first control member 310 and the second control member 320 can move in the Z-axis direction. That is, the first control member 310 and the second control member 320 can move up and down in the Z-axis direction.

Referring to (b) of FIG. 2, the second control member 320 can move in the Y-axis direction. That is, the second control member 320 can move in the optical axis direction. Here, the optical axis direction may be defined as the optical axis direction of light moving from the angle of view control member 300 to the reflective member 400.

Accordingly, the first control member 310 moves only in the Y-axis direction. That is, the first control member 310 moves in only one direction. Additionally, the second control member 320 moves in the Y-axis direction and the Z-axis direction. That is, the second control member 320 moves in multiple directions.

Referring to (c) of FIG. 2, the second control member 320 can rotate. The second control member 320 may rotate using the Y axis as a rotation axis. Additionally, the second control member 320 may rotate using the Z axis as a rotation axis. That is, the second control member 320 rotates using the Y-axis and the Z-axis as rotation axes. That is, the second control member 320 rotates in multiple directions.

Accordingly, the first control member 310 moves in one direction. Additionally, the second control member 320 moves in multiple directions and rotates in multiple directions. Accordingly, the angle of view control member 300 can control the angle of view of light moving to the light guide 1000 within a set range.

The position of the angle of view control member 300 and the angle of the second control member 320 with respect to the Y axis determine the x component of the angle of view, and the position of the second control member 320 and the angle with respect to the Z axis The angle determines the y component of the angle of view. Accordingly, the angle of view ranges of the x and y components of the light can be controlled by moving and rotating the first control member 310 and the second control member 320.

Light whose angle of view is controlled by the angle of view control member 300 is incident on the reflection member 400. Light incident on the reflective member 400 is reflected in the direction of the light guide 1000.

The reflective member 400 may include various members capable of reflecting light. For example, the reflective member 400 may include a mirror or prism.

The reflective member 400 may be disposed inclined at an angle θ within a set range. In detail, the reflective member 400 may be inclined at an angle θ within a set range with respect to an imaginary line VL in a direction perpendicular to the optical axis OA.

In detail, the reflective member 400 may be disposed inclined at an angle θ of 40° to 50°. The angle θ of the reflective member 400 is an angle set to prevent interference with the size of the reflective member 400 and the light guide 1000.

If the angle θ of the reflective member 400 is less than 40°, the size of the reflective member 400 may increase to reflect the light, and the reflection angle of light may increase, thereby reducing the quality of light. Additionally, if the angle θ of the reflective member 400 exceeds 50°, the path of the light and the position of the light guide 1000 may interfere.

The light reflected from the reflective member 400 is incident on the light guide 1000. In detail, the light reflected from the reflection member 400 passes through the first diffraction pattern 1210, is diffracted, is incident on the inside of the substrate 1100, and is totally reflected inside the substrate 1100, 2 It passes through the diffraction pattern 1220 and is emitted to the outside of the substrate 1100.

A measuring member may be placed around the light guide 1000. In detail, a plurality of measuring members may be disposed around the light guide 1000. The measuring member includes a first measuring member 510, a second measuring member 520, and a third measuring member 530.

The first measurement member 510, the second measurement member 520, and the third measurement member 530 may each measure different characteristics of light.

The first measurement member 510 may measure characteristics of the emitted light that passes through the second diffraction pattern 1220 from the substrate 1100.

Additionally, the second measuring member 520 can measure characteristics of incident light reflected from the reflective member 400 toward the light guide 1000.

In addition, the third measuring member 530 does not pass through the second diffraction pattern 1220 on the substrate 1100, but radiates from a side opposite to the side of the substrate on which the second diffraction pattern 1220 is disposed. The characteristics of lost light can be measured.

Accordingly, the first measuring member 510 measures main characteristics of the light guide 1000. That is, the first measuring member 510 measures the characteristics of the emitted light transmitted to the user through the light guide 1000.

A mask 600 may be disposed between the first measuring member 510 and the light guide 1000 based on the path of the light. An area through which light is transmitted to the user may be defined by the mask 600. Therefore, the characteristics of the emitted light visible to the user can be measured through the light moving through the mask 600.

The first measurement member 510 can measure the intensity and distribution of light emitted through the second diffraction pattern 1220. In detail, the first measurement member 510 can measure the power or energy of emitted light, or measure the distribution and angle of the light. Accordingly, it can be determined whether the conditions for the emitted light delivered to the user through the first measurement member 510 are satisfied.

Additionally, the second measuring member 520 can measure characteristics of incident light incident on the light guide 1000. In detail, the second measurement member 520 can measure characteristics of incident light incident on the first diffraction pattern 1210. To this end, before light is incident on the light guide, the light guide 1000 can be placed in a position different from the light path, and the characteristics of the incident light can be measured through the second measuring member 520. Subsequently, when the measurement of incident light is completed, the light guide 1000 can be moved back to the position of the light path.

In detail, the second measuring member 520 can measure the power or energy of incident light, or measure the distribution and angle of the light. Accordingly, it can be determined whether the conditions for incident light transmitted to the light guide through the second measuring member 520 are satisfied.

Additionally, the third measuring member 530 measures characteristics of loss light emitted from the light guide 1000 in a direction opposite to the second diffraction pattern 1220. That is, the third measuring member 530 can measure the intensity and distribution of lost light that is not emitted from the light guide 1000 toward the user.

In detail, the third measurement member 530 can measure the power or energy of the lost light, or measure the distribution and angle of the light. Accordingly, it can be determined whether the condition of lost light not being transmitted to the user through the third measurement member 530 is satisfied.

Figure 3 is a flow chart showing a method for inspecting a light guide using the inspection device described above.

Referring to FIG. 3, the method for testing the performance of a light guide according to an embodiment includes steps of emitting light from a light source member (ST10), entering the light into a view angle control member (ST20), and reflecting the light from a reflection member. a step (ST30), a step of entering the light into the light guide (ST40), a step of measuring the characteristics of the incident light (ST50), a step of emitting the light from the light guide (ST60), and measuring the characteristics of the emitted light and the lost light. It may include a measuring step (ST70).

In the step of emitting light from the light source member (ST10), light is generated from the light source member and light is emitted. The light source member generates at least one of red light, green light, and blue light, and at least one of the red light, green light, and blue light is emitted.

In detail, if the light guide includes a diffraction pattern responsive to the wavelength of the blue light, blue light is emitted from the light source member, and if the light guide includes a diffraction pattern responsive to the wavelength of the green light, green light is emitted from the light source member. And, if the light guide includes a diffraction pattern that responds to the wavelength of the red light, red light may be emitted from the light source member.

That is, the wavelength of light emitted from the light source member 100 may vary depending on the diffraction pattern included in the light guide.

Next, in the step (ST20) where the light is incident on the angle of view control member, the angle of view of the light is controlled. In detail, the range of the angle of view of light incident on the light guide can be controlled.

The angle of view control member includes a first control member and a second control member. The first control member and the second control member may control the angle of view of light emitted from the light source member within a set range. In detail, the light emitted from the light source member can be controlled to have a viewing angle of 20° to 60°.

In detail, the first control member and the second control member are spaced apart from each other and are disposed to face each other. The first control member moves in the Z-axis direction. Additionally, the second control member moves in the Z-axis direction and the Y-axis direction. Additionally, the second control member rotates using the Y-axis and Z-axis as rotation axes.

That is, the first control member moves in one direction, and the second control member moves in multiple directions and rotates in multiple directions.

The position of the angle of view control member and the angle of the second control member with respect to the Y axis determine the x component of the angle of view, and the position of the second control member and the angle with respect to the Z axis determine the y component of the angle of view. do. Accordingly, the angle of view ranges of the x component and y component of the light can be controlled by movement and rotation of the first control member and the second control member.

Light controlled to a set angle of view range moves toward the reflective member.

Next, in the step (ST30) in which the light is reflected by the reflective member, light with a controlled angle of view is incident on the reflective member and reflected, and the reflected light moves in the direction of the light guide.

The reflective member may be tilted at a set angle. In detail, depending on the range of the angle of view set by the angle of view control member, the reflective member may be disposed to be inclined at a set angle.

For example, the reflective member may be inclined at an angle within a set range with respect to an imaginary line perpendicular to the optical axis of the light incident on the reflective member.

In detail, the reflective member may be disposed inclined at an angle of 40° to 50°. Since the reflective member is inclined at an angle within a set range, the size of the reflective member can be reduced and interference between light and the light guide can be prevented.

In detail, if the angle of the reflective member is less than 40°, the size of the reflective member may increase to reflect the light, and the reflection angle of light may increase, thereby reducing the quality of light. Additionally, if the angle of the reflective member exceeds 50°, the path of the light and the position of the light guide may interfere.

Light reflected from the reflective member moves in the direction of the light guide.

In the step (ST40) where the light is incident on the light guide, the light reflected from the reflective member is incident on the light guide.

The light guide includes a first diffraction pattern disposed in an incident area and a second diffraction pattern disposed in an exit area. Light reflected from the reflective member moves toward the incident area of the light guide.

Next, in the step of measuring the characteristics of the incident light (ST50), the characteristics of the incident light incident on the light guide are measured. In detail, the characteristics of the incident light incident on the light guide are measured using a measuring member.

In order to measure the characteristics of the incident light incident on the light guide, the light guide is moved to a position that does not overlap the light path, and then the characteristics of the incident light are measured. In detail, the intensity, distribution, and angle of incident light can be measured using the measuring member.

After measuring the incident light, the light guide is rearranged to overlap the light path, and the incident light is diffracted through the first diffraction pattern and enters the inside of the substrate.

Subsequently, in the step of emitting the light from the light guide (ST60), the light may be emitted outside the light guide. In detail, light that is totally reflected inside the substrate may be emitted to the outside of the light guide.

The light may be emitted in an emission area of the light guide and in a direction opposite to the emission area. In detail, the light emitted from the light emitting area of the light guide is light that delivers image information to the user. That is, in the emission area of the light guide, the emitted light that has passed through the second diffraction pattern can be delivered to the user. Additionally, lost light emitted in a direction opposite to the emission area of the light guide is light that is lost without being transmitted to the user.

Next, in the step of measuring the characteristics of the emitted light and the lost light (ST70), the characteristics of the emitted light emitted from the emitting area of the light guide and the lost light emitted in the bar direction of the emitted light area of the light guide can be measured.

In detail, the characteristics of the emitted light and lost light are measured using a measuring member. The intensity, distribution, and angle of the emitted light and the lost light can be measured using the measuring member.

The light guide inspection device and inspection method according to the embodiment can inspect the performance of the light guide before applying the light guide to the wearable device.

In detail, the light guide includes a waveguide. That is, the light guide includes a waveguide that diffracts light.

The light guide inspection device and inspection method can measure the characteristics of the incident light incident on the light guide, the characteristics of the emitted light emitted from the light guide, and the characteristics of the lost light lost from the light guide.

Accordingly, the characteristics of the light guide can be measured before applying the light guide to a wearable device. Accordingly, if there is a problem with the characteristics of the light guide, the configuration of the light guide can be corrected.

For example, if there is a problem with the light emitted or lost from the light guide, the characteristics of the light guide can be changed by correcting the refractive index of the light guide, the shape and size of the diffraction pattern, etc.

Alternatively, a defective light guide can be discarded before being applied to a wearable device.

Accordingly, a light guide whose performance has been confirmed by the light guide inspection device and inspection method according to the embodiment can be applied to a wearable device. Accordingly, the reliability and driving characteristics of the wearable device can be improved.

Hereinafter, with reference to FIG. 4. An example of a display device including a light guide inspected by the inspection device and inspection method according to the embodiment will be described.

Referring to FIG. 4, the light guide according to the embodiment can be applied to a wearable display device. In detail, the light guide according to the embodiment can be applied to a wearable display device worn on the human head or the human ear.

For example, the display device 2000 may be an augmented reality device.

The display device 2000 includes a wearable unit 2100 and a display unit 2300.

The wearing portion 2100 may extend in one direction. The wearing unit 2100 can be worn on the user's body. For example, the wearing unit 2100 is worn on the user's head or ear, and thereby the display device 2000 can be fixed to the user's body. For example, the wearing unit 2100 may be a glasses tail in the wearable display device.

A projector 2200 is disposed on the wearing unit 2100. The projector 2200 emits light in the direction of the display unit 2300. In detail, the projector (@200) emits light containing image information in the direction of the display unit (2300).

The display unit 2300 may be the light guide described above. Alternatively, the display unit 2300 may be AR glass including the light guide.

As a result, the user can receive light containing image information emitted from the projector 2200 through the display unit @300. Accordingly, the user can view virtual reality and augmented reality of real reality through the light guide.

The features, structures, effects, etc. described in the above-described embodiments are included in at least one embodiment of the present invention and are not necessarily limited to only one embodiment. Furthermore, the features, structures, effects, etc. illustrated in each embodiment can be combined or modified and implemented in other embodiments by a person with ordinary knowledge in the field to which the embodiments belong. Therefore, contents related to such combinations and modifications should be construed as being included in the scope of the present invention.

In addition, although the above description focuses on the embodiments, this is only an example and does not limit the present invention, and those skilled in the art will understand the above examples without departing from the essential characteristics of the present embodiments. You will be able to see that various modifications and applications are possible. For example, each component specifically shown in the embodiments can be modified and implemented. And these variations and differences in application should be construed as being included in the scope of the present invention as defined in the appended claims.

Claims (10)

A light source member emitting light;
A view angle control member, a reflection member, and a light guide arranged sequentially based on the light path;
a first measuring member that measures characteristics of light emitted from the light guide;
a second measuring member that measures characteristics of incident light incident on the light guide; and
It includes a third measuring member that measures characteristics of lost light lost from the light guide,
The angle of view control member controls the angle of view of light by movement and rotation of the first control member and the second control member,
An inspection device for a light guide wherein the reflection member reflects light incident from the angle of view control member to the light guide. According to clause 1,
The optical axis of the light incident from the angle of view control member to the reflective member is defined as the Y axis,
X and Z axes perpendicular to the Y axis are defined,
An inspection device for a light guide wherein the reflective member is inclined at an angle of 40° to 50° with respect to an imaginary line perpendicular to the Y axis. According to clause 2,
The first control member moves in one direction,
The second control member moves in multiple directions,
An inspection device for a light guide in which the second control member rotates in multiple directions. According to clause 3,
The first control member moves in the Z-axis direction,
The second control member is an inspection device for a light guide that moves in the Y-axis direction and the Z-axis direction. According to clause 3,
The second control member is a light guide inspection device that rotates around the Y-axis and the Z-axis as rotation axes. According to clause 1,
An inspection device for a light guide wherein the angle of view control member controls the angle of view of the light to 40° to 50°. Emitting light from a light source member;
incident of the light onto a view angle control member;
reflecting the light from a reflective member;
The light is incident on the light guide;
Measuring characteristics of incident light incident on the light guide;
The light is emitted from the light guide; and
A method of inspecting a light guide comprising measuring characteristics of emitted light and lost light emitted from the light guide. According to clause 7,
The light incident on the view angle control member is controlled by the view angle and is incident on the reflection member,
The optical axis of the light incident from the angle of view control member to the reflective member is defined as the Y axis,
X and Z axes perpendicular to the Y axis are defined,
A method of inspecting a light guide in which the reflective member is disposed inclined at an angle of 40° to 50° with respect to an imaginary line perpendicular to the Y axis. According to clause 8,
The first control member moves in one direction,
The second control member moves in multiple directions,
A method for inspecting a light guide in which the second control member rotates in multiple directions. According to clause 8,
The first control member moves in the Z-axis direction,
The second control member moves in the Y-axis direction and the Z-axis direction,
The second control member rotates around the Y-axis and the Z-axis as rotation axes.

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