JP2017229037A - Display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To display an image which has an appropriate depth to any observer having a different interocular distance, without an arithmetic operation to estimate a complicated depth.SOLUTION: A display device includes: a display unit which mixes and displays a plurality of two-dimensional images which are imaged toward the same direction from each of a plurality of different imaging positions, which are preset beforehand in association with one eyeball of an observer; and a gradation addition unit which sets the luminance of the mixed two dimensional images, which are perceived by the pupil of the eyeball, to have a low luminance, according to a distance from the imaging position associated with each two-dimensional image to the viewpoint position, at an arbitrary viewpoint position of the eyeball which can move in a range determined at the plurality of different imaging positions.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a display device.

  A wearable display device that performs three-dimensional display in consideration of a difference in viewpoint position caused by the interocular distance is known (see, for example, Patent Document 1). In the technique shown in Patent Document 1, a laminated image is displayed for each of the left and right eyes, and a movement parallax is generated by changing the deviation of the laminated image according to the viewpoint position, thereby causing a difference in viewpoint position caused by the interocular distance Correct.

JP 2000-261832 A

  In the technique described in Patent Document 1, it is necessary to generate an image distributed in advance to each layer of the multilayer display that displays the multilayer image. If the depth of the subject for each pixel of the image is known, the distributed image is displayed. It is possible to generate by calculation. However, when displaying a live-action image, the depth is generally not known, and it is not easy to obtain and calculate high-resolution and accurate distance information, so there is a problem that real-time and low-delay imaging display is difficult. .

  In view of the above circumstances, the present invention can display an image having a more appropriate depth for any observer with different interocular distances without performing a calculation for estimating a complex depth. The purpose is to provide.

  One embodiment of the present invention is a display that displays a mixture of a plurality of two-dimensional images captured in the same direction from each of a plurality of different imaging positions determined in advance in association with one of the eyeballs of an observer. And the luminance of each of the mixed two-dimensional images perceived by the pupil of the eyeball at any viewpoint position of the eyeball that can move within a range defined by the plurality of different imaging positions, The display device includes a gradation providing unit configured to reduce luminance according to a distance from the imaging position corresponding to a two-dimensional image to the viewpoint position.

  One aspect of the present invention is the display device described above, in which the gradation providing unit is configured such that the viewpoint position of the eyeball corresponds to any one of the plurality of predetermined different imaging positions. The luminance of the two-dimensional image corresponding to the imaging position is set to the maximum luminance, and the luminance of each of the plurality of two-dimensional images at an arbitrary viewpoint position of the eyeball is determined from the imaging position corresponding to the viewpoint. According to the distance to the position, the luminance is set to a low luminance that is linearly reduced from the maximum luminance.

  One aspect of the present invention is the above-described display device, wherein the gradation providing unit perceives the luminance of each of the plurality of two-dimensional images at an arbitrary viewpoint position of the eyeball with a pupil of the eyeball. It is assumed that the total luminance of the mixed two-dimensional image is constant.

  One aspect of the present invention is the above-described display device, in which the gradation providing unit is configured to change the luminance of each of the plurality of two-dimensional images at an arbitrary viewpoint position of the eyeball from each of the imaging positions. It is set as the brightness | luminance which added the weight acquired based on the distance to a viewpoint position.

  One embodiment of the present invention is the above-described display device, wherein an interval between the plurality of different imaging positions is a distance approximately equal to or less than a diameter of the eyeball.

  One aspect of the present invention is the display device described above, including a plurality of imaging units that are arranged at each of the plurality of different imaging positions and that capture the two-dimensional image, and the display unit includes the plurality of imaging units. Each of the two-dimensional images captured by the imaging unit is mixed and displayed.

  One embodiment of the present invention is the display device, wherein the display unit includes a plurality of liquid crystal panels that display the plurality of two-dimensional images, and the plurality of two-dimensional images displayed on the liquid crystal panel. A backlight for irradiating the liquid crystal panel with light and a lens, and the gradation providing unit adds gradation to the light emitted by the backlight. The luminance is reduced, and the lens is arranged so that the surface to which the gradation is added forms an image at the viewpoint position.

  One embodiment of the present invention is the above-described display device, in which the display unit is a liquid crystal panel stack in which each layer displays each of the two-dimensional images from the plurality of different viewpoint positions.

  According to the present invention, it is possible to display an image having a more appropriate depth for any observer having different interocular distances without performing a calculation for estimating a complicated depth.

It is a block diagram which shows the structure of the display apparatus by 1st Embodiment of this invention. It is a figure which shows the flow which adds the gradation by 1st Embodiment. It is a block diagram which shows the structure of the display apparatus by 2nd Embodiment of this invention. It is FIG. (1) which shows the example of arrangement | positioning of another camera in 2nd Embodiment. It is FIG. (2) which shows the example of arrangement | positioning of another camera in 2nd Embodiment. It is FIG. (3) which shows the example of arrangement | positioning of another camera in 2nd Embodiment. It is a block diagram which shows the structure of the display apparatus by 3rd Embodiment of this invention.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
(First embodiment)
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing the configuration of the display device 1 according to the first embodiment of the present invention and the positional relationship between the display device 1 and one of the left and right eyeballs 100 of the observer. In the following description, the position of the pupil 101 of the observer's eyeball 100 is referred to as the viewpoint position, and the viewpoint position includes the position of the pupil 101 or the vicinity of the pupil 101. The display device 1 is, for example, a head mounted display or a video see-through head mounted display, and includes a plurality of backlights 10 (10-1 and 10-2), a plurality of gradation films 11 (11-1 and 11-2), A plurality of lenses 12 (12-1 and 12-2), a plurality of liquid crystal panels 13 (13-1 and 13-2) and a half mirror 14 are provided.

  Each of the backlights 10-1 and 10-2 emits light. The gradation film 11-1 is a gradation providing unit that modulates the intensity of light emitted from the backlight 10-1 and adds gradation, and is disposed close to the irradiation surface of the backlight 10-1. . The gradation film 11-2 is a gradation providing unit that modulates the luminance of the light emitted from the backlight 10-2 to add gradation, and is disposed close to the irradiation surface of the backlight 10-2. .

  The lens 12-1 is disposed between the gradation film 11-1 and the liquid crystal panel 13-1. The lens 12-2 is disposed between the gradation film 11-2 and the liquid crystal panel 13-2. The lens 12-1 is a lens having a focal length sufficient to form the image of the gradation film 11-1 at the viewpoint position of the eyeball 100. The lens 12-2 is a lens having a focal length sufficient to form an image of the gradation film 11-2 at the viewpoint position of the eyeball 100.

  The liquid crystal panel 13-1 is a display unit that receives a signal from the outside and displays a two-dimensional image, and is close to the front surface of the lens 12-1 between the lens 12-1 and the half mirror 14. Placed in. The liquid crystal panel 13-2 is a display unit that receives a signal from the outside and displays a two-dimensional image, and is close to the front surface of the lens 12-2 between the lens 12-2 and the half mirror 14. Placed in. Here, the two-dimensional images displayed by the liquid crystal panels 13-1 and 13-2 are images of a three-dimensional object from a plurality of different imaging positions determined in advance for one eyeball 100 in the same direction. It is a plurality of two-dimensional images obtained in this way. For example, in the case shown in FIG. 2, the plurality of different imaging positions are two points having a distance between the left end and the right end of the eyeball 100, that is, an interval about the diameter of the eyeball 100, and two two-dimensional images are obtained by imaging. Obtained in advance.

  The half mirror 14 (an example of a mixing unit) constitutes a display unit together with the liquid crystal panels 13-1 and 13-2, and includes a backlight 10-1, a gradation film 11-1, a lens 12-1, and a liquid crystal panel 13-1. The light from the optical system (hereinafter referred to as “first optical system 40-1”) is transmitted to the eyeball 100 side. Further, the half mirror 14 is from the optical system of the backlight 10-2, gradation film 11-2, lens 12-2, and liquid crystal panel 13-2 (hereinafter referred to as “second optical system 40-2”). Is reflected to the eyeball 100 side, and a two-dimensional image displayed on each of the liquid crystal panels 13-1 and 13-2 is mixed and displayed.

  With the configuration of the display device 1, the luminance of the light emitted from the backlight 10-1 is intensity-modulated by the gradation film 11-1, and the light whose luminance is intensity-modulated is the lens 12-1 and the liquid crystal panel 13-1. And the half mirror 14 are transmitted. Thereby, the image of the gradation film 11-1 is formed at the viewpoint position of the eyeball 100. For example, when a certain two-dimensional image is displayed on the liquid crystal panel 13-1, the observer perceives the two-dimensional image with the brightness of the image of the gradation film 11-1 formed at the viewpoint position of the eyeball 100. To do.

  Further, the brightness of the light emitted from the backlight 10-2 is intensity-modulated by the gradation film 11-2, and the light whose intensity is modulated is transmitted through the lens 12-2 and the liquid crystal panel 13-2. Reflected by the half mirror 14. Thereby, the image of the gradation film 11-2 is formed at the viewpoint position of the eyeball 100. For example, when a two-dimensional image is displayed on the liquid crystal panel 13-2, the viewer perceives the image with the brightness of the image of the gradation film 11-2 formed at the viewpoint position of the eyeball 100. That is, the observer uses the left or right eyeball 100 to display an image obtained by mixing the image displayed by the first optical system 40-1 and the image displayed by the second optical system 40-2. You will perceive.

  FIG. 2 shows a state in which the mixing ratio of the two-dimensional images displayed on the liquid crystal panels 13-1 and 13-2 changes due to the change characteristic of the transmittance of the gradation films 11-1 and 11-2 in the display device 1. FIG. FIG. 2 is a view as seen from above the observer, for example, and the upward direction of the drawing corresponds to the right direction of the observer. As the gradation films 11-1 and 11-2, a film whose transmittance changes linearly is applied. The gradation film 11-1 has a maximum transmittance (for example, 100%) at the left end as viewed from the observer, the transmittance decreases toward the right, and the transmittance at the left end is the minimum transmittance (for example, , 0%). The gradation film 11-2 has the maximum transmittance (for example, 100%) at the end as viewed from the observer, the transmittance decreases toward the front, and the transmittance at the tip as viewed from the observer is the minimum transmittance. It arrange | positions so that it may become a rate (for example, 0%).

  When the image of the gradation film 11-1 is formed at the viewpoint position of the eyeball 100 by the lens 12-1, the left and right are switched. That is, the luminance of the image of the gradation film 11-1 formed at the viewpoint position of the eyeball 100 is a linear line indicated by a solid line with the maximum transmittance at the right end, that is, the maximum luminance, and the minimum transmittance at the left end, that is, the minimum luminance. Showing change. On the other hand, the brightness of the image of the gradation film 11-2 reflected by the half mirror 14 and imaged at the viewpoint position of the eyeball 100 by the lens 12-2 has the maximum transmittance at the left end, that is, the maximum brightness, and the right end. Indicates a linear change indicated by a broken line having a minimum transmittance, that is, a minimum luminance.

  As described above, the image of the gradation film 11-1 is formed at the viewpoint position of the eyeball 100 by the lens 12-1. That is, one point on the gradation film 11-1 corresponds to one point imaged at the viewpoint position of the eyeball 100. The light irradiated by the backlight 10-1 that has passed through the one point of the gradation film 11-1 illuminates the entire liquid crystal panel 13-1 that displays the two-dimensional image A, for example. The light passes through the mirror 14 and enters the pupil 101. The observer has the luminance proportional to the transmittance at the one point of the gradation film 11-1, that is, the highest luminance in the vicinity of the right end of the eyeball 100, the luminance decreases linearly toward the left side, and the left end of the eyeball 100 Thus, the entire image A is viewed with the brightness of any value of the brightness changing to the minimum brightness in the vicinity of. That is, when the eyeball 100 of the observer moves to the right (upward in FIG. 2), the image A looks bright, and when it moves to the left (downward in FIG. 2), the image A looks dark.

  Similarly, one point on the gradation film 11-2 corresponds to one point imaged at the viewpoint position of the eyeball 100. The light irradiated by the backlight 10-2 that has passed through the one point of the gradation film 11-2 illuminates the entire liquid crystal panel 13-2 that displays the two-dimensional image B, for example, and passes through the liquid crystal panel 13-2. Then, it is reflected by the half mirror 14 and enters the pupil 101. The observer has a luminance proportional to the transmittance at the one point of the gradation film 11-2, that is, the highest luminance in the vicinity of the left end of the eyeball 100, and the luminance decreases linearly toward the right side. Thus, the entire image B is viewed with the brightness of any value of the brightness that changes to the minimum brightness in the vicinity of. That is, when the observer's eyeball 100 moves to the left (downward in FIG. 2), the image B looks bright, and when it moves to the right (upward in FIG. 2), the image B looks dark.

  The characteristics of the linear change in luminance by the gradation films 11-1 and 11-2 are mixed by the half mirror 14 so that the total luminance of the image A and the image B mixed at the viewpoint position of the eyeball 100 is always constant. It is the characteristic that becomes. For example, in the case of the position of the pupil 101 shown in FIG. 2, the brightness of the image A and the image B is the same level, and the image A and the image B are displayed in half, that is, mixed at a mixing ratio of 50%. become.

  With the configuration of the first embodiment described above, the two imaging positions that are determined in advance in association with the eyeball 100 of the observer by the liquid crystal panels 13-1 and 13-2 and the half mirror 14 that are display units, that is, A two-dimensional image captured in the same direction from two points having an interval of about the diameter of the eyeball 100 is mixed and displayed. The gradation films 11-1 and 11-2 serving as gradation applying units modulate the intensity of light emitted from the backlights 10-1 and 10-2 and add gradation. The lenses 12-1 and 12-2 form images of the gradation films 11-1 and 11-2 at the viewpoint position of the eyeball 100. Thereby, in the observer's viewpoint position, the luminance of each of the mixed two-dimensional images becomes low according to the distance from the imaging position where the two-dimensional image is captured to the viewpoint position. Thereby, when the observer's eyeball 100 moves to the right, the image A displayed on the liquid crystal panel 13-1 looks bright, and when the eyeball 100 moves to the left, the image B displayed on the liquid crystal panel 13-2 looks bright. become. That is, it is possible to display an image having a more appropriate depth for any observer having different interocular distances without performing a calculation for estimating a complex depth.

  Moreover, in said 1st Embodiment, a brightness | luminance changes linearly with the gradation which the gradation films 11-1 and 11-2 provide. As shown in paragraph [0024] of Reference Document 1 (Japanese Patent Laid-Open No. 2015-121748), an image at an intermediate viewpoint position can be perceived by weighted averaging of images having a small image shift width. It is known that it can be done. That is, by mixing a plurality of images captured at the above-described image capturing positions, that is, when the image capturing position is the viewpoint position, a plurality of images having a ratio of 100% are captured between these image capturing positions. It is possible to make the viewer perceive a more appropriate image of the viewpoint position. Also in the configuration according to the first embodiment, when a two-dimensional image captured at two different imaging positions has a viewpoint position at an imaging position corresponding to one two-dimensional image, the one two-dimensional image Is the highest luminance, and the luminance of the other two-dimensional image is the lowest luminance. Therefore, when there is a viewpoint position at an arbitrary position between the two imaging positions, the viewer can perceive a more appropriate image at the viewpoint position.

  In the configuration of the first embodiment, a plurality of two-dimensional images captured from a plurality of different imaging positions by a general imaging method are used instead of using a two-dimensional image captured by a special method. I use it. Therefore, an observer can perceive an image at an arbitrary viewpoint position between the different imaging positions in real time and with a low delay.

In the first embodiment, the observer's eyeball 100 directly looks at the liquid crystal panels 13-1 and 13-2, but between the lenses 12-1 and 12-2 and the half mirror 14, or A lens may be disposed between the half mirror 14 and the eyeball 100, and the distance between the optical systems may be compressed in the first optical system 40-1 and the second optical system 40-2.
In the first embodiment, two two-dimensional images are superimposed by the half mirror 14, but a tensor display or the like in which two or more liquid crystal panels are stacked is applied as a configuration corresponding to the display unit described above. The mixing ratio depending on the viewpoint position may be changed.
In the first embodiment, the two backlights 10-1 and 10-2 are used. However, as the gradation films 11-1 and 11-2, those having different transmittances depending on the polarization are applied. A liquid crystal panel that displays an image with specific polarization and transmits orthogonal polarized light like a liquid crystal may be arranged to have a single backlight.

(Second Embodiment)
Next, a display device 1a according to a second embodiment of the present invention will be described with reference to FIGS. The display device 1a according to the second embodiment is, for example, a head-mounted display or a video see-through head-mounted display. The display device 1 according to the first embodiment includes two display devices 1 according to the first embodiment for both the left and right eyes of an observer. It has become. The display device 1a according to the second embodiment further includes cameras 20-1R, 20-2R, 20-1L, and 20-2L that are imaging units that capture a two-dimensional image. In the following description, for the configuration for the right eye, for example, the display device 1 </ b> R or the half mirror 14 </ b> R is added with the symbol “R” in addition to the reference numerals given to the respective configurations of the display device 1 of the first embodiment. The configuration for the left eye is indicated by adding a symbol “L” as in the display device 1L or the half mirror 14L, for example. That is, the display device 1a according to the second embodiment includes the display device 1R, the display device 1L, and the cameras 20-1R, 20-2R, 20-1L, and 20-2L. In the following description, the eyeball of the observer is shown as the right eyeball 100R and the left eyeball 100L, and the pupil of the observer is shown as the pupil 101R for the right eye and the pupil 101L for the left eye.

  The camera 20-1R and the camera 20-2R are respectively connected to the liquid crystal panel 13-1R and the liquid crystal panel 13-2R of the display device 1R for the right eye. The camera 20-1L and the camera 20-2L are connected to the liquid crystal panel 13-1L and the liquid crystal panel 13-2L of the left-eye display device 1L, respectively. The camera 20-1R and the camera 20-2R are respectively arranged so as to image in the same direction at an imaging position having a distance between the left end and the right end of the right eyeball 100R of the observer, that is, an interval about the diameter of the right eyeball 100R. Is done. The camera 20-1L and the camera 20-2L are respectively arranged so as to image in the same direction at an imaging position having a distance between the left end and the right end of the left eyeball 100L of the observer, that is, a distance of about the diameter of the left eyeball 100L. Is done.

  In addition, the distance between the center point of the camera 20-1R and the camera 20-2R and the center point of the camera 20-1L and the camera 20-2L is approximately equal to the general interocular distance of the observer. Be placed. In addition, the direction in which the camera 20-1R and the camera 20-2R perform imaging and the direction in which the camera 20-1L and the camera 20-2L perform imaging are the same direction, and these cameras 20-1R and 20-2R are also the same. , 20-1L, 20-2L, a three-dimensional object is imaged and displayed on the liquid crystal panels 13-1R, 13-2R, 13-1L, 13-2L. Will perceive a stereoscopic image of the subject. The imaging positions at which these cameras 20-1R, 20-2R, 20-1L, and 20-2L are arranged are positions where the observer images the direction in front of the observer when using the display device 1a. Alternatively, as long as the positional relationship described above is maintained as the positional relationship between the cameras 20-1R, 20-2R, 20-1L, and 20-2L, the position may be a position where an image is captured in an arbitrary direction. .

  Each of the two-dimensional images captured by the cameras 20-1R and 20-2R is displayed as an image AR and an image BR on the liquid crystal panels 13-1R and 13-2R. As described in the first embodiment, the image AR and the image BR are mixed and displayed at the viewpoint position of the right eyeball 100R by the light whose luminance is intensity-modulated by the gradation films 11-1R and 11-2R. become. That is, when the observer moves the right eyeball 100R to the right side, the brightness of the image AR captured by the camera 20-1R increases with a linear change, and the image AR appears bright. When the observer moves the right eyeball 100R to the left side, the brightness of the image BR captured by the camera 20-2R increases with a linear change, and the image BR appears bright.

  When the viewpoint position of the right eyeball 100R is an arbitrary position between two imaging positions corresponding to the right eyeball 100R, the image AR has a distance from the imaging position at the right end of the right eyeball 100R to the viewpoint position. The brightness is reduced accordingly. The image BR is displayed with a brightness reduced in accordance with the distance from the imaging position at the left end of the right eyeball 100R to the viewpoint position, and the observer views an image obtained by mixing these images AR and BR with the right eye pupil. It will be perceived through 101R. The same applies to the left eye. When the viewpoint position of the left eyeball 100L is an arbitrary position between the two imaging positions corresponding to the left eyeball 100L, the right end of the left eyeball 100L is imaged for the image AL. It is displayed with a reduced brightness according to the distance from the position to the viewpoint position. The image BL is displayed with a luminance reduced according to the distance from the imaging position of the left end of the left eyeball 100L to the viewpoint position, and the observer views an image obtained by mixing these images AL and the image BL. It will be perceived through 101L.

By configuring as in the second embodiment described above, each viewpoint of the right eyeball 100R and the left eyeball 100L can be obtained even in an adult and a child having different interocular distances, which are distances between the right eye pupil 101R and the left eye pupil 101L. A two-dimensional image can be seen that is mixed in proportions depending on the position. Therefore, it is possible to display an image having a more appropriate depth for any observer having different interocular distances without performing a calculation for estimating a complex depth.
Moreover, real-time video see-through display can be easily realized by using a plurality of imaging units arranged corresponding to two-dimensional images to be mixed as in the second embodiment. Further, in each of the right eyeball 100R and the left eyeball 100L, an individual having an interocular distance can be obtained by appropriately setting an imaging position where a plurality of imaging units are arranged for one eyeball and an eyeball position. It is possible to correct the change in the interpupillary distance due to the inversion or abduction of the eyeball due to the difference or convergence, and to display the image with a natural depth feeling as if looking at the real thing.

  In addition, as an arrangement of the imaging unit, for example, as illustrated in FIG. 4, the configuration may be such that one camera 20-2 is shared by both the right eyeball 100 </ b> R and the left eyeball 100 </ b> L. The two-dimensional image captured by the camera 20-2 is displayed on both the liquid crystal panel 13-2R and the liquid crystal panel 13-1L.

As an arrangement of the imaging units, for example, as shown in FIG. 5, three cameras 20-1, 20-2, and 20-3 are spaced from the right end, the center, and the left end of the eyeball 100 with respect to one eyeball 100. It may be arranged at. In this case, the display device 1 according to the first embodiment includes the third optical system 40-3 that is the third optical system, and as shown in the graph of FIG. The two-dimensional images captured by −2, 20-3 are mixed at a ratio corresponding to the distance from the imaging position where the cameras 20-1, 20-2, 20-3 are arranged to the viewpoint position. The gradation of the gradation films 11-1, 11-2, 11-3 is determined.
When the cameras 20-1, 20-2, and 20-3 arranged linearly as shown in FIG. 5 are increased, the imaging positions become intervals less than the diameter of the eyeball 100, and a two-dimensional image for each narrower imaging position is obtained. Since the image can be picked up, the difference between the images can be reduced. Thereby, even a subject distributed over a wide depth range can be displayed without causing a double image to be perceived.

  In addition, as shown in FIGS. 6 (A) and 6 (B), four cameras 20-1, 20-2, 20-3, 20-4 are arranged for one eyeball 100 as the arrangement of the imaging units. It may be arranged two-dimensionally. When two-dimensionally arranging the cameras 20-1, 20-2, 20-3, and 20-4 as shown in FIG. 6, in particular, by arranging the positions to be imaged symmetrically with respect to the center of the viewing zone. Even if the viewpoint position moves in any direction including not only left and right but also up and down, it is possible to perceive a natural change of the subject according to the movement.

  When there are a plurality of imaging units, that is, cameras, n (n ≧ 2) cameras close to the viewpoint position are selected from arbitrarily determined viewpoint positions, and weighted ak expressed by the following equation (1) You may make it add by. In Expression (1), rn is a variable indicating the distance from the imaging position of each camera to the viewpoint position.

  For example, in the display device 1 of the first embodiment, the addition as shown in the equation (1) is performed by increasing the optical systems corresponding to the first optical system 40-1 and the second optical system 40-2. The gradation films 11-1, 11-2,... So that the two-dimensional images displayed on the liquid crystal panels 13-1, 13-2,. This can be realized by changing the in-plane distribution of transmittance.

(Third embodiment)
Next, a display device 1b according to a third embodiment of the present invention will be described with reference to FIG. The display device 1b is, for example, a video see-through head-mounted display, and is fixed to the observer's head with a belt or the like. The display device 1b includes a housing 50 that blocks light from the outside, liquid crystal panels 13T-1 and 13T-2, polarizing plates 15T-1 and 15T-2, a backlight 10 that are disposed inside the housing 50, And cameras 20-1R, 20-2R, 20-1L, and 20-2L attached to the wall surface of the housing 50. Here, imaging positions where the cameras 20-1R, 20-2R, 20-1L, and 20-2L according to the third embodiment are attached will be described. In the case of the right eyeball 100R, two points where the line extending from the right end and the left end of the right eyeball 100R in the line of sight and the wall surface of the housing 50 intersect are determined as imaging positions, and the camera 20-1R and the camera 20- 2R is attached. In the case of the left eyeball 100L, two points where the line extending from the right end and the left end of the left eyeball 100L in the line of sight and the wall surface of the housing 50 intersect are determined as the imaging positions, and the camera 20-1L and the camera 20- 2L is attached. The interocular distance between the right eyeball 100R and the left eyeball 100L is a general distance that is about the interocular distance of the observer. Accordingly, the observer perceives the three-dimensional object ahead of the observer's line of sight through the liquid crystal panels 13T-1 and 13T-2 and the polarizing plates 15T-1 and 15T-2.

  The backlight 10 irradiates light in a direction in which the observer's pupils 101-R and 101-L exist. For example, twisted nematic (TN) liquid crystal is applied to the liquid crystal panels 13T-1 and 13T-2, and the tilt angle of the liquid crystal molecules is antiparallel when viewed from above, and the ratio of the two-dimensional image is 100%. When close to each other, the viewer's line of sight and the orientation vector of the liquid crystal molecules are arranged to be orthogonal. The liquid crystal panel 13T-1 and the liquid crystal panel 13T-2 constitute a liquid crystal panel laminate, and the liquid crystal panel laminate is sandwiched between two polarizing plates 15T-1 and 15T-2. The polarizing plate 15T-1 and the polarizing plate 15T-2 are arranged in a direction in which the polarization directions are orthogonal. In addition, a general display has a structure in which one liquid crystal panel is sandwiched between two polarizing plates. In this way, a so-called tensor display is formed by sandwiching two liquid crystal panels between two polarizing plates. Configure.

  For example, the liquid crystal panel 13T-1 is a two-dimensional image captured by each of the cameras 20-1R and 20-1L at a position on the liquid crystal panel 13T-1 corresponding to each imaging position of the cameras 20-1R and 20-1L. The image of is displayed. The liquid crystal panel 13T-2 displays two-dimensional images captured by the cameras 20-2R and 20-2L at positions on the liquid crystal panel 13T-2 corresponding to the imaging positions of the cameras 20-2R and 20-2L. To do. Thus, when the viewpoint position matches each imaging position, the mixing ratio of the two-dimensional images captured by the cameras 20-1R, 20-2R, 20-1L, and 20-2L corresponding to each imaging position is 100. As the viewpoint position moves away from each imaging position, the luminance of the two-dimensional image to be displayed changes due to the viewing angle characteristics of the liquid crystal panels 13T-1 and 13T-2, and the mixing ratio of the two-dimensional images Will change. As the liquid crystal panels 13T-1 and 13T-2, those having a viewing angle characteristic that linearly changes in luminance are applied. As a result, as shown in the graph of FIG. 7, 2 in each of the right eyeball 100R and the left eyeball 100L. The mixing ratio of two two-dimensional images changes linearly.

With the configuration of the third embodiment, the cameras 20-1R and 20-2R and the cameras 20-1L and 20-2L, which are imaging units, are determined based on the right and left ends of the right eyeball 100R and the left eyeball 100L. It arrange | positions in the imaging position on the wall surface of the housing | casing 50. FIG. In the polarizing plates 15T-1 and 15T-2 and the liquid crystal panels 13T-1 and 13T-2 constituting the display unit, the liquid crystal panel 13T-1 captures a two-dimensional image captured by the cameras 20-1R and 20-1L. The image is displayed at a position corresponding to each imaging position. The liquid crystal panel 13T-2 displays two-dimensional images captured by the cameras 20-2R and 20-2L at positions corresponding to the respective image capturing positions. In the first and second embodiments, the gradation film 11-1, 11-2, 11-1R, 11-2R, 11-1L, 11-2L is applied as a gradation providing unit, thereby changing the luminance. Multiple two-dimensional images were mixed. On the other hand, in the third embodiment, the viewing angle characteristics in the liquid crystal panels 13T-1 and 13T-2 correspond to the gradation providing unit, and the liquid crystal panels 13T-1 and 13T-2 display according to the viewing angle characteristics. Two-dimensional images are mixed so as to have a difference in luminance. Therefore, even in an adult and a child having different interocular distances, which are distances between the right eye pupil 101R and the left eye pupil 101L, two-dimensionally mixed at a ratio corresponding to the position where each of the left and right pupils 101R, 101L exists. The image can be viewed. This makes it possible to display images that allow the observer to perceive a more appropriate depth, that is, a depth equal to the depth of the real object, for any observer with different interocular distances, without performing complex depth estimation calculations. It becomes possible to do.
In the third embodiment, since the mixing ratio is changed using the viewing angle characteristics of the liquid crystal panels 13T-1 and 13T-2, the cameras 20-1R and 13T-2 are connected to the liquid crystal panels 13T-1 and 13T-2. Even if the 20-2R, 20-1L, and 20-2L images are directly displayed, the observer can perceive an image mixed in a desired ratio.

In the third embodiment, the configuration includes two liquid crystal panels 13T-1 and 13T-2. However, the configuration may include three or more liquid crystal panels.
In the configuration of the third embodiment, a lens may be provided between the polarizing plate 15T-2 and the left and right eyeballs 100R and 100L. By providing the lens, the depth of the housing 50 of the display device 1b can be shortened.

  In the second embodiment and the third embodiment, the positional relationship of the cameras 20-1R, 20-2R, 20-1L, and 20-2L is maintained, and the cameras 20-1R, 20-2L, and 20-2L are arranged at remote locations to move the observer's head. The direction of the cameras 20-1R, 20-2R, 20-1L, and 20-2L is controlled in accordance with the image, and the image is transferred through the communication line to be liquid crystal panels 13-1R, 13-2R, 13-1L, and 13-. You may make it display on 2L, 13T-1, and 13T-2. By doing in this way, the observer can experience as if in a remote place.

  In each of the embodiments described above, a plurality of different imaging positions are described as two points having a distance between the left end and the right end of the eyeball 100, that is, an interval of about the diameter of the eyeball 100. It may be determined as follows. For example, when it is assumed that the display device is used by a plurality of people, the eyeball position of the person assumed to have the maximum interocular distance among the users and the minimum interocular distance among the users The imaging position may be determined based on the eyeball position of the person assumed to have the eyeball. In this case, when the display device is used, the position of the pupil when the eyeball of the user having the maximum interocular distance is maximum abducted and the eyeball of the user having the minimum interocular distance are The camera may be installed with the position of the pupil at that time as both ends. When it is assumed that the display device is used by a specific person, the imaging position may be determined based on the eyeball position of the one user. In this case, when the display device is used, a camera may be installed with both the pupil position when the user's eyeball is abducted to the maximum and the pupil position when the user's eyeball is abducted to the maximum. Furthermore, when it is assumed that the display device is used for a purpose in which a specific user stares at a specific display (that is, when the user's eyeball does not rotate), the left and right ends of the user's pupil are both ends. A camera may be installed. Note that the distance between the cameras may be set slightly wider in consideration of the shift at the time of wearing.

  Further, the meaning of “same direction” described in each of the above embodiments does not necessarily mean the completely same direction, and means that a slight deviation may be included. More specifically, in the above “same direction”, when the optical axes of two cameras that capture images corresponding to the left and right eyes are arranged in parallel, the optical axes of the other cameras are also arranged in parallel. Means. In addition, when the optical axes of the two cameras that capture images corresponding to the left and right eyes are arranged so as to converge at a specific point, the optical axes of the other cameras should also be arranged so as to converge at that one point. Means. Note that the subject image captured by each camera from the “same direction” is corrected by a process such as projective transformation or shift, with the camera image arranged so that the direction of the optical axis is substantially the same. It may be an image.

  You may make it implement | achieve the display apparatus 1,1a, 1b in embodiment mentioned above with a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read into a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. Further, the program may be a program for realizing a part of the above-described functions, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system. You may implement | achieve using programmable logic devices, such as FPGA (Field Programmable Gate Array).

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Display apparatus, 10-1 to 10-2 ... Back light, 11-1 to 11-2 ... Gradation film, 12-1 to 12-2 ... Lens, 13-1 to 13-2 ... Liquid crystal panel, 14 ... Half mirror, 40-1 ... first optical system, 40-2 ... second optical system, 100 eyeball, 101 ... pupil

Claims (8)

A display unit that displays a mixture of a plurality of two-dimensional images captured in the same direction from each of a plurality of different imaging positions determined in advance in association with one of the observer's eyeballs;
At any viewpoint position of the eyeball that can move within a range defined by the plurality of different imaging positions, the brightness of each of the mixed two-dimensional images perceived by the pupil of the eyeball is determined for each of the two-dimensional A gradation providing unit configured to reduce luminance according to a distance from the imaging position corresponding to an image to the viewpoint position;
A display device comprising: When the viewpoint position of the eyeball corresponds to the imaging position of any one of the plurality of predetermined different imaging positions, the gradation assigning unit calculates the luminance of the two-dimensional image corresponding to the imaging position. The luminance of each of the plurality of two-dimensional images at an arbitrary viewpoint position of the eyeball is linearly determined from the highest luminance in accordance with the distance from the imaging position corresponding to each to the viewpoint position. Reduced brightness,
The display device according to claim 1. The gradation assigning unit is configured such that the luminance of each of the plurality of two-dimensional images at an arbitrary viewpoint position of the eyeball is constant, and the total luminance of the mixed two-dimensional image perceived by the pupil of the eyeball is constant. The brightness becomes
The display device according to claim 2. The gradation assigning unit adds a weight acquired based on a distance from each of the imaging positions to the viewpoint position, for each of the plurality of two-dimensional images at an arbitrary viewpoint position of the eyeball. Brightness
The display device according to any one of claims 1 to 3. The interval between the plurality of different imaging positions is a distance about the diameter of the eyeball or a distance equal to or less than the diameter.
The display device according to any one of claims 1 to 4. Arranged at each of the plurality of different imaging positions, comprising a plurality of imaging units for imaging the two-dimensional image,
The display unit displays a mixture of each of the two-dimensional images captured by the plurality of imaging units.
The display device according to any one of claims 1 to 5. The display unit includes a plurality of liquid crystal panels that display the plurality of two-dimensional images, and a mixing unit that mixes the plurality of two-dimensional images displayed on the liquid crystal panel. A backlight for irradiating light and a lens,
The gradation providing unit adds a gradation to the light irradiated by the backlight to reduce the luminance,
The lens is disposed so that the surface to which the gradation is added forms an image at the viewpoint position.
The display device according to any one of claims 1 to 6. The display unit is a liquid crystal panel stack in which each layer displays each of two-dimensional images from the plurality of different viewpoint positions.
The display device according to any one of claims 1 to 6.

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