KR102157554B1 - Diffractive light guide plate and display device including the same - Google Patents

Abstract

Embodiments according to an aspect of the present invention include a light guide unit for guiding light; An input diffraction optical element that receives light from a light source and diffracts the received light so that the received light can be guided on the light guide unit; An intermediate diffraction optical element configured to receive the light diffracted from the input diffraction optical element and to allow the received light to be expanded one-dimensionally by diffraction; And an output diffraction optical element configured to receive the extended light from the intermediate diffraction optical element and to output the received light from the optical guide unit by diffraction, wherein the intermediate diffraction optical element and the output diffraction optical element are the optical guide The intermediate diffraction optical elements are separated from each other in regions separated from each other along the horizontal direction on the part, and the intermediate diffractive optical element includes a main intermediate diffractive optical element and a plurality of auxiliary intermediate diffractive optical elements that are spaced apart from each other along the vertical direction on the optical guide unit. It provides a diffractive light guide plate.

Description

A diffractive light guide plate and a display device including the same TECHNICAL FIELD

The present invention relates to a display device comprising a diffractive light guide plate and a diffractive light guide plate.

Recently, as interest in display units implementing Augmented Reality (AR), Mixed Reality (MR), or Virtual Reality (VR) has increased, research on display units implementing this has been actively conducted. There is a trend. A display unit implementing augmented reality, mixed reality, or virtual reality includes a diffractive light guide plate using a diffraction phenomenon based on the wave nature of light.

The diffractive light guide plate may include an optical guide portion and a plurality of diffractive optical elements provided on one or the other surface of the optical guide portion and having a plurality of grating line patterns. Specifically, the diffractive light guide plate is optically coupled to the first diffraction optical element through which light output through the micro light source output element is input and guided onto the light guide unit, and the first diffraction optical element through the light guide unit. The second diffraction optical element is optically coupled to the second diffraction optical element through a second diffraction optical element and an optical guide unit that enables one-dimensional expansion in the first direction by diffraction of the light received from the element. A third diffraction optical element may be provided that outputs the received light from the optical guide while diffracting the received light in a second direction by diffraction and directs it to the pupil of the user.

1A is a view schematically showing a diffractive light guide plate according to an example of the prior art, and FIG. 1B is a schematic view showing a display device including the diffractive light guide plate shown in FIG. 1A.

1A, in a diffractive light guide plate 10 according to an example of the prior art, a first diffraction optical element 12 is disposed on one side of an optical guide unit 11, and a second diffraction optical element 13 is an optical guide. A horizontal direction (y-axis direction in FIG. 1) extending from one side of the part 11 to the other side is elongated in the main direction, and is disposed on the optical guide part 11, and the third diffraction optical element 14 ) May have a structure that is spaced apart from the second diffractive optical element 13 on the optical guide part 11 in the main direction in the vertical direction (the x-axis direction in FIG. 1 ). That is, the path in which the first diffraction optical element 12, the second diffraction optical element 13, and the third diffraction optical element 14 are arranged on the optical guide part 11 is a structure in which the overall “a” shape is formed. I can.

On the other hand, in the case where the first direction in which the light is expanded one-dimensionally by diffraction in the second diffraction optical element 13 is the horizontal direction as the main direction, and the path in which the diffractive optical element is arranged is in the shape of “A” In this case, when the second diffraction optical element 13 moves the horizontal direction from the first diffraction optical element 12 in the main direction and diffracts the received light in the main direction, the diffracted light is diffracted into the third diffraction optical element. (14) can be directed to the side.

That is, in this structure, the second diffraction optical element 13 can direct the light received from the first diffraction optical element 12 to the third diffraction optical element 14 only by diffracting the light received from the first diffraction optical element 12 an odd number of times. The number of diffraction for directing to the 3-diffraction optical element N = 2n-1, n is the number of diffraction in the x-axis direction). On the other hand, a part of the light received through the second diffraction optical element 13 is diffracted and the remaining part is totally reflected, and again, some of the light is diffracted, and the rest of the light is repetitively diffraction and total reflection. . Accordingly, when diffraction in which the optical movement path is changed is performed multiple times with respect to the direction in which total reflection proceeds, the amount of light gradually decreases in the direction in which total reflection proceeds. Therefore, simply by gradually increasing the diffraction rate (a value obtained by dividing the amount of diffracted light by the amount of light before diffracting) along the horizontal direction, which is the extension direction of the second diffraction optical element 13, the second diffraction optical element 30 There is an advantage of being able to easily achieve uniformity of the amount of light of the lights expanded by diffraction from

A rainbow pattern may occur due to interference by external light with respect to image light in which diffraction and total reflection occurs in a certain area of the optical guide unit 11 in which the second diffraction optical element 13 is disposed, and to prevent this It is necessary to provide a reduction layer for reducing the light-receiving rate of external light received on a predetermined area of the optical guide unit 11 in which the second diffraction optical element 13 is disposed.

Meanwhile, in the diffraction light guide plate 10 according to an example of the prior art, the second diffraction optical element 13 and the third diffraction optical element 14 are separately disposed in regions A and B separated from each other along the vertical direction. , Specifically, the second diffraction optical element 13 is disposed in the upper region A of the regions separated from each other along the vertical direction, and the third diffraction optical element 14 is the lower part of the regions separated from each other along the vertical direction. It is arranged in the area B. In this case, since the second diffraction optical element 13 is elongated in the main direction along the horizontal direction, the reduction layer 15 is formed on a certain area of the optical guide 11 in which the second diffraction optical element 13 is disposed. ), the reduction layer 15 occupies a significant portion of the upper area on the lens to which the diffractive light guide plate 10 can be applied, such as the display device shown in FIG. 1B, and thus has a disadvantage in appearance.

2 is a diagram schematically showing a diffractive light guide plate according to another example of the prior art.

2, in the diffractive light guide plate 20 according to another example of the prior art, a first diffraction optical element 22 is disposed on one side of the optical guide unit 21, and the second diffraction optical element 23 is A vertical direction (x-axis direction in FIG. 2) extending from the top to the bottom of the light guide part 21 is elongated in the main direction, and is disposed on the light guide part 21, and a third diffraction optical element Reference numeral 24 may be a structure in which the horizontal direction (y-axis direction in FIG. 2) is separated from the lower end of the second diffractive optical element 23 on the optical guide part 21 in the main direction. In other words, the path in which the first diffraction optical element 22, the second diffraction optical element 23, and the third diffraction optical element 24 are arranged on the optical guide part 21 is a structure in which the overall “b” shape is formed. I can.

On the other hand, in the second diffraction optical element 23, since the first direction in which light is one-dimensionally expanded by diffraction is the vertical direction as the main direction, when the path in which the diffractive optical element is arranged is in the form of “b” In this case, the second diffraction optical element 23 must first diffract the vertical direction to the main direction for the light that has been moved in the main direction and received the horizontal direction from the first diffraction optical element 22. Further, the diffracted light in the vertical direction should be diffracted again in the horizontal direction in the main direction, so that the diffracted light can be directed toward the third diffraction optical element 24.

That is, in such a structure, the light received from the first diffraction optical element 22 by the second diffraction optical element 23 must be diffracted by an even number of times to direct it to the third diffraction optical element 24 (the third diffraction optical element 24). The number of diffractions for directing to the optical element N = 2n, where n is the number of diffractions in the x-axis or y-axis direction).

On the other hand, when diffraction in which the optical path is changed multiple times with respect to the direction in which the total reflection proceeds, the amount of light gradually decreases in the direction in which the total reflection proceeds. However, one-dimensional diffraction from the second diffraction optical element 23 In general, in order to make the amount of light of the expanded light uniform, more constructive interference of light needs to be accompanied by basically more than the case of odd-numbered diffraction, so it is necessary to form a wide width in the main direction in the horizontal direction. However, the grating line pattern of the second diffraction optical element 23 may slightly distort the intended total reflection path on the optical guide unit 21. In this way, when the second diffraction optical element 23 is elongated in the vertical direction in the main direction and the width in the horizontal direction is widened in the main direction, the light moving in total reflection encounters the grating line pattern more, so that the diffraction and total reflection are observed. There is a possibility that the furnace is formed differently from the original design intention, which causes a problem of deteriorating the quality of the image light output through the third diffraction optical element 34.

The above-described background technology is technical information that the inventor possessed for derivation of the embodiments of the present invention or acquired during the derivation process, and is not necessarily known to the public before filing the embodiments of the present invention. none.

US 2014/0300966 A1

In the present invention, a diffractive optical element that one-dimensionally expands image light forming an image on an optical guide unit and a diffractive optical element that outputs the extended image light from the optical guide are spaced apart from each other along the horizontal direction on the optical guide unit. An object of the present invention is to provide a diffractive light guide plate that has a structure but can prevent the image quality from deteriorating, and a display device including the diffractive light guide plate.

However, the problem to be solved by the present invention is not limited to the above-mentioned problems, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

Embodiments according to an aspect of the present invention include a light guide unit for guiding light; An input diffraction optical element that receives light from a light source and diffracts the received light so that the received light can be guided on the light guide unit; An intermediate diffraction optical element configured to receive the light diffracted from the input diffraction optical element and to allow the received light to be expanded one-dimensionally by diffraction; And an output diffraction optical element configured to receive the extended light from the intermediate diffraction optical element and to output the received light from the optical guide unit by diffraction, wherein the intermediate diffraction optical element and the output diffraction optical element are the optical guide The intermediate diffraction optical elements are separated from each other in regions separated from each other along the horizontal direction on the part, and the intermediate diffractive optical element includes a main intermediate diffractive optical element and a plurality of auxiliary intermediate diffractive optical elements that are spaced apart from each other along the vertical direction on the optical guide unit. And the main intermediate diffraction optical element is optically coupled to the input diffraction grating through the optical guide unit to direct diffracted light received from the input diffraction grating toward the auxiliary intermediate diffraction optical element by diffraction, and the plurality of Among the auxiliary intermediate diffraction optical elements, a first auxiliary intermediate diffraction optical element disposed adjacent to the main intermediate diffraction optical element is optically coupled to the main intermediate diffraction optical element through the optical guide unit and received from the main intermediate diffraction optical element. The diffracted light is directed toward the output diffractive optical element by diffraction, and the second auxiliary intermediate diffractive optical element disposed adjacent to the first auxiliary intermediate diffractive optical element is optically connected to the first auxiliary intermediate diffractive optical element through the optical guide unit. There is provided a diffraction light guide plate that is coupled to receive light that has not been diffracted from the first auxiliary intermediate diffraction optical element toward the output diffraction optical element and directs it to the output diffraction optical element by diffraction.

In this embodiment, it is preferable that the extending direction of the auxiliary intermediate diffractive optical element is inclined with respect to the extending direction of the main intermediate diffractive optical element.

In the present embodiment, it is preferable that the extension directions of the first auxiliary intermediate diffractive optical element and the second auxiliary intermediate diffractive optical element are parallel to each other.

In this embodiment, it is preferable that the main intermediate diffraction optical element gradually increases the diffraction rate from one side to the other side along the extension direction.

In this embodiment, it is preferable that the auxiliary intermediate diffraction optical element has the same diffraction rate from one side to the other along the extension direction.

In this embodiment, it is preferable that the diffraction rate of the second auxiliary intermediate diffraction optical element is higher than that of the first auxiliary intermediate diffraction optical element.

In this embodiment, the intermediate diffractive optical element is disposed on one side of the optical guide unit, and output from the light source is in an area corresponding to a region in which the intermediate diffractive optical element is located on one side or the other side of the optical guide unit. A reduction unit for reducing a light-receiving rate of external light other than light may be disposed.

An embodiment according to another aspect of the present invention includes a light source that outputs image light forming an image; And it provides a display device including a diffraction light guide plate according to an aspect of the present invention.

According to embodiments of the present invention, an intermediate diffraction optical element that one-dimensionally expands image light forming an image on the optical guide unit and an output diffraction optical element that outputs the expanded image light from the optical guide unit is provided on the optical guide unit. It has a structure that is spaced apart along the horizontal direction, but the intermediate diffraction optical element has a structure including a main intermediate diffraction optical element and an auxiliary intermediate diffraction optical element that are spaced apart from each other along the vertical direction on the optical guide unit, It can prevent the image quality from deteriorating.

1A is a diagram schematically showing a diffractive light guide plate according to an example of the prior art.
1B is a schematic diagram of a display device including the diffractive light guide plate shown in FIG. 1A.
2 is a diagram schematically showing a diffractive light guide plate according to another example of the prior art.
3 is a diagram schematically illustrating a diffractive light guide plate according to an aspect of the present invention.
4A to 4C are cross-sectional views taken along the line IV-IV of FIG. 3 and are views showing various embodiments for controlling the diffraction rate in the main intermediate diffraction optical device.
5A is a cross-sectional view taken along the line V-V of FIG. 3, and FIG. 5B is a cross-sectional view taken along the line V'-V' of FIG. 3, showing a first auxiliary intermediate diffraction optical element and a second auxiliary intermediate diffraction optic. It is a diagram showing an example in which the diffraction rate of the device is different.
6 is a schematic diagram illustrating an embodiment of a display device according to another aspect of the present invention.
7 is a schematic diagram illustrating another embodiment of a display device according to another aspect of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms different from each other, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to those who have it, and the invention is only defined by the scope of the claims. Meanwhile, terms used in the present specification are for explaining embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless specifically stated in the phrase. As used in the specification, "comprises" and/or "comprising" refers to the presence of one or more other components, steps, actions and/or elements, and/or elements, steps, actions and/or elements mentioned. Or does not exclude additions. Terms such as first and second may be used to describe various components, but the components should not be limited by terms. The terms are only used for the purpose of distinguishing one component from another component.

In the present specification, the term "light guide part" may be defined as a structure for guiding light from the inside using total internal reflection. The condition for total internal reflection is that the refractive index of the optical guide portion must be greater than that of the surrounding medium adjacent to the surface of the optical guide portion. The light guide unit may be formed of a glass and/or plastic material, and may be transparent or translucent. The light guide portion may be formed in various layouts on a plate type. Here, the term "plate" refers to a three-dimensional structure having a predetermined thickness between one surface and the other surface opposite to it, and the one surface and the other surface may be substantially flat planes, but at least one surface of the one surface and the other surface is It may be formed to be curved one-dimensionally or two-dimensionally. For example, the plate-type light guide portion may be curved one-dimensionally so that one surface and/or the other surface thereof may have a shape corresponding to some of the side surfaces of the cylinder. However, it is preferable that the curvature formed by the curvature has a sufficiently large radius of curvature to facilitate total internal reflection in order to guide light on the light guide part.

In the present specification, the term "diffraction optical device" may be defined as a structure for changing an optical path by diffracting light on an optical guide part. Here, the “diffraction optical device” may mean a portion in which a plurality of grid lines oriented in one direction on the optical guide unit are arranged in a predetermined direction to form a predetermined area while having a pattern.

In the present specification, the term "lattice line" is a protrusion shape having a predetermined height on the surface of the optical guide unit (ie, a relief pattern) and/or a groove shape having a predetermined depth on the surface of the light guide unit (ie, an intaglio pattern Can mean ). Here, the orientation direction of the grating line can be freely designed so that the optical path can be changed in the intended direction through diffraction by the diffractive optical element.

In the present specification, the term "extension direction of the diffraction optical element" means a length that can be defined based on two directions substantially perpendicularly intersecting a predetermined area formed by arranging the diffractive optical element on the optical guide unit When it is desired to distinguish the width, it may mean a length direction which is a direction that can be calculated to be longer among the two directions.

In this specification, the term "main direction" refers to a direction in which a specific element is extended, and the actual extended direction is parallel to the reference direction or 45 degrees or less with respect to the reference direction (including both clockwise and counterclockwise directions. ) Can be inclined, it can be used like the phrase'a specific element extends the reference direction to the main direction'.

In the present specification, the term "diffraction index" means that the light totally internally reflected on the optical guide part is partially diffracted by the diffractive optical element to change the optical path, and the rest may be totally reflected along the optical path before diffraction. It may mean a value obtained by dividing the amount of light of the diffracted light whose furnace is changed by the amount of light immediately before being diffracted.

In the present specification, the term "light-receiving rate of external light" may mean a ratio of the amount of light that is received by reaching one or the other surface of the optical guide unit compared to the amount of external light traveling toward one side or the other side of the optical guide unit. have.

3 is a diagram schematically illustrating a diffractive light guide plate according to an aspect of the present invention.

Referring to FIG. 3, the diffractive light guide plate 100 may include an optical guide unit 110, an input diffractive optical element 120, an intermediate diffractive optical element 130, and an output diffractive optical element 140.

The light guide unit 110 may guide light from the inside using total internal reflection.

The input diffraction optical element 120 may receive the light L1 from the light source 200 and diffract the received light so that the received light may be guided on the light guide unit 110. The input diffraction optical element 120 may be disposed on one side (eg, the left side of FIG. 3) of the one surface 110a of the optical guide unit 110.

The intermediate diffraction optical element 130 may be configured to receive the light L2 diffracted from the input diffraction optical element 120 and to expand the received light one-dimensionally by diffraction. As the diffracted light received from the input diffraction optical element 120 passes through the intermediate diffraction optical element 130, some of the diffracted light is diffracted to change the optical path, and the rest may be totally reflected to the existing optical path, from the optical element 120. Since the initially received light may be divided into a plurality of beams L3 while such diffraction is performed a plurality of times at a point spaced apart in a specific direction, eventually one-dimensional expansion may be achieved.

The output diffraction optical element 140 may be configured to receive the extended light (L3b, L3b') from the intermediate diffraction optical element 130 and output the received light from the optical guide unit 110 by diffraction. On the other hand, the output diffraction optical element 140 may also one-dimensionally expand the light received from the intermediate diffraction optical element 130 by diffraction. At this time, the direction in which the plurality of beams L3b and L3b' formed by the light expanded by the intermediate diffraction grating 130 are spaced apart from the light receiving side 140a of the output diffraction optical element 140, and a single beam ( L3b, L3b') Since the directions in which the plurality of beams L4 extended by the reference output diffraction optical element 140 are spaced apart cross each other (for example, orthogonal), the input diffraction optics from the light source 200 A two-dimensional expansion is made based on the light received by the device 120.

The intermediate diffraction optical element 130 and the output diffraction optical element 140 may be separately disposed in regions S1 and S2 separated from each other along the horizontal direction (y-axis direction based on FIG. 3) on the optical guide unit 110. have. In detail, the intermediate diffraction optical element 130 is disposed in a first region S1 adjacent to the input diffraction optical element 120 among the first region S1 and the second region S2 that are separated from each other, and the output diffraction optical element 140 may be disposed in the second area S2 located to the right (based on FIG. 3) than that.

On the other hand, when external light input from a light source is incident on the intermediate diffraction optical element 130, interference occurs in the image light that is output from the light source and received and diffracted, so that a rainbow pattern is formed in the region where the intermediate diffraction optical element 130 is located. Can occur. Therefore, it is necessary to provide a reduction unit for reducing the light-receiving rate of external light received by the intermediate diffraction optical element 130.

According to an embodiment of the present invention, when the intermediate diffractive optical element 130 and the output diffractive optical element 140 are separately disposed in regions divided in the horizontal direction, the actual glasses-type head mounted display device (FIG. 6 or 7 In designing), the input diffractive optical element 120 and the intermediate diffractive optical element 130 are placed in a region adjacent to the support 320 supported by the wearer's nose or the leg 530 supported by the wearer's ear. It can be densely arranged in adjacent areas. In addition, the output diffractive optical element 140 is far apart from the input diffractive optical element 120 and the intermediate diffractive optical element 130 and can be disposed in a region corresponding to the position of the pupil of the wearer. In the end, the reduction unit 150 for reducing the light-receiving rate of the external light received by the intermediate diffraction optical element 130, and the intermediate diffraction densely disposed in the area adjacent to the support unit 320 or the area adjacent to the leg unit 530 Since it can be disposed in a region corresponding to the optical element 130, interference by the reduction unit 150 can be minimized when the wearer visually recognizes the external environment.

The intermediate diffraction optical element 130 includes a main intermediate diffraction optical element 131 and a plurality of auxiliary intermediate diffraction optical elements 132a and 132b that are spaced apart from each other along the vertical direction (x-axis direction based on FIG. 3) on the optical guide unit 110. ) Can be included. Here, the main intermediate diffraction optical element 131 and the plurality of auxiliary intermediate diffraction optical elements 132a and 132b are spaced apart from each other along the vertical direction on the optical guide unit 110 so that the extension directions are parallel to each other. It is not limited to a shape that is spaced apart along the vertical direction, and any spaced arrangement shape may be possible as long as it is disposed on the light guide unit 110 with a region in which a grid line pattern is not formed therebetween.

The main intermediate diffraction optical element 131 is optically coupled with the input diffraction optical element 120 through the optical guide unit 110 to diffract the diffracted light received from the input diffraction optical element 120 by diffraction. It can be directed toward the elements 132a and 132b. In this embodiment, since the main intermediate diffraction optical element 131 and the auxiliary intermediate diffraction optical elements 132a and 132b are spaced apart in the vertical direction, light diffracted by the main intermediate diffraction optical element 131 is in the vertical direction ( 3, the x-axis direction) may be used as the main direction, and may proceed through total internal reflection on the optical guide unit 110.

The main intermediate diffraction optical element 131 may extend in a horizontal direction (y-axis direction based on FIG. 3) as a main direction.

The diffraction rate of the main intermediate diffraction optical element 131 may gradually increase from one side (left of FIG. 3) to the other side (right of FIG. 3) along the extension direction. The light received by the main intermediate diffraction optical element 131 from the input diffraction optical element 120 is totally internally reflected on the optical guide unit 110 and moves with the extension direction of the main intermediate diffraction optical element 131 as the main direction, Part of the light is diverged by diffraction on the total reflection path by the grating line pattern so that the light path is directed toward the auxiliary intermediate diffraction optical elements 132a and 132b. As a result, as the main diffractive optical element 131 extends along the total reflection path as the main direction, the amount of light decreases. That is, since the amount of light to be diffracted by the grating line pattern also decreases along the total reflection path, the diffraction rate is increased along the extension direction in the main diffraction optical element 131, thereby Expanded light that is diffracted and directed toward the auxiliary intermediate diffraction optical element 132a, that is, the plurality of first beams L3a may have similar amounts of light therebetween.

4A to 4C are IV-IV cross-sectional views of FIG. 3, showing various embodiments for controlling diffraction rate in the main intermediate diffraction optical device.

Referring to FIG. 4A, a plurality of grating lines included in the main intermediate diffraction optical element 131 are provided in a protrusion shape 131a having a predetermined height h1 on one surface 110a of the optical guide unit 110. Can be. The grating lines of the protrusion shape 131a may be disposed with a predetermined period d1 along the extending direction of the main intermediate diffraction optical element 131. In addition, the height h1 of the grating line having the protrusion shape 131a may gradually increase from one side to the other side along the extension direction of the main intermediate diffraction optical element 131. Here, the degree to which the height of the grid line h1 of the protrusion shape 131a increases may be a form that continuously increases at a predetermined rate along the extension direction, but it is constant within a predetermined section and then further increases when passing to another section. It can also take the form of a step function.

4B, a plurality of grating lines included in the main intermediate diffraction optical element 131 are provided in a groove shape 131b having a predetermined depth h2 on one surface 110a of the optical guide unit 110 Can be. The grating line of the groove shape 131b may be disposed with a predetermined period d2 along the extension direction of the main intermediate diffraction optical element 131. In addition, the grating line of the groove shape 131b may gradually increase in depth h2 from one side to the other side along the extension direction of the main intermediate diffraction optical element 131. Here, the degree of the deepening of the grid line depth h2 of the groove shape 131b may be a form that continuously increases at a predetermined rate along the extension direction, but is constant within a predetermined section along the extension direction and then to another section. It can also take the form of a step function that increases further.

Referring to FIG. 4C, a plurality of grating lines included in the main intermediate diffraction optical element 131 are provided in a protrusion shape 131c having a predetermined height h3 on one surface 110a of the optical guide unit 110. Can be. The grating line of the protrusion shape 131a may be disposed with a predetermined period d3a along the extending direction of the main intermediate diffraction optical element 131. Meanwhile, the grid line of the protrusion shape 131a may have a predetermined width d3b within the period d3a, a value obtained by dividing the width d3b of the grid line by the period d3a of the grid line (d3b/d3a) Will be defined as “duty”. Here, the duty of the grating line may increase from one side to the other side along the extension direction of the main intermediate diffraction optical element 131. Here, the degree of increase of the duty of the grid line may be a form that continuously increases at a predetermined ratio along the extension direction, but may take the form of a step function that is constant within a predetermined section and increases further when passing to another section.

A plurality of auxiliary intermediate diffraction optical elements 132 may be provided so as to be spaced apart from each other along the vertical direction (the x-axis direction of FIG. 3) on the optical guide unit 110. Each of the auxiliary intermediate diffraction optical elements 132a and 132b receives light whose main optical path goes from the upper side of the optical guide unit 110 to the lower side (see Fig. 3), and directs it toward the output diffraction optical element 140 by diffraction. Can be configured to In this embodiment, since the intermediate diffraction optical element 130 and the output diffraction optical element 140 are disposed in separate regions along the horizontal direction, the light diffracted by the auxiliary intermediate diffraction optical elements 132a and 132b is It may proceed through total internal reflection on the optical guide unit 110 with the horizontal direction (y-axis direction based on FIG. 3) as the main direction.

On the other hand, as the number of auxiliary intermediate diffraction optical elements 132 spaced apart from each other along the vertical direction increases, the light L3a diffracted by the main intermediate diffraction optical element 131 is separated from the auxiliary intermediate diffraction optical element 132 A plurality of beams L3b and L3b ′ may be re-branched and expanded along the vertical direction, which is the direction in which it is formed. Therefore, by increasing the number of auxiliary intermediate diffraction optical elements 132 rather than lengthening the extension lengths of the main intermediate diffraction optical element 131 and the auxiliary intermediate diffraction optical element 132, one-dimensional expansion of light as much as a target can be achieved. You can achieve it. However, as the number of auxiliary intermediate diffraction optical elements 132 increases, the number of times the progressing light meets the grid line increases, and the actual optical path is compared with the intended target optical path. It can increase the likelihood of being wrong. Therefore, it is desirable to minimize the number of the plurality of auxiliary intermediate diffraction optical elements 132. For example, as in the embodiment of the present invention, the auxiliary intermediate diffraction optical element 132 includes two auxiliary intermediate diffraction optical elements, such as the first auxiliary intermediate diffraction optical element 132a and the second auxiliary intermediate diffraction optical element 132b. It can be configured to have an element.

The first auxiliary intermediate diffraction optical element 132a disposed adjacent to the main intermediate diffraction optical element 131 among the plurality of auxiliary intermediate diffraction optical elements 132a and 132b is a main intermediate diffraction optical element ( The diffracted light L3a, which is optically coupled to the 131 and received from the main intermediate diffraction optical element 131, can be directed toward the output diffraction optical element 140 by diffraction.

The second auxiliary intermediate diffractive optical element 132b disposed adjacent to the first auxiliary intermediate diffractive optical element 132a among the plurality of auxiliary intermediate diffractive optical elements 132a and 132b is provided through the optical guide unit 110. Optically coupled with the diffraction optical element 132a, the first auxiliary intermediate diffraction optical element 132a receives the undiffracted light L3a' from the output diffraction optical element 140 side, and the diffracted light L3b ') may be directed toward the output diffraction optical element 140.

It is preferable that the extension direction of the auxiliary intermediate diffraction optical elements 132a and 132b is inclined toward the lower side of the optical guide unit 110 (see FIG. 3) with respect to the extension direction of the main intermediate diffraction optical element 131. Meanwhile, the light diffracted by the auxiliary intermediate diffraction optical elements 132a and 132b is propagated toward the right side (refer to FIG. 3) on the optical guide unit 110 and proceeds toward the output diffraction optical element 140. An optical path may be formed with the extending direction of the diffractive optical element 131 as the main direction. If, unlike in the present embodiment, if the extension direction of the auxiliary intermediate diffractive optical element is approximately parallel to the extension direction of the main intermediate diffractive optical element, the light traveling toward the output diffractive optical element follows the extension direction of the auxiliary intermediate diffractive optical element. It repeatedly encounters the occupied grid line, and the light path may be slightly twisted each time. In this case, it is difficult to form an intended optical path, and eventually the quality of an image formed by light is degraded. Meanwhile, as in the present embodiment, the extension direction of the auxiliary intermediate diffraction optical elements 132a and 132b is the lower side of the optical guide unit 110 (see FIG. 3) with respect to the extension direction of the main intermediate diffraction optical element 131. If it is inclined toward the output diffraction optical element 140, the light traveling toward the output diffraction optical element 140 proceeds in a direction inclined toward the upper side of the optical guide unit 110 (see FIG. 3) with respect to the extension direction of the auxiliary intermediate diffraction optical element 132. In the end, the number of times the advancing light meets the grating line occupied along the extension direction of the auxiliary intermediate diffraction optical element 132 can be significantly reduced compared to the above-described case, and the optical path can be prevented from turning into an unintended path. . In the end, there is an advantage in that the quality of an image formed by light can be maintained at a high level.

It is preferable that the extension directions of the first auxiliary intermediate diffractive optical element 132a and the second auxiliary intermediate diffractive optical element 132b are parallel to each other. The lengthwise separation distance of the optical guide unit 110 between the points where the plurality of beams L3a meet along the extension direction of the first auxiliary intermediate diffraction optical element 132a, and the extension of the second auxiliary intermediate diffraction optical element 132b A plurality of beams whose optical paths are changed by the first auxiliary intermediate diffraction optical element 132a by similarly forming the longitudinal separation distance of the optical guide unit 110 between points where the plurality of beams L3a' meet along the direction ( L3b) and the second auxiliary intermediate diffraction optical element (132b) to form a longitudinal separation distance of the optical guide unit 110 between the plurality of beams (L3b') is changed in the optical path is similar. As a result, the ratio of the amount of light that is reduced due to the expansion of the light can be kept similar over the area where the light is expanded.

It is preferable that the auxiliary intermediate diffraction optical elements 132a and 132b have substantially the same diffraction rate from one side (left of FIG. 3) to the other side (right of FIG. 3) along the extension direction. The auxiliary intermediate diffraction optical element 132 receives the plurality of first beams L3a and L3a' and directs it toward the output intermediate diffraction optical element 140 by diffraction, so that the plurality of second beams L3b whose optical paths are changed , L3b') to allow total internal reflection through the optical guide unit 110. At this time, in this embodiment, since the plurality of first beams L3a or L3a' have similar amounts of light, the first beam L3a or L3a' is diffracted by the auxiliary intermediate diffraction optical elements 132a and 132b. When the diffraction rate at each point is substantially the same, the amount of light between the plurality of second beams L3b or L3b' whose optical paths are changed may also be similar to each other.

Here, it is preferable that the diffraction rate of the second auxiliary intermediate diffraction optical element 132b is higher than that of the first auxiliary intermediate diffraction optical element 132a. For example, the diffraction rate of the first auxiliary intermediate diffraction optical device 132a may be about 50%, and the diffraction rate of the second auxiliary intermediate diffraction optical device 132b may be close to about 100%. Accordingly, the first auxiliary intermediate diffraction optical element 132a diffracts the light L3a received from the main intermediate diffraction optical element 131 by about 50% (thereby, the amount of light of L3b is about 50% of L3a) and the remaining 50%. The degree proceeds toward the second auxiliary intermediate diffraction optical element 132b (thereby, the light quantity of L3a' is about 50% of L3a), and the second auxiliary intermediate diffraction optical element 132b is the first auxiliary intermediate diffraction optical element 132a. ), it is possible to diffract light (L3a') received from) to close to 100% (thereby, the amount of light of L3b' is about 50% of L3a). Eventually, the amount of light of L3b whose optical path is changed by diffracting by the first auxiliary intermediate diffraction optical element (132a) and L3b' whose optical path is changed by diffracting by the second auxiliary intermediate diffraction optical element (132b) is It is diffracted by the device 131 and the optical path may be similar to the level of 50% of the amount of light of the changed L3a.

FIG. 5A is a cross-sectional view taken along the line V-V of FIG. 3, and FIG. 5B is a cross-sectional view taken along the line V'-V' of FIG. 3, showing a first auxiliary intermediate diffraction optical element and a second auxiliary intermediate diffraction optic. A diagram showing an example in which the diffraction rate of the device is different.

5A and 5B, a plurality of grating lines included in the first auxiliary intermediate diffractive optical element 132a and the second auxiliary intermediate diffractive optical element 132b are all shown on one side of the optical guide unit 110 ( 110a) is shown to be provided in the shape of protrusions 1321a and 1321b having predetermined heights ha and hb. However, the plurality of grid lines may be provided in a groove shape having a predetermined depth on one surface 110a of the light guide unit 110 in addition to the protrusion shape. Hereinafter, for convenience of description, a description will be made focusing on a plurality of grid lines provided in protrusions 1321a and 1321b. The grid lines of the protrusions 1321a and 1321b may be arranged with a predetermined period d5. On the other hand, the grating lines of the protrusion shapes 1321a and 1321b may have the same height (ha, hb) along the extension direction within the first auxiliary intermediate diffraction optical element 132a or the second auxiliary intermediate diffraction optical element 132b. I can. This is to ensure that the diffraction rate of the first auxiliary intermediate diffraction optical element 132a or the second auxiliary intermediate diffraction optical element 132b can be formed equally along the extension direction. However, the height hb of the grating line 1321b of the second auxiliary intermediate diffraction optical element 132b is higher than the height ha of the grating line 1321a of the first auxiliary intermediate diffraction optical element 132a. desirable. This is to make the diffraction rate of the second auxiliary intermediate diffraction optical element 132b higher than that of the first auxiliary intermediate diffraction optical element 132a. On the other hand, if the grating lines in the first and second auxiliary intermediate diffraction optical elements 132a and 132b are formed in a groove shape, the groove is more than the first auxiliary intermediate diffraction optical element 131b. It would be desirable to form deeper in 132a).

The intermediate diffraction optical element 130 may be disposed on one side 110a of the optical guide unit 110. To reduce the light-receiving rate of external light other than the light L output from the light source 200 in an area corresponding to the area where the intermediate diffraction optical element 130 is located on one side 110a or the other side 110b of the optical guide unit The reduction unit 150 may be disposed. Here, the reduction unit 150 may be a film layer capable of covering an area corresponding to an area in which the intermediate diffraction optical element 130 is located on one side 110a side or the other side 110b side of the optical guide unit, and is opaque. It may include a substance, for example a black substance. The reduction unit 150 may be formed of, for example, black ink. Another aspect of the reduction unit 150 is spaced apart from the light guide unit 110 from a region corresponding to the region in which the intermediate diffractive optical element 130 is located on one side 110a or the other side 110b of the light guide unit. It may be a plastic or glass structure disposed spaced apart a predetermined distance in the direction. Such plastic or glass structures can also be formed comprising an opaque material, for example a black material, more specifically a black ink.

6 is a schematic diagram illustrating an embodiment of a display device according to another aspect of the present invention.

The display apparatus 1000 may include a light source (not shown) that outputs image light forming an image, and the diffractive light guide plate 100 according to an aspect of the present invention described above. Here, the display device 1000 may be a head mount type display device having a structure in which the diffractive light guide plate 100 is coupled to the main body 300 having the shape of an eyeglass frame. Here, the main body 300 connects a pair of edge portions 310 to which the diffraction light guide plate 100 can be coupled, and one side of the pair of edge portions 310 to each other, and is formed by the wearer's nose (not shown). It may include a supporting part 320 supported, and a leg part 330 connected to the other side of the rim part 310 and supported by the wearer's ear (not shown).

In the diffractive light guide plate 100 and/or the display device 1000 according to the embodiment of the present invention, the intermediate diffractive optical element 130 and the output diffractive optical element 140 are arranged in the horizontal direction of the optical guide unit 110 (see FIG. 6 ). y-axis direction), so that the intermediate diffractive optical element 130 is disposed in a separate region along the direction of the y-axis), so that the intermediate diffraction optical element 130 is a region (S1a) adjacent to the support part 320 supported by the wearer's nose (not shown). The output diffraction optical device 140 may be disposed in a region S2a adjacent to the leg portion 330 supported by the wearer's ear. Therefore, even if the reduction unit 150 is disposed in the region on the other surface 110b of the optical guide unit 110 corresponding to the region where the intermediate diffraction optical element 130 is located, the wearer's field of view is blurred by the reduction unit 150. There is an advantage that can be minimized.

7 is a schematic diagram illustrating another embodiment of a display device according to another aspect of the present invention.

The display apparatus 2000 may include a light source (not shown) that outputs image light forming an image, and the diffractive light guide plate 100 according to an aspect of the present invention described above. Here, the display device 2000 may be a head mount type display device having a structure in which the diffractive light guide plate 100 is coupled to the main body 500 having the shape of an eyeglass frame. Here, the main body 500 connects a pair of edge portions 510 to which the diffraction light guide plate 100 can be coupled, and one side of the pair of edge portions 510 to each other, and is formed by the wearer's nose (not shown). It may include a supporting portion 520 supported and a leg portion 530 connected to the other side of the rim portion 510 and supported by the wearer's ear (not shown).

In the diffractive light guide plate 100 and/or the display device 2000 according to the embodiment of the present invention, the intermediate diffractive optical element 130 and the output diffractive optical element 140 are arranged in the horizontal direction of the optical guide unit 110 (see FIG. 5 ). Since they are arranged separately in regions separated from each other along the y-axis direction), in more detail, the intermediate diffraction optical element 130 is a region (S1b) adjacent to the leg portion 530 supported by the wearer's ear (not shown). ), and the output diffraction optical element 140 may be disposed in an area S2b adjacent to the support part 520 supported by the wearer's nose (not shown). Therefore, even if the reduction unit 150 is disposed in the region on the other surface 110b of the optical guide unit 110 corresponding to the region where the intermediate diffraction optical element 130 is located, the wearer's field of view is blurred by the reduction unit 150. There is an advantage that can be minimized.

In addition, in the diffractive light guide plate 100 and/or the display devices 1000 and 2000 according to the embodiments of the present invention, light received from the input diffraction optical element 120 is transmitted from the main intermediate diffraction optical element 131. By diffraction, the optical path is changed with the vertical direction (the x-axis direction based on FIGS. 3 and 5) as the main direction, and the light whose optical path is changed is diffracted in the auxiliary intermediate diffraction optical elements 132a and 132b in the horizontal direction ( 3 and 5 reference y-axis direction) in the main direction, the main intermediate diffractive optical element 131 and the auxiliary intermediate diffractive optical elements 132a and 132b are in the vertical direction of the optical guide unit 110 Are separated from each other along the line, and in particular, since the extension direction of the auxiliary intermediate diffraction optical elements 132a and 132b is inclined with respect to the extension direction of the main intermediate diffraction optical element 131, the horizontal direction is changed for at least two optical path changes as described above. Compared to the case of using a single intermediate diffractive optical element having a length extending in a lengthwise direction and a width extending in a lengthwise direction, there is an advantage in that the number of times the grating line is encountered while the light travels is reduced. Accordingly, there is an advantage in that it is possible to minimize the optical path being turned into an unintended path whenever the traveling light meets the grid line.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the scope of the appended claims will include such modifications or variations as long as they fall within the gist of the present invention.

100: diffraction light guide plate
110: optical guide part
120: input diffraction optical element
131: main intermediate diffraction optical element
132a: first auxiliary intermediate diffraction optical element
132b: second auxiliary intermediate diffraction optical element
140: output diffraction optical element
150: light blocking layer
200: light source
1000, 2000: display device

Claims (8)

A light guide part for guiding light;
An input diffraction optical element that receives light from a light source and diffracts the received light so that the received light can be guided on the light guide unit;
An intermediate diffraction optical element configured to receive the light diffracted from the input diffraction optical element and to allow the received light to be expanded one-dimensionally by diffraction; And
And an output diffraction optical element configured to receive the expanded light from the intermediate diffraction optical element and to output the received light from the optical guide unit by diffraction,
The intermediate diffraction optical element and the output diffraction optical element are separately disposed in regions separated from each other along the horizontal direction on the optical guide unit,
The intermediate diffraction optical element includes a main intermediate diffraction optical element and a plurality of auxiliary intermediate diffraction optical elements that are spaced apart from each other in a vertical direction on the optical guide part,
The main intermediate diffraction optical element is optically coupled to the input diffraction grating through the optical guide unit to direct diffracted light received from the input diffraction grating toward the auxiliary intermediate diffraction optical element by diffraction,
A first auxiliary intermediate diffractive optical element disposed adjacent to the main intermediate diffractive optical element among the plurality of auxiliary intermediate diffractive optical elements is optically coupled to the main intermediate diffractive optical element through the optical guide unit, and the main intermediate diffractive optical element The diffracted light received from the light is directed toward the output diffraction optical element by diffraction, and the second auxiliary intermediate diffractive optical element disposed adjacent to the first auxiliary intermediate diffractive optical element is the first auxiliary intermediate diffractive optical element through the optical guide unit. The diffractive light guide plate, which is optically coupled to the first auxiliary intermediate diffraction optical element to receive light that has not been diffracted toward the output diffraction optical element and directs it to the output diffraction optical element by diffraction. The method of claim 1,
The diffractive light guide plate, wherein the extension direction of the auxiliary intermediate diffractive optical element is inclined with respect to the extension direction of the main intermediate diffractive optical element. The method of claim 2,
The first auxiliary intermediate diffractive optical element and the second auxiliary intermediate diffractive optical element have respective extension directions parallel to each other. The method of claim 1,
The diffraction light guide plate of the main intermediate diffraction optical element gradually increasing a diffraction rate from one side to the other side along the extension direction. The method of claim 1,
The auxiliary intermediate diffractive optical element has the same diffraction rate from one side to the other along the extending direction thereof. The method of claim 5,
The diffraction light guide plate, wherein a diffraction rate of the second auxiliary intermediate diffraction optical element is higher than that of the first auxiliary intermediate diffraction optical element. The method of claim 1,
The intermediate diffraction optical element is disposed on one side of the optical guide unit,
A diffractive light guide plate, wherein a reduction unit for reducing a light-receiving rate of external light other than the light output from the light source is disposed in a region corresponding to a region in which the intermediate diffractive optical element is located on one side or the other side of the optical guide unit. A light source that outputs image light forming an image; And
A display device comprising the diffractive light guide plate according to any one of claims 1 to 7.

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