JP4627334B1 - Stereoscopic image display device - Google Patents

Abstract

The advantages of both glasses-type and naked-eye type devices can be obtained without switching or the like.
The first display unit 7 and the second display unit 11 have light-shielding areas BR2 and BR1 formed on both sides of the center line because the light sources are arranged asymmetrically. When the person is positioned, only the right-eye image is observed with the observer's right eye ER, and only the left-eye image is observed with the observer's left eye EL. As a result, at the positions of the light shielding regions BR2 and BR1, a stereoscopic image can be observed even if the observer faces the stereoscopic image display device 1 with the naked eye. On the other hand, in the areas other than the light shielding areas BR2 and BR1, the right-eye image and the left-eye image are mixed. When applied, the same stereoscopic image can be observed simultaneously by a plurality of observers.
[Selection] Figure 6

Description

  The present invention relates to a stereoscopic image display apparatus that inputs an image having binocular parallax separately to the left and right eyes of an observer and recognizes it as a stereoscopic image.

  Conventionally, as this type of apparatus, there is a so-called “glasses type” stereoscopic image display apparatus. Specifically, for example, from a first image display unit with a display surface facing the observer, and a second image display unit arranged in a posture orthogonal to the display surface of the first image display unit An image display unit in which a pair of image display units are arranged in an L shape, and a half mirror arranged in an inclined posture from a corner of the image display unit (for example, see Patent Document 1). .

  In this “glasses-type” stereoscopic image display device, for example, a left-eye image is displayed on the first image display unit, and a right-eye image is displayed on the second image display unit. A part of the light emitted from the first image display unit is reflected by the half mirror, but the remaining light passes through the half mirror and travels toward the observer. Although a part of the light emitted from the second image display unit is transmitted, the rest is reflected and travels toward the observer. The light reflected by the half mirror is made to have a polarization state different from that of the transmitted light, so that different images can be observed with the left and right eyes by the observer wearing glasses with different polarization characteristics on the left and right. A stereoscopic image can be observed.

  As another device, there is a so-called “naked eye” stereoscopic image display device. Specifically, for example, the first image display unit facing the viewer and the first field selection glass that limits the viewing angle, and the posture orthogonal to the display surface of the first image display unit An image display unit in which a pair of image display units each including a second image display unit and a second field selection glass that limits the viewing angle are arranged in an L shape, and the image display unit And a half mirror disposed in an inclined posture from the corner (see, for example, Patent Document 2).

  In this “naked eye type” apparatus, since the viewing angle is limited, the stereoscopic vision is possible without the observer wearing glasses as in the above “glasses type” apparatus.

JP 2000-338449 A Japanese Patent Laid-Open No. 09-90276

However, the conventional example having such a configuration has the following problems.
That is, among the conventional apparatuses, the “glasses type” apparatus has a problem that it is troublesome to wear glasses although it is possible for a plurality of observers to perform stereoscopic viewing by wearing glasses. On the other hand, the “naked eye type” has no problem of wearing glasses, but has a limited field of view, and thus has another problem that stereoscopic viewing by a plurality of observers is difficult. Therefore, there is a problem that it is not possible to enjoy the advantages of both “glasses type” and “naked eye type”.

  The present invention has been made in view of such circumstances, and a stereoscopic image display device that can enjoy the advantages of both the “glasses type” and “naked eye type” devices without switching or the like. The purpose is to provide.

  In order to achieve such an object, the present invention has the following configuration.

That is, the invention according to claim 1 is a stereoscopic image display device that displays a stereoscopic image.
Includes a first image display means for displaying one image for the right eye and the left eye image and a second image display means for displaying the other image for the right eye and the left eye image, An image display unit in which the first image display means and the second image display means are arranged in a posture forming a corner;
A half that is arranged in an inclined posture from the corner of the image display unit, reflects light from the first image display means to the viewer side, and transmits light from the second image display means to the viewer side. Mirror,
The first image display unit is disposed on the back surface of the first image display unit, has one focal point on the back side of the first image display unit, and the other focal point is set between the eyes of the observer . Condensing means;
A first light source unit that is directed to the first light collecting unit and emits light asymmetrically across one focal point of the first light collecting unit in plan view;
The second image display unit is disposed on the back surface of the second image display unit, has one focal point on the back side of the second image display unit, and the other focal point set between both eyes of the observer . Condensing means;
A second light source unit that is directed to the second light collecting unit and emits light asymmetrically across one focal point of the second light collecting unit in plan view;
With
On the viewer side, a mixed area where both the light from the first image display means and the second image display means reach, a first area where only the light from the first image display means reaches, And a second region where only the light of the second image display means reaches.

  [Operation / Effect] According to the first aspect of the present invention, the mixed area where the light from the first image display means and the second image display means constituting the image display unit reaches both via the half mirror; A first region that is reflected by the half mirror and only light from the first image display means reaches, and a second region that transmits only the light from the second image display means through the half mirror are formed. When the observer is positioned so that the eyes are positioned in the first region and the second region, only the right eye image can be observed with the right eye, and only the left eye image can be observed with the left eye. Stereoscopic viewing is possible with the naked eye. Further, even if the first image display means and the second image display means are in the same polarization state, the light from the first image display means reflected by the half mirror is the light from the second image display means. It becomes a different polarization state. Therefore, in the mixed region, the same stereoscopic image can be simultaneously observed by a plurality of observers by the observer wearing glasses with different polarizations for the right eye and the left eye. As a result, it is possible to enjoy the advantages of both the naked eye type and the glasses type device without performing an operation such as switching on the stereoscopic image display device side.

The invention according to claim 2 is a stereoscopic image display device for displaying a stereoscopic image.
Includes a first image display means for displaying one image for the right eye and the left eye image and a second image display means for displaying the other image for the right eye and the left eye image, An image display unit in which the first image display means and the second image display means are arranged in a posture forming a corner;
A half that is arranged in an inclined posture from the corner of the image display unit, reflects light from the first image display means to the viewer side, and transmits light from the second image display means to the viewer side. Mirror,
The ellipse is arranged on the back side of the first image display means, is a part of an elliptical arc, and has a symmetrical reflecting surface with a center line in plan view, and one focal point of the ellipse is on the reflecting surface side A first elliptical mirror having the other focus of the ellipse set between the eyes of the observer;
The second image display means is disposed on the back side of the second image display means and includes a reflection surface that is a part of an elliptical arc and is symmetrical with respect to the center line in plan view. A second elliptical mirror having the other focus of the ellipse set between the eyes of the observer;
In a posture to irradiate light on the reflection surface of the first elliptical mirror, it is attached to the back side of the first image display means, and is provided across one focal point of the first elliptical mirror in plan view. Among the pair of light sources, one of the pair of light sources as viewed from the observation side emits light from the center line to the outside, and the other light source as viewed from the observation side is predetermined from the center line to the outside. A first light source unit that emits light from a position apart from the distance;
In a posture to irradiate light on the reflecting surface of the second elliptical mirror, the second elliptical mirror is attached to the back side of the second image display unit, and is provided across one focal point of the second elliptical mirror in plan view. Among the pair of light sources, one of the pair of light sources as viewed from the observation side emits light from the center line to the outside, and the other light source as viewed from the observation side is predetermined from the center line to the outside. A second light source unit that emits light from a position away from the distance;
It is characterized by having.

  [Operation / Effect] According to the invention described in claim 2, the light emitted from the pair of light sources of the first light source unit is reflected by the first elliptical mirror and travels to the first image display means. Only the other light source is configured such that the outside emits light from a position away from the center line by a predetermined distance, and the light irradiating region is asymmetric between one light source and the other light source. Accordingly, in the vicinity of the other focal point on the viewer side, there is a region where the light does not reach the region irradiated with the light from the other light source. Similarly, the light emitted from the pair of light sources of the second light source unit is reflected by the second elliptical mirror and travels to the second image display means, but one light source and the other light source irradiate light. The area is asymmetric. Therefore, on the viewer side who observes the image display unit through the half mirror, there is a region where light is not irradiated on each of the left and right sides. Therefore, if the viewer is located in a region where the light does not reach, light from the first light source unit is generated. Is incident on only one eye, and the light from the second light source unit is incident only on the other eye. As a result, at this position, the observer can perform stereoscopic viewing with the naked eye.

  On the other hand, the light from the first light source unit and the second light source unit is mixed outside the area where the light does not reach, but the light from the first image display means reflected by the half mirror is the second image. It becomes a polarization state different from the light from the display means. Therefore, the same stereoscopic image can be simultaneously observed by a plurality of observers by the observer wearing glasses with different polarizations for the right eye and the left eye. As a result, it is possible to enjoy the advantages of both the naked eye type and the glasses type device without performing an operation such as switching on the stereoscopic image display device side.

According to a third aspect of the present invention, there is provided a stereoscopic image display device that displays a stereoscopic image.
Includes a first image display means for displaying one image for the right eye and the left eye image and a second image display means for displaying the other image for the right eye and the left eye image, An image display unit in which the first image display means and the second image display means are arranged in a posture forming a corner;
A half that is arranged in an inclined posture from the corner of the image display unit, reflects light from the first image display means to the viewer side, and transmits light from the second image display means to the viewer side. Mirror,
The first image display unit is disposed on the back side of the first image display unit, has one focal point on the back side of the first image display unit, and the other focal point is set between the eyes of the observer. A cylindrical convex lens,
The second image display unit is disposed on the back side of the second image display unit, has one focal point on the back side of the second image display unit, and the other focal point is set between the eyes of the observer. A cylindrical convex lens,
A pair of light sources attached to the back side of the first cylindrical convex lens in a posture to irradiate light to the first cylindrical convex lens and sandwiching one focal point of the first cylindrical convex lens in plan view Among the pair of light sources, one light source viewed from the observation side emits light from the center line to the outside, and the other light source viewed from the observation side is located at a predetermined distance from the center line to the outside. A first light source unit that emits light from the outside,
A pair of light beams is provided on the back side of the second image display means in a posture to irradiate light to the second cylindrical convex lens, and is provided across one focal point of the second cylindrical convex lens in plan view. One of the pair of light sources as viewed from the observation side emits light from the center line to the outside, and the other light source as viewed from the observation side is separated from the center line by a predetermined distance. A second light source unit that emits light outside from the position;
It is characterized by having.

  [Operation and Effect] According to the invention described in claim 3, the light emitted from the pair of light sources of the first light source unit is refracted by the first cylindrical convex lens and travels to the first image display means. Only the other light source is configured such that the outside emits light from a position away from the center line by a predetermined distance, and the light irradiating region is asymmetric between one light source and the other light source. Accordingly, in the vicinity of the other focal point on the viewer side, there is a region where the light does not reach the region irradiated with the light from the other light source. Similarly, the light emitted from the pair of light sources of the second light source unit is refracted by the second cylindrical convex lens and travels toward the second image display means, but one light source and the other light source irradiate light. The area is asymmetric. Therefore, on the viewer side who observes the image display unit through the half mirror, there is a region where light is not irradiated on each of the left and right sides. Therefore, if the viewer is located in a region where the light does not reach, light from the first light source unit is generated. Is incident on only one eye, and the light from the second light source unit is incident only on the other eye. As a result, at this position, the observer can perform stereoscopic viewing with the naked eye.

  On the other hand, the light from the first light source unit and the second light source unit is mixed except in the area where the light does not reach, but the light from the first light source unit and the second light source unit is mixed. The light from the first image display means reflected by the mirror is in a polarization state different from that of the light from the second image display means. Therefore, the same stereoscopic image can be simultaneously observed by a plurality of observers by the observer wearing glasses with different polarizations for the right eye and the left eye. As a result, the advantages of both the naked eye type and the eyeglass type device can be enjoyed with a relatively simple optical system configuration without performing a switching operation or the like on the stereoscopic image display device side.

  In the present invention, it is preferable that the light sources on the other side of the first light source unit and the second light source unit include a light emitting unit provided from the position away from the center line to the outside by a predetermined distance. Claim 4).

  Since the other light source may be a light emitting part shorter than the light emitting part of one light source, the light source unit can be reduced in weight.

  Further, in the present invention, the light source on the other side of the first light source unit and the second light source unit includes a light emitting portion provided from the center line to the outside, and from the center line to a position away from the center line by a predetermined distance. Is preferably shielded from light (claim 5).

  The same light source can be used for one light source and the other light source, and the cost can be reduced by sharing the members.

  In the present invention, it is preferable that the image display unit includes the first image display unit and the second image display unit in an L shape in plan view.

In the present invention, the image display unit includes the first image display unit and the second image display unit in an L shape in a side view,
The half mirror is provided at the tip end downward from the corner side,
The first light source unit and the second light source unit are each provided with a pair of light sources on each upper part and are arranged with the upper parts facing the corners,
In the first light source unit and the second light source unit, a pair of light sources are provided in the same positional relationship in a front view of each of the first image display unit and the second image display unit. (Claim 7).

  Since the same thing can be employ | adopted by a 1st image display means and a 1st light source unit, and a 2nd image display means and a 2nd light source unit, apparatus cost can be reduced.

In the present invention, the image display unit includes the first image display unit and the second image display unit in an L shape in a side view,
The half mirror is provided at the tip end downward from the corner side,
It is preferable that one of the first light source unit and the second light source unit has a pair of light sources in the upper part and the other has a pair of light sources in the lower part and the upper parts are arranged with the corners facing each other. (Claim 8).

  According to the stereoscopic image display device according to the present invention, the light from the first image display means and the second image display means constituting the image display unit both reach through the half mirror, and is reflected by the half mirror. Thus, a first area where only the light from the first image display means reaches and a second area where only the light from the second image display means reaches through the half mirror are formed. When the observer is positioned so that the eyes are positioned in the first region and the second region, only the right eye image can be observed with the right eye, and only the left eye image can be observed with the left eye. Stereoscopic viewing is possible with the naked eye. Further, even if the first image display means and the second image display means are in the same polarization state, the light from the first image display means reflected by the half mirror is the light from the second image display means. It becomes a different polarization state. Therefore, in the mixed region, the same stereoscopic image can be simultaneously observed by a plurality of observers by the observer wearing glasses with different polarizations for the right eye and the left eye. As a result, it is possible to enjoy the advantages of both the naked eye type and the glasses type device without performing an operation such as switching on the stereoscopic image display device side.

1 is a plan view illustrating a schematic configuration of a stereoscopic image display apparatus according to Embodiment 1. FIG. It is a longitudinal cross-sectional view which shows the principal part of a 2nd display unit (1st display unit). It is a schematic diagram which shows the optical path by the 1st light source in a 2nd display unit. It is a schematic diagram which shows the optical path by the 2nd light source in a 2nd display unit. It is a schematic diagram which shows the optical path by the light source unit for left eyes in a 2nd display unit. It is a figure where it uses for description of the observation state of the stereoscopic vision by a stereoscopic image display apparatus. It is a front view which shows the modification of the light source unit for left eyes. It is a schematic diagram which shows an example of the attachment aspect of an image display unit and a light source. It is a schematic diagram which shows the other example of the attachment aspect of an image display unit and a light source. 6 is a plan view illustrating a schematic configuration of a stereoscopic image display apparatus according to Embodiment 2. FIG.

  Each embodiment of the stereoscopic image display device will be described below.

Embodiment 1 of the present invention will be described below with reference to the drawings.
1 is a plan view illustrating a schematic configuration of the stereoscopic image display apparatus according to the first embodiment, and FIG. 2 is a longitudinal sectional view illustrating a main part of a second display unit (first display unit).

  The stereoscopic image display apparatus 1 according to the present embodiment displays a stereoscopic image by displaying a left-eye image and a right-eye image. The stereoscopic image display device 1 includes an image display unit 3. The image display unit 3 includes a first display unit 7 that includes a first image display unit 5 that displays a right-eye image, and a second display unit that includes a second image display unit 9 that displays a left-eye image. 11. In the present embodiment, the first image display unit 5 and the second image display unit 9 are arranged so as to form corners. More specifically, it is arranged in an L-shaped posture in plan view, and a surface on which an image is displayed takes a vertical posture. A specific configuration of the first image display unit 5 and the second image display unit 9 includes, for example, a transmissive liquid crystal display panel.

  The first image display unit 5 described above corresponds to the “first image display unit” in the present invention, and the second image display unit 9 corresponds to the “second image display unit” in the present invention.

  Between the first image display unit 5 and the second image display unit 9, from the corner to the diagonal part on the opposite side to the corner of the first image display unit 5 and the second image display unit 9. The half mirror 13 is provided in an inclined posture. The half mirror 13 reflects the right eye image displayed on the first image display unit 5 and transmits the left eye image displayed on the second image display unit 9. Each image is directed to the viewer (shown as right eye ER and left eye EL in the figure).

  In the present embodiment, since the first display unit 7 and the second display unit 11 provided in the image display unit 3 have the same configuration, the configuration will be described in detail below mainly using the second display unit 11 as an example. To do.

  The second display unit 11 includes an elliptical mirror 15 on the back side of the second image display unit 9. The elliptical mirror 15 is a part of an elliptical arc, and includes a reflective surface 17 having a symmetrical shape across a center line in plan view. The elliptical mirror 15 has one focal point of the ellipse on the reflection surface 17 side, and the other focal point of the ellipse is set between the eyes of the observer (right eye ER and left eye EL). Specifically, one focal point is in the vicinity of the end of the first light source 25 on the center line described later.

  A left eye light source unit 19 is provided on the back side of the second image display unit 9. The light source unit 19 for the left eye includes a pair of light sources 21 for the left eye that sandwiches one focal point of the elliptical mirror 15 in a plan view in a posture to irradiate the reflection surface 17 of the elliptical mirror 11. Of the pair of light sources 21 for the left eye, the first light source 25 on one side (right side) as viewed from the observation side has a length that emits light from the center line to the outside, and the other side as viewed from the observation side ( The second light source 27 on the left side has such a length that only the outside emits light from a position away from the center line by a predetermined distance d. This predetermined distance d is, for example, about half of the length of the first light source 25. The first light source 25 has a light emitting part longer than the second light source 27, and the second light source 27 has a light emitting part having a length separated outward by a predetermined distance d.

  Thus, since the light source shorter than the 1st light source 25 is utilized as the 2nd light source 27, the weight reduction of the light source unit 19 for left eyes can be achieved.

Next, the first image display unit 7 will be briefly described.
The first image display unit 7 includes a first image display unit 5, an elliptical mirror 29, a reflecting surface 31, a right eye light source unit 33, a pair of right eye light sources 35, and a first light source 39. The second light source 41 is provided. Each configuration is the same as that of the second image display unit 11 described above. The first image display unit 5 emits light having the same polarization characteristic as that of the second image display unit 9 described above. Examples of the polarization characteristic include a linear polarization characteristic at an oblique angle of 45 degrees and a circular polarization characteristic.

  The elliptical mirror 29 described above corresponds to the “first condensing unit” in the present invention, and the elliptical mirror 15 corresponds to the “second condensing unit” in the present invention. The right-eye light source unit 33 described above corresponds to a “first light source unit” in the present invention, and the left-eye light source unit 35 corresponds to a “second light source unit” in the present invention.

  Reference is now made to FIGS. FIG. 3 is a schematic diagram showing an optical path by the first light source in the second display unit, FIG. 4 is a schematic diagram showing an optical path by the second light source in the second display unit, and FIG. It is a schematic diagram which shows the optical path by the light source unit for left eyes in a 2nd display unit.

  As shown in FIG. 3, the light emitted from the first light source 25 of the second display unit 11 is reflected by the reflecting surface 17, passes through the second image display unit 9, and is on the observer (not shown) side. Head to. However, since the first light source 25 is provided on the right side, the light is biased from the center line to the left side.

  As shown in FIG. 4, the light emitted from the second light source 27 of the second display unit 11 is reflected by the reflecting surface 17, passes through the second image display unit 9, and is viewed by an observer (not shown). ) Head to the side. However, since the second light source 27 is provided on the left side, the light is biased from the center line to the right side. In addition, unlike the first light source 25, the second light source 27 emits light only from the outside from a portion that is a predetermined distance d from the center line. Therefore, on the viewer side, a light blocking region BR2 (second region) is generated in which light does not reach the right side (the viewer's right eye ER side) from the center line.

  Therefore, when the left-eye light source unit 19 (the first light source 25 and the second light source 27) is turned on, the optical path overlaps FIG. 3 and FIG. 4 because they are arranged asymmetrically. It becomes like this. That is, as shown in FIG. 5, the image for the left eye is directed to the observer side. As a result, when the observer faces the stereoscopic image display device 1 so that the observer's right eye ER is positioned in the light-shielding region BR2, only the left-eye image displayed on the second display unit 11 is displayed to the observer. It will be visually recognized by the left eye EL.

  The first display unit 7 has the same configuration as the second display unit 11 described above, and the image is inverted in the left-right direction by the half mirror 13, so the first display unit 7 sandwiches the center line. The light shielding area BR1 (first area) is formed on the left side. Accordingly, as shown in FIG. 6, the first display unit 7 and the second display unit 11 form the light shielding regions BR2 and BR1 on both sides of the center line. Only the image for the right eye is observed with the right eye ER, and only the image for the left eye is observed with the left eye EL of the observer. As a result, at the positions of the light shielding regions BR2 and BR1, a stereoscopic image can be observed even if the observer faces the stereoscopic image display device 1 with the naked eye.

  On the other hand, in the area (mixed area) excluding the light shielding areas BR2 and BR1, the right-eye image and the left-eye image are mixed. However, since the light from the first display unit 7 reflected by the half mirror 13 is in a polarization state different from that of the second display unit 11, glasses with different polarizations are applied to the right eye and the left eye corresponding thereto. Thus, the same stereoscopic image can be simultaneously observed by a plurality of observers.

  As a result, it is possible to enjoy the advantages of both the naked eye type and the glasses type device without performing any switching operation on the stereoscopic image display device 1 side.

  In the first embodiment, the light emitted from the first image display unit 5 and the second image display unit 9 has the same polarization characteristics, for example, the linear polarization characteristic and the circular polarization characteristic of 45 degrees obliquely. The polarization characteristics of the display unit 5 and the second image display unit 9 may be different polarization characteristics such as horizontal and vertical linear polarization or vice versa. Since the polarization characteristics of the horizontal and vertical linear polarization characteristics do not change due to reflection and transmission by the half mirror, polarization glasses corresponding to these polarization states may be used. Furthermore, the polarization characteristics of the first image display unit 5 and the second image display unit 9 are the same for horizontal or vertical linearly polarized light, and a half-wave plate or a phase difference plate is disposed in front of one of the image display units. However, one polarization axis may be rotated by 90 degrees.

(Modification of light source unit)
In the first embodiment described above, the light emitting portions of the second light source 27 of the left eye light source unit 19 and the right eye light source unit 33 are configured to be shorter than the light emitting portion of the first light source 25. However, a configuration as shown in FIG. 7 may be adopted. FIG. 7 is a front view showing a modification of the light source unit for the left eye. In the following description, the light source unit 19 for the left eye is taken as an example, but the same applies to the light source unit 33 for the right eye.

  That is, the pair of light sources 21 for the left eye may be configured by the first light source 25 and the second light source 27A, and thereby the left eye light source unit 19 may be configured. The second light source 27 </ b> A is composed of the same light source as the first light source 25. That is, the light emitting part of the same length is provided. Further, in the second light source 27 </ b> A, a range of a predetermined distance d from the center line is covered with a light shielding member 51. Even if the left-eye light source unit 19 and the right-eye light source unit 33 are configured in this way, the same operational effects as described above are obtained.

  In addition, the first light source 25 and the second light source 27A can share the same member, thereby reducing the cost of the apparatus.

(Arrangement variation)
In Example 1 mentioned above, the 1st display unit 7 and the 2nd display unit 11 are arrange | positioned so that L shape may be exhibited in planar view, and the image display unit 3 is comprised. However, it may be arranged as shown in FIG. 8 or FIG. FIG. 8 is a schematic diagram illustrating an example of an attachment mode of the image display unit and the light source, and FIG. 9 is a schematic diagram illustrating another example of an attachment mode of the image display unit and the light source. In FIGS. 8 and 9, the elliptical mirror 15 and the like are not shown because of the illustration.

Please refer to FIG.
In the stereoscopic image display apparatus 1A of this example, the first display unit 7 and the second display unit 11 are configured to have an L shape in a side view. The half mirror 13 is provided in a posture in which the tip part is lowered from the corner part. Further, the first display unit 7 and the second display unit 11 are arranged with the respective light source units (the left-eye light source unit 19 and the right-eye light source unit 33) facing the corners. In this case, the first display unit 7 and the second display unit 11 can have exactly the same configuration. Therefore, the apparatus cost can be reduced by the common configuration.

Please refer to FIG.
In the stereoscopic image display device 1B of this example, the orientation of the first display unit 7 is different from the above-described stereoscopic image display device 1A. That is, the first display unit 7 includes the right eye light source unit 33 on the side opposite to the corner. Even if comprised in this way, there can exist an effect similar to the above.

  In the first embodiment, the optical paths of the elliptical mirrors 15 and 29 are in the air (only air without an optical material), but may be configured to be filled with a light transmitting material. As a result, it is possible to suppress deterioration over time such as cloudiness that may occur on the reflection surfaces 17 and 31.

  In the first embodiment, the light source is provided only on the upper side as shown in FIG. 2, but the light source may be provided only on the lower side. Further, light sources may be provided on both upper and lower sides. Thereby, the brightness | luminance of a stereo image can be raised.

Next, Embodiment 2 of the present invention will be described with reference to the drawings.
FIG. 10 is a plan view illustrating a schematic configuration of the stereoscopic image display apparatus according to the second embodiment.

  The stereoscopic image display apparatus 1C according to the second embodiment is different from the first embodiment described above in that it does not include a reflection system such as an elliptical mirror. In addition, about the structure which is common in Example 1 mentioned above, detailed description is abbreviate | omitted by attaching | subjecting a same sign.

  The stereoscopic image display device 1 </ b> C includes a first display unit 7 and a second display unit 11 that constitute the image display unit 3. However, the first display unit 7 includes a cylindrical convex lens 61 on the back side of the first image display unit 5, and the second display unit 11 includes a cylindrical convex lens 63 on the back side of the second image display unit 9. These cylindrical convex lenses 61 and 63 have a length in the paper plane, and one focal point is on the back side of the first image display unit 5 or the second image display unit 9, and on the back side of the cylindrical convex lenses 61 and 63. And the other focus is set between both sides of the observer.

  The cylindrical convex lens 63 corresponds to the “first condensing unit” in the present invention, and the cylindrical convex lens 61 corresponds to the “second condensing unit” in the present invention.

  The first display unit 7 includes a right eye light source unit 33 on the back side of the cylindrical convex lens 61, and the second display unit 11 includes a left eye light source light source unit 19 on the back side of the cylindrical convex lens 63. The configurations of the right-eye light source unit 33 and the left-eye light source unit 19 are substantially the same as those of the first embodiment described above, and are configured in an asymmetric arrangement with the center line interposed therebetween.

  In the stereoscopic image display device 1 </ b> C having such a configuration, the light shielding area BR <b> 2 is generated by the second display unit 11, and the light shielding area BR <b> 1 is generated by the first display unit 7. Therefore, the same effect can be obtained while the optical system has a relatively simple configuration as compared with the first embodiment.

  In the second embodiment, similarly to the first embodiment described above, a modification example of the optical unit and a modification example of the arrangement can be employed.

  The present invention is not limited to the above-described embodiment, and can be modified as follows.

  (1) In the first and second embodiments described above, a transmissive liquid crystal display is used as the first image display unit 5 corresponding to the first image display unit and the second image display unit 9 corresponding to the second image display unit. Although the panel is illustrated, the present invention is not limited to the liquid crystal display type, and the present invention can be applied to any transmissive display panel. For example, transmissive MEMS (microelectro mechanical systems) can be mentioned. In the case of a transmissive liquid crystal display panel, the polarization characteristics are determined by the built-in polarizing plate. However, in the case of a transmissive MEMS, since the polarizing plate is not built in, for example, a polarizing unit that gives a predetermined polarization characteristic. Is preferably provided on the light exit surface of the light source of each image display unit or on the front surfaces of the first image display unit 5 and the second image display unit 9.

  (2) In each of the above-described embodiments, it is preferable that a vertical diffusion plate that diffuses light in the vertical direction is provided on the back side of the first image display unit 5 and the second image display unit 9. As a result, it is possible to suppress uneven brightness of the image due to the light emission shapes of the first light source 25 and the second light source 27.

  (3) In each of the first and second embodiments described above, the first light source 25 and the second light source 27 are configured as separate light sources, and the first light source 39 and the second light source 41 are separately configured. It consists of a light source. However, since it is sufficient that they are always turned on, the first light source 25 and the second light source 27 are configured as an integrated light source, and the first light source 39 and the second light source 41 are configured as an integrated light source. However, a configuration in which a part is shielded may be employed. Further, for example, a plurality of small light sources (for example, light emitting diodes) may be arranged in a planar shape to configure each light source, and a part of the small light sources may be turned off.

  (4) The present invention is not limited to the first and second embodiments described above, and the light from the first image display unit 5 and the second image display unit 9 constituting the image display unit 3 is reflected by the half mirror 13. A mixed region that reaches both via the first mirror, a first region that is reflected by the half mirror 13 and only receives light from the first image display unit 5, and only the light from the second image display unit 9 that passes through the half mirror 13. Any structure may be used as long as it forms the second region to which the light reaches.

  (5) In each of the first and second embodiments described above, the right-eye image is reflected by the half mirror 13 and the left-eye image is transmitted through the half mirror 13. However, in the present invention, these are reversed. Even can be applied.

  (6) Although the elliptical mirrors 15 and 29 are used in the first embodiment described above, a Fresnel mirror may be used instead. Thereby, the depth of the 1st display unit 7 and the 2nd display unit 11 can be suppressed, and size reduction can be achieved.

DESCRIPTION OF SYMBOLS 1,1A, 1B, 1C ... Three-dimensional image display apparatus 3 ... Image display unit 5 ... 1st image display part 7 ... 1st display unit 9 ... 2nd image display part 11 ... 2nd display unit 13 ... Half mirror ER ... Right Eye EL ... Left eye 15, 29 ... Elliptical mirror 17, 31 ... Reflecting surface 19 ... Light source unit for left eye 21 ... A pair of light sources for left eye 23, 37 ... Polarization unit 25, 39 ... First light source 27, 41 ... Second light source BR1 ... Light-shielding region (right eye)
BR2: Shading area (left eye)
33 ... Light source unit for right eye 35 ... A pair of light sources for right eye 51 ... Light shielding member

Claims (8)

In a stereoscopic image display device that displays a stereoscopic image,
Includes a first image display means for displaying one image for the right eye and the left eye image and a second image display means for displaying the other image for the right eye and the left eye image, An image display unit in which the first image display means and the second image display means are arranged in a posture forming a corner;
A half that is arranged in an inclined posture from the corner of the image display unit, reflects light from the first image display means to the viewer side, and transmits light from the second image display means to the viewer side. Mirror,
The first image display unit is disposed on the back surface of the first image display unit, has one focal point on the back side of the first image display unit, and the other focal point set between both eyes of the observer . Condensing means;
A first light source unit that is directed to the first light collecting unit and emits light asymmetrically across one focal point of the first light collecting unit in plan view;
The second image display unit is disposed on the rear surface of the second image display unit, has one focal point on the rear side of the second image display unit, and the other focal point is set between both eyes of the observer Condensing means;
A second light source unit that is directed to the second light collecting unit and emits light asymmetrically across one focal point of the second light collecting unit in plan view;
With
On the viewer side, a mixed area where both the light from the first image display means and the second image display means reach, a first area where only the light from the first image display means reaches, A stereoscopic image display device, wherein the second image display means forms a second region to which only light from the second image display means reaches. In a stereoscopic image display device that displays a stereoscopic image,
Includes a first image display means for displaying one image for the right eye and the left eye image and a second image display means for displaying the other image for the right eye and the left eye image, An image display unit in which the first image display means and the second image display means are arranged in a posture forming a corner;
A half that is arranged in an inclined posture from the corner of the image display unit, reflects light from the first image display means to the viewer side, and transmits light from the second image display means to the viewer side. Mirror,
The ellipse is arranged on the back side of the first image display means, is a part of an elliptical arc, and has a symmetrical reflecting surface with a center line in plan view, and one focal point of the ellipse is on the reflecting surface side A first elliptical mirror having the other focus of the ellipse set between the eyes of the observer;
The second image display means is disposed on the back side of the second image display means and includes a reflection surface that is a part of an elliptical arc and is symmetrical with respect to the center line in plan view. A second elliptical mirror having the other focus of the ellipse set between the eyes of the observer;
In a posture to irradiate light on the reflection surface of the first elliptical mirror, it is attached to the back side of the first image display means, and is provided across one focal point of the first elliptical mirror in plan view. Among the pair of light sources, one of the pair of light sources as viewed from the observation side emits light from the center line to the outside, and the other light source as viewed from the observation side is predetermined from the center line to the outside. A first light source unit that emits light from a position apart from the distance;
In a posture to irradiate light on the reflecting surface of the second elliptical mirror, the second elliptical mirror is attached to the back side of the second image display unit, and is provided across one focal point of the second elliptical mirror in plan view. Among the pair of light sources, one of the pair of light sources as viewed from the observation side emits light from the center line to the outside, and the other light source as viewed from the observation side is predetermined from the center line to the outside. A second light source unit that emits light from a position away from the distance;
A stereoscopic image display device comprising: In a stereoscopic image display device that displays a stereoscopic image,
Includes a first image display means for displaying one image for the right eye and the left eye image and a second image display means for displaying the other image for the right eye and the left eye image, An image display unit in which the first image display means and the second image display means are arranged in a posture forming a corner;
A half that is arranged in an inclined posture from the corner of the image display unit, reflects light from the first image display means to the viewer side, and transmits light from the second image display means to the viewer side. Mirror,
The first image display unit is disposed on the back side of the first image display unit, has one focal point on the back side of the first image display unit, and the other focal point is set between the eyes of the observer. A cylindrical convex lens,
The second image display unit is disposed on the back side of the second image display unit, has one focal point on the back side of the second image display unit, and the other focal point is set between the eyes of the observer. A cylindrical convex lens,
A pair of light sources attached to the back side of the first cylindrical convex lens in a posture to irradiate light to the first cylindrical convex lens and sandwiching one focal point of the first cylindrical convex lens in plan view Among the pair of light sources, one light source viewed from the observation side emits light from the center line to the outside, and the other light source viewed from the observation side is located at a predetermined distance from the center line to the outside. A first light source unit that emits light from the outside,
A pair of light beams is provided on the back side of the second image display means in a posture to irradiate light to the second cylindrical convex lens, and is provided across one focal point of the second cylindrical convex lens in plan view. One of the pair of light sources as viewed from the observation side emits light from the center line to the outside, and the other light source as viewed from the observation side is separated from the center line by a predetermined distance. A second light source unit that emits light outside from the position;
A stereoscopic image display device comprising: The stereoscopic image display device according to claim 2 or 3,
The light source on the other side of the first light source unit and the second light source unit includes a light emitting portion provided from the position away from the center line to the outside by a predetermined distance from the outside to the outside. The stereoscopic image display device according to claim 2 or 3,
The light source on the other side of the first light source unit and the second light source unit includes a light emitting portion provided from the center line to the outside, and is shielded from the center line to a position away from the center line by a predetermined distance. A stereoscopic image display device characterized by the above. In the three-dimensional image display apparatus in any one of Claim 1 to 5,
The image display unit includes the first image display unit and the second image display unit in an L shape in plan view. The stereoscopic image display device according to any one of claims 2 to 5,
The image display unit includes the first image display unit and the second image display unit in an L shape in a side view,
The half mirror is provided at the tip end downward from the corner side,
The first light source unit and the second light source unit are each provided with a pair of light sources on each upper part and are arranged with the upper parts facing the corners,
In the first light source unit and the second light source unit, a pair of light sources are provided in the same positional relationship in a front view of each of the first image display unit and the second image display unit. A stereoscopic image display device characterized by the above. The stereoscopic image display device according to any one of claims 2 to 5,
The image display unit includes the first image display unit and the second image display unit in an L shape in a side view,
The half mirror is provided at the tip end downward from the corner side,
One of the first light source unit and the second light source unit is provided with a pair of light sources in the upper part, the other is provided with a pair of light sources in the lower part, and the upper parts are arranged with the corners facing each other. A stereoscopic image display device.

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