JP4576390B2 - Stereoscopic two-dimensional image display apparatus and stereoscopic two-dimensional image display method - Google Patents

Description

  The present invention relates to a stereoscopic two-dimensional image display device and a stereoscopic two-dimensional image display method for displaying a stereoscopic two-dimensional image with a sense of depth by forming a two-dimensional image in space.

  Image display devices are used in various fields such as home TVs, amusement game devices, training simulators, medical surgery support systems, architectural landscape simulations, mobile phone displays, etc. Yes. In recent years, in image display devices used in these fields, in order to improve amusement and visibility, development of stereoscopic display technology that can provide a high sense of reality has been attempted. Stereoscopic display devices can be broadly classified into those using parallax information and those using depth information. Those using parallax information can be further divided into those using polarized glasses and those not using them.

  For example, the parallax information method that does not use polarized glasses is the lenticular lens method, in which multiple screens are latent on a single screen, and multiple screens are transmitted through a transmissive screen in which semi-cylindrical lenses of a certain width are connected horizontally By seeing, 3D expression and animation expression are possible. Specifically, stripe images alternately arranged from two right and left parallax images corresponding to both eyes of the viewer are supplied to both eyes of the viewer using a lenticular lens to recognize a stereoscopic image (for example, , See Patent Document 1).

  However, since the lenticular lens method causes a plurality of screens to be latent images on one screen, it requires computer image processing, lenticular lens design, and an accurate combination operation between the lens and the image, and tends to be expensive. In addition, there are a method using depth information for displaying all three-dimensional coordinate information and an electronic holography system that completely reproduces the reflected light of an object by the effect of diffraction, but the amount of information is large.

  On the other hand, a stereoscopic two-dimensional image display device has been proposed that can display a two-dimensional image as if it is projected with a simple configuration by forming a two-dimensional image with a microlens array. . The stereoscopic two-dimensional image display device includes a display unit that displays a two-dimensional image including a stereoscopic image on a planar image display surface, and a microlens array that is arranged on the image display surface and is separated from the microlens array. Thus, an imaging plane of a real image (imaging image) of the two-dimensional image is generated in a space located on the opposite side of the display unit. According to this three-dimensional two-dimensional image display apparatus, it was possible to obtain a sense of reality with a very simple configuration and a remarkably small amount of information.

JP-A-10-221644

  However, since the above-described conventional stereoscopic two-dimensional image display device generates a two-dimensional image formation plane in space, a sense of depth is generated by the embossed display of the real image, and a realistic feeling is realized with a very simple configuration. Although obtained, when a stereoscopic two-dimensional image is always observed at the same raised position, there is a problem that the raised effect and the unexpectedness are lowered and it is difficult to maintain a high rendering effect. In addition, since there is a single image plane on which a real image is raised, there is a limit to the expression of the difference in depth, and a sufficient three-dimensional effect cannot be obtained, which is also an obstacle to obtaining a high rendering effect.

  The problems to be solved by the present invention include the problem that the embossing effect / unexpectedness is reduced and it is difficult to maintain a high rendering effect, and an obstacle to obtaining a high rendering effect without obtaining a sufficient stereoscopic effect. Each of these problems is an example.

The stereoscopic two-dimensional image display device according to claim 1, wherein the incident light is inverted inside and then emitted to form a stereoscopic two-dimensional image which is an erecting equal-magnification image on one optical axis. A microlens array that is spaced apart from the microlens array on the one optical axis and displays a two-dimensional image, and light is transmitted from the image display surface to the microlens array. A plurality of display units that emit light, and a video signal supply unit that distributes a video signal that is a source of the stereoscopic two-dimensional image and supplies the video signals to the plurality of display units, respectively, and the microlens array The working distance to be imaged is not a single, but has a range, and the separation distance between each of the display units and the microlens array is set individually, so that a plurality of three-dimensional two-dimensional images can be placed in space. Display Serial video signal supply section, the performed a plurality of control to vary individually each image signal supplied to the display unit, and arranging the plurality of display portions are inclined from each plane perpendicular to said one optical axis The imaging planes of the plurality of stereoscopic two-dimensional images are set so as to be non-parallel and intersect with each other .

The stereoscopic two-dimensional image display method according to claim 7, wherein the incident light is inverted inside and then emitted to form a stereoscopic two-dimensional image that is an erect life-size image on one optical axis. A microlens array that is spaced apart from the microlens array on the one optical axis and displays a two-dimensional image, and light is transmitted from the image display surface to the microlens array. Stereoscopic two-dimensional image display in an apparatus comprising: a plurality of display units that emit; and a video signal supply unit that distributes a video signal that is a source of the stereoscopic two-dimensional image and supplies the video signals to the plurality of display units, respectively. In the method, the microlens array has not a single working distance for imaging light, but has a range, and the distance between each of the display unit and the microlens array is individually set. In Ri, a plurality of stereoscopic two-dimensional image is displayed on the spatial, the video signal supply unit performs control to change individually each image signal supplied to the plurality of display portions, the plurality of display Are arranged so as to be inclined from the vertical plane with respect to the one optical axis, and the imaging planes of the plurality of three-dimensional two-dimensional images are set so as to be non-parallel and intersect with each other .

  Preferred embodiments of a stereoscopic two-dimensional image display device and a stereoscopic two-dimensional image display method according to the present invention will be described below with reference to the drawings. In the present invention, “stereoscopic two-dimensional image” means a two-dimensional image displayed in space.

<< First Embodiment >>
First, the stereoscopic two-dimensional image display apparatus according to the first embodiment of the present invention will be described.
FIG. 1 is a perspective view illustrating a configuration of a stereoscopic two-dimensional image display device 100 according to the first embodiment, and FIG. 2 is a view taken along the line AA in FIG.

As shown in FIGS. 1 and 2, the stereoscopic two-dimensional image display apparatus 100 according to the present embodiment includes a first display unit 11, a second display unit 27, an image transmission panel 17, and a half mirror 19. The video supplied from the video signal supply unit 41 (details will be described later) is reproduced.
The first display unit 11 includes an image display surface 11 a that projects a two-dimensional image onto the image transmission panel 17. Similarly, the second display unit 27 projects an image that projects a two-dimensional image onto the image transmission panel 17. A display surface 27a is provided.

  As the first display unit 11 and the second display unit 27, for example, a color liquid crystal display (LCD) can be used as an example. The image display surfaces 11a and 27a, a backlight illumination unit and a drive circuit (not shown), and the like are included. Prepare. In addition to the LCD, the first display unit 11 and the second display unit 27 can use a cathode ray tube, a plasma display, an organic EL (Electroluminescence) display device, or the like. The drive circuit outputs a display drive signal to the LCD based on the video signal input from the video signal supply unit described later, and displays a stereoscopic two-dimensional image having a sense of depth on the image display surfaces 11a and 27a.

  The image transmission panel 17 includes a microlens array 25 (details will be described later), and is disposed at a predetermined position in the stereoscopic two-dimensional image display device 100. The first display unit 11 and the second display unit 27 are spaced apart from the image transmission panel 17. In the first embodiment, the first display unit 11 is disposed on the optical axis of the image transmission panel 17 and is disposed in parallel with the image transmission panel 17.

Further, the image transmission panel 17 forms an image of light (projected two-dimensional image) emitted from the image display surfaces 11 a and 27 a and displays a plurality of stereoscopic two-dimensional images 13 a and 13 b in the space 15.
The stereoscopic two-dimensional images 13a and 13b are displayed on a single plane on a space defined according to the working distance of the microlens array 25. In the stereoscopic two-dimensional image display device 100, for example, the stereoscopic two-dimensional image 13 (13a, 13b) displayed on the imaging surfaces 21b, 21a can be viewed from the front on the front surface of a housing (not shown). An opening is provided.

  Further, as shown in FIG. 2, the half mirror 19 is disposed at a position where the light emitted from the first display unit 11 and the light emitted from the second display unit 27 intersect with each other, from the first display unit 11. And the light emitted from the second display unit 27 is reflected in the direction along the light emitted from the first display unit 11.

  Since the light emitted from the first display unit 11 passes through the half mirror 19, the two-dimensional image displayed on the image display surface 11a of the first display unit 11 is formed on the image forming surface 21b via the image transmission panel 17. The image is formed as a stereoscopic two-dimensional image 13b.

In addition, since the light emitted from the second display unit 27 is reflected by the half mirror 19, the two-dimensional image displayed on the image display surface 27 a of the second display unit 27 is connected via the image transmission panel 17. An image is formed on the image plane 21a as a stereoscopic two-dimensional image 13a.
Since the imaging positions of the stereoscopic two-dimensional images 13a and 13b are determined according to the distances between the first display unit 11, the second display unit 27, and the image transmission panel 17, the first display unit 11 and the image transmission are performed. By individually setting the separation distance from the panel 17 and the separation distance between the second display unit 27 and the image transmission panel 17, the plurality of imaging surfaces 21 a and 21 b are formed with a distance, and are formed on the optical axis. An observer who observes from a viewpoint that is positioned can observe individual stereoscopic two-dimensional images with perspective. That is, the observer can view the stereoscopic two-dimensional images 13 a and 13 b as the stereoscopic two-dimensional image 13 in the space 15 in the viewing direction. In FIG. 2, 31 represents a virtual position of the second display unit 27.

  According to such a half mirror 19, the second display unit 27 uses a general LCD similar to the first display unit 11 and does not block the emitted light from the first display unit 11. The two-dimensional images 13a and 13b can be formed on the space 15 in an overlapping manner.

<< Second Embodiment >>
Next, a stereoscopic two-dimensional image display device according to a second embodiment of the present invention will be described.
FIG. 3 is a schematic configuration diagram of a stereoscopic two-dimensional image display device 150 according to the second embodiment of the present invention.

As shown in FIG. 3, the stereoscopic two-dimensional image display device 150 includes a first display unit 11, a second display unit 33, and an image transmission panel 17, and includes a video signal supply unit 41 (details will be described later). Play the supplied video. In addition, the same number is attached | subjected to the same thing as 1st Embodiment, and the detailed description is abbreviate | omitted.
The second display unit 33 includes an image display surface 33 a that projects a two-dimensional image, is on the optical axis of the image transmission panel 17, and is disposed between the first display unit 11 and the image transmission panel 17. The second display unit 33 has light transmission from the surface facing the image display surface 11a toward the image display surface 33a, and transmits light emitted from the first display unit 11 and is two-dimensional. Display an image. For example, an organic EL display device that is a light-emitting display device can be suitably used as the second display unit 33.

  If the second display unit 33 is an organic EL display device, it is possible to increase the light transmittance from the first display unit 11 as compared with the first embodiment using the half mirror 19. The stereoscopic two-dimensional image 13b from the first display unit 11 that is imaged can be brightened.

  Further, when an organic EL display device is used as the second display unit 33, high light transmittance is obtained and the thin display unit 33 is thin, so that it is on the optical axis of the image transmission panel 17 and communicates with the first display unit 11. It becomes easier to arrange the plurality of second display parts 33 between the panel 17. In the configuration shown in FIG. 3, one second display unit 33 is provided. By arranging a plurality of second display units 33 in parallel therewith, the observer can place two or more in the space 15. The three-dimensional two-dimensional image can be viewed by overlapping, and more accurate three-dimensional information can be expressed.

<< Third Embodiment >>
Next, a stereoscopic two-dimensional image display device according to a third embodiment of the present invention will be described.
FIG. 4 is a schematic configuration diagram showing a stereoscopic two-dimensional image display apparatus 200 according to the third embodiment of the present invention.

  As shown in FIG. 4, the stereoscopic two-dimensional image display device 200 includes a first display unit 11, a second display unit 33, a third display unit 35, and an image transmission panel 17, and a video signal supply unit 41 (not shown) The video supplied from details will be played back. In addition, the same number is attached | subjected to the same thing as 1st Embodiment-2nd Embodiment, and the detailed description is abbreviate | omitted.

  Similar to the second display unit 33, the third display unit 35 has light transmission from the surface facing the image display surface 11 a toward the image display surface 35 a and is emitted from the first display unit 11. Transmits light and displays a two-dimensional image. For example, an organic EL display device that is a light-emitting display device can be suitably used as the third display unit 35.

  In addition, the third display unit 35 in the third embodiment is installed on the opposite side of the first display unit 11 across the image transmission panel 17 and between the image transmission panel 17 and the observer.

In the stereoscopic two-dimensional image display apparatus 200 shown in FIG. 4, the second display unit 33 is provided between the first display unit 11 and the image transmission panel 17, so that the image plane 21a is also stereoscopically displayed. A dimensional image can be displayed.
Therefore, in the stereoscopic two-dimensional image display device 200, the observer visually observes the two-dimensional image of the third display unit 35 displayed on the far side in the viewing direction, and connects to the imaging planes 21a and 21b before that. The stereoscopic two-dimensional images from the first display unit 11 and the second display unit 33 that have been imaged are viewed. According to the third embodiment, a stereoscopic two-dimensional image formed on the imaging planes 21a and 21b appears to protrude from an image (for example, a background image) displayed on the third display unit 35. A feeling can be heightened. Furthermore, since the half mirror 19 is not used, the stereoscopic two-dimensional image display device 200 can be made compact.

  Further, according to the stereoscopic two-dimensional image display device 200, for example, by displaying the same two-dimensional image from the third display unit 35 and the first display unit 11 (second display unit 33), the stereoscopic two-dimensional image is displayed. The embossing effect and unexpectedness of can be further enhanced. Further, by turning off the display of the two-dimensional image from the first display unit 11 (second display unit 33), the normal two-dimensional image can be displayed from the third display unit 35.

<< Fourth Embodiment >>
Next, a stereoscopic two-dimensional image display device according to a fourth embodiment of the present invention will be described.
FIG. 5 is a schematic configuration diagram of a stereoscopic two-dimensional image display apparatus 250 according to the fourth embodiment of the present invention.

  As shown in FIG. 5, the stereoscopic two-dimensional image display device 250 includes a first display unit 11, a second display unit 29, an image transmission panel 17, and a half mirror 19, and a video signal supply unit 41 (not shown) (details) The video supplied from (to be described later) is reproduced. In addition, the same number is attached | subjected to the same thing as 1st Embodiment-3rd Embodiment, and the detailed description is abbreviate | omitted.

  In the stereoscopic two-dimensional image display device 250 according to the fourth embodiment, the half mirror 19 and the second display unit 29 are also arranged at different positions from the first stereoscopic two-dimensional image display device 100. The half mirror 19 is installed on the side opposite to the first display unit 11 with the image transmission panel 17 interposed between the image transmission panel 17 and the observer. As shown in FIG. 5, the half mirror 19 is emitted from the first display unit 11 through the image transmission panel 17 and emitted from the second display unit 29 on the optical axis of the image transmission panel 17. Is disposed at a position where it intersects with the light to be transmitted, transmits light from the first display unit 11, and reflects light emitted from the second display unit 29 in a direction along the light emitted from the first display unit 11. . In FIG. 5, 91 represents a virtual position of the second display unit 29.

  In the stereoscopic two-dimensional image display device 250, the two-dimensional image displayed on the image display surface 11a of the first display unit 11 is imaged as a stereoscopic two-dimensional image on the imaging surface 21b via the image transmission panel 17. Is done.

Further, the two-dimensional image displayed on the image display surface 29a of the second display unit 29 is reflected from the half mirror 19 and is displayed from the position 91 in FIG. Accordingly, the observer visually observes the two-dimensional image of the second display unit 29 virtually displayed at the position 91 on the back side in the viewing direction, and the first image formed on the imaging surface 21b in front of the viewer. A stereoscopic two-dimensional image from the display unit 11 is visually observed. According to the fourth embodiment, a stereoscopic two-dimensional image formed on the imaging surface 21 b is formed from a two-dimensional image (for example, a background image) displayed on the second display unit 29 that is visible through the half mirror 19. It can be raised to enhance the stereoscopic effect.
Although a part of the description is simplified in the present embodiment, it is needless to say that there may be a plurality of two-dimensional image forming surfaces.

<< Fifth Embodiment >>
Next, a stereoscopic two-dimensional image display device according to a fifth embodiment of the present invention will be described.
FIG. 6 is a schematic configuration diagram of a stereoscopic two-dimensional image display apparatus 300 according to the fifth embodiment of the present invention.

  As shown in FIG. 6, the stereoscopic two-dimensional image display apparatus 300 includes a first display unit 11, a second display unit 29, an image transmission panel 17, and a half mirror 19, and a video signal supply unit 41 (not shown) (details). The video supplied from (to be described later) is reproduced. In addition, the same number is attached | subjected to the same thing as 1st Embodiment-4th Embodiment, The detailed description is abbreviate | omitted.

  As shown in FIG. 6, the half mirror 19 is emitted from the first display unit 11 through the image transmission panel 17 and emitted from the second display unit 29 on the optical axis of the image transmission panel 17. It is disposed at a position where it intersects with the light to be reflected, reflects light from the first display unit 11, and transmits light emitted from the second display unit 29 in a direction along the light emitted from the first display unit 11. . The image transmission panel 17 is disposed between the half mirror 19 and the first display unit 11.

In this configuration, the second display unit 29 is viewed through the half mirror 19, and a two-dimensional image from the first display unit 11 reflected by the half mirror 19 is formed on the imaging surface 21b. Therefore, the observer visually observes the image displayed on the second display unit 29 on the far side in the viewing direction, and the stereoscopic two-dimensional image from the first display unit 11 imaged on the imaging surface 21b in front of the image. The image will be viewed. According to the fifth embodiment, a stereoscopic two-dimensional image formed on the imaging plane 21b is formed from a two-dimensional image (for example, a background image) displayed on the second display unit 29 that is visible through the half mirror 19. It can be raised to enhance the stereoscopic effect.
Although a part of the description is simplified in the present embodiment, it is needless to say that there may be a plurality of two-dimensional image forming surfaces.

<< Sixth Embodiment >>
Next, a stereoscopic two-dimensional image display device according to a sixth embodiment of the present invention will be described.
FIG. 7 is a schematic configuration diagram of a stereoscopic two-dimensional image display apparatus 350 according to the sixth embodiment of the present invention.

  As shown in FIG. 7, the stereoscopic two-dimensional image display device 350 includes a first display unit 11, a second display unit 27, an image transmission panel 17, and a half mirror 19, and an unillustrated video signal supply unit 41 (details). The video supplied from (to be described later) is reproduced.

  In the first to fifth embodiments described above, each display unit (the first display unit 11 and the second display unit 27) is disposed substantially perpendicular to the optical axis. The first display unit 11 and the second display unit 27 are disposed with a predetermined angle with respect to the optical axis.

  That is, the first display unit 11 is disposed at a predetermined angle θ1 from the vertical plane V1 with respect to the axis shown in FIG. 7, and the second display unit 27 is a vertical plane with respect to the axis shown in FIG. Arranged at a predetermined angle θ2 from V2.

  In the example of FIG. 7, the arrangement of each part other than the tilt of the first display unit 11 and the second display unit 27 with respect to the optical axis is substantially the same as that of the first embodiment. The same number is attached | subjected to the same thing as this embodiment, and the detailed description is abbreviate | omitted.

  In this configuration, the imaging surface 21b is inclined with respect to the vertical plane V1 with respect to the optical axis by a predetermined angle θ1, and the stereoscopic two-dimensional image 13b is also inclined to form an image. Further, the imaging surface 21a is inclined with respect to the vertical plane V1 with respect to the optical axis by a predetermined angle θ2, and the stereoscopic two-dimensional image 13a is also inclined to form an image.

In the example shown in FIG. 7, the separation distance between the first display unit 11 and the image transmission panel 17 and the separation distance between the second display unit 27 and the image transmission panel 17 are further adjusted to form the imaging surface 21 b and the imaging surface 21 a. And are arranged so that and intersect at approximately the center.
Thereby, for example, as shown in FIG. 7, a variety of video expressions such as a highly amusement video in which two videos (stereoscopic two-dimensional image 13b and stereoscopic two-dimensional image 13a) collide at the center and collide with each other. It becomes possible.

  Furthermore, in the configuration according to another embodiment of the present invention, an imaging position varying unit may be used as the image transmission panel 17. As an example of the imaging position varying means, a variable focus lens provided in the image transmission panel 17 can be cited.

  As the variable focus lens, a so-called liquid crystal lens can be preferably used. The variable focus lens is a lens that can continuously change the direction of the major axis of liquid crystal molecules in the vertical direction by controlling the magnitude of the applied voltage. Therefore, the refractive index continuously changes with respect to the light incident in the orientation direction of the liquid crystal molecules.

  By changing the focal length using this variable focal length lens, the image formation position of the two-dimensional image is moved and displayed, and the amount of protrusion of the image can be varied to further enhance the unexpectedness and stereoscopic effect. it can.

<< Video Playback Method in Each Embodiment >>
Next, a video reproduction method for each display unit in the stereoscopic two-dimensional image display device of each embodiment will be described.
FIG. 8 is a block diagram showing a schematic configuration of the video signal supply unit 41. In FIG. 8, the video signal is supplied from the video signal supply unit 41 to the first display unit 11 and the second display unit 27, corresponding to the first embodiment. However, this is merely an example, and the same video signal reproduction method is used in other embodiments. Hereinafter, a description will be given corresponding to the first embodiment.

  The video signal supply unit 41 irradiates the recording medium 43 with the light beam 45, reads a recording pit on the recording medium 43, a demodulation unit 49 that demodulates a reproduction signal from the pickup 47, and a first demodulation signal. Distributing unit 51 for display unit 11 and second display unit 27, demultiplexers 53a and 53b for inputting respective demodulated signals, separating them into image information signals and audio information signals, and image information signals Video decoders 55a and 55b that decode video signals and output video signals, audio decoders 57a and 57b that decode audio information signals and output audio signals, a spindle motor 59 that rotates the recording medium 43, and a spindle Servo rotation for motor 59 rotation control and pickup focus servo and tracking servo control 61, an operation unit 63 which is a user operation, the system controller 65 for controlling the whole apparatus based on the operation signal from the operation unit 63, and a memory 67.

The video signal supply unit 41 reproduces the recording medium 43 on which the video signal is recorded, and supplies the video signal to the first display unit 11 and the second display unit 27. On the recording medium 43, a video signal of a two-dimensional image on which a stereoscopic visual effect having a sense of depth is given is recorded in advance.
More specifically, as a stereoscopic two-dimensional image having a sense of depth, an image drawn by a perspective method, a close-up image on the imaging surface 21b close to the observer, and an imaging surface 21a far from the observer are used. An image that displays a distant view in a small size, an image that alternately displays a close view and a distant view on the front and back imaging planes 21a and 21b, or an image that displays a close view moving fast and a distant view moving slowly when displaying a moving image, etc. Can be mentioned. Furthermore, the background portion other than the stereoscopic two-dimensional image may be dark color such as black so that the stereoscopic two-dimensional image appears more three-dimensionally.

Next, the operation of the stereoscopic two-dimensional image display device 100 will be described.
FIG. 9 is an explanatory diagram showing an example of an image displayed on the first display unit 11 and the second display unit 27, and FIG. 10 is an image observed by an observer when the image of FIG. 9 is formed on the imaging plane. It is explanatory drawing showing this.

  In the stereoscopic two-dimensional image display device 100, first, in the video signal supply unit 41, the reproduction signal recorded on the recording medium 43 is demodulated by the demodulation unit 49, and the reproduction signal is separated from the first display unit 11 by the distribution unit 51. And the second display unit 27 (light-transmissive second display unit 33). On the recording medium 43, an image signal and an audio signal drawn in perspective are recorded in advance.

  The respective image signals divided by the distribution unit 51 are decoded by the video decoders 55a and 55b and output to the first display unit 11 and the second display unit 27 as video signals. Therefore, the light for projecting the two-dimensional image is emitted from the second display unit 27 through the half mirror 19 toward the image transmission panel 17, and the light for projecting the two-dimensional image from the first display unit 11 is image transmission panel 17. , The stereoscopic two-dimensional image is displayed on the imaging plane 21b and the imaging plane 21a.

  The two-dimensional image displayed on the first display unit 11 is imaged on the imaging surface 21b on the near side as viewed from the observer, and the two-dimensional image displayed on the second display unit 27 is the back as viewed from the observer. The image is formed on the image forming surface 21a on the side. For example, when displaying the same object image, as shown in FIG. 9A, the object image drawn large is displayed on the first display unit 11 and small on the second display unit 27. As a result, a large object image 71a is formed on the imaging surface 21b on the near side, and a small object image 71b is formed on the imaging surface 21a on the back side. By drawing with a sense of distance that matches such perspective, a more effective stereoscopic display becomes possible.

Further, for example, the object images 71a and 71b displayed on the first display unit 11 and the second display unit 27 are displayed so as to move back and forth.
In one frame image shown in FIG. 9A, a large object image 71a is displayed on the left side of the near-side image plane 21b, and a small object image 71b is displayed on the right side of the back-side image plane 21a. .
In the other frame image shown in FIG. 9B, a large object image 71a is displayed on the right side of the near-side image plane 21b, and a small object image 71b is displayed on the left side of the back-side image plane 21a. These two frame images are alternately displayed by the video signal supply unit 41.
In other words, the front and rear imaging surfaces 21a and 21b are displayed so as to alternately switch between the foreground image and the distant view image. Accordingly, the object images 71a and 71b of the stereoscopic two-dimensional image are observed as if the two object images on the left and right are alternately moving back and forth as shown in FIG.
In this way, by continuously displaying the same object image on the front and rear imaging planes, it is possible to display as if a plurality of imaging planes are moving. In addition, it is possible to display not only two image forming surfaces as shown in FIG. 9 but also a plurality of three or more image forming surfaces. Further, it is also conceivable to prepare an image that complements between the left image and the right image in FIG. 9 so that the movement (switching) of the image is smooth, and insert the image between the image switching. In that case, the same object image is simultaneously displayed on the front and rear imaging planes during the switching of the images.

  In addition, when a moving image is displayed, the movement of the object in the foreground is displayed fast and the movement of the object in the distant view is displayed slowly. By creating an image using such empirical knowledge based on motion parallax, more effective stereoscopic display becomes possible.

  FIG. 11 shows a two-dimensional image display apparatus 100 that displays two images superimposed on two front and rear imaging planes, and changes the luminance ratio of the two front and rear images to change between the two planes. Stereoscopic illusion that can perceive the depth position at an arbitrary position, and a stereoscopic image display method called the brightness modulation type stereoscopic display method or DFD (Depth-Fused 3-D) method (NTT Technical Review Online August 2004 Vol.2 It is operation | movement explanatory drawing at the time of utilizing No.8 "The small DFD display which laminated | stacked LCD of two front and back surfaces").

In the stereoscopic two-dimensional image display device 100, the video signal supply unit 41 uses the same two-dimensional image display apparatus 100 at the same position on the plurality of imaging planes 21 a and 21 b so that the displayed stereoscopic two-dimensional image is displayed with greater perspective. In addition, the DFD method for displaying images with different luminances may be used.
The DFD method uses a phenomenon in which a plurality of points 81, 83, and 85 are arranged in the depth direction, and a depth sensation is generated when the brightness of each of the points 81, 83, and 85 is differentiated.
As shown in FIG. 11, if points 81, 83, and 85 are superimposed on two imaging planes 21a and 21b to form an image, and the point 81 imaged on the back imaging plane 21a is brightened, The point 81 feels far away, and if the point 85 imaged on the imaging surface 21b on the near side is brightened, the point 85 feels close.
If the brightness of the points 83 and 83 on the two image planes 21a and 21b is the same, it feels as if they are in the middle.

  Since the DFD method is generally performed using two image display devices, the video is viewed through the transparent display screen. Therefore, it is not an image that appears in space but an image that is displayed inside the display. On the other hand, in the stereoscopic two-dimensional image display device 100, since the points 81, 83, and 85 with different luminances can be overlapped on the plurality of imaging planes 21a and 21b formed in the space 15, the pop-out effect has already made it possible. By adding a sense of depth due to a luminance difference to an image in which a stereoscopic effect is expressed, the stereoscopic effect can be dramatically enhanced synergistically. Of course, this embodiment can also display three or more screens.

  Finally, the structure of the image transmission panel 17 will be described. FIG. 12 is an enlarged view of the image transmission panel 17.

  The image transmission panel 17 is configured by a microlens array 25. The microlens array 25 includes, for example, two lens array halves 25a and 25b in which a plurality of microconvex lenses 23 are two-dimensionally arranged on both surfaces of a transparent substrate made of glass or resin having excellent light transmittance. It is configured to be integrated.

  The optical axis of each micro-convex lens 23a formed on one surface is formed to be the same as the optical axis of the micro-convex lens 23b formed on the other surface formed at the opposite position. The micro convex lenses 23b and 23a adjacent to each other between the array halves 25a and 25b are overlapped so that the optical axes thereof are also the same.

  In the present invention, an embodiment using the microlens array 25 in which the lens array surface is formed on any of the surfaces (total four surfaces) of the two lens array halves 25a and 25b will be described. The configuration of the microlens array 25 is not limited to this.

  The microlens array 25 is arranged at a position separated by a predetermined separation distance (operating distance of the microlens array 25) set for each display unit. In the microlens array 25 (image transmission panel 17), the working distance for imaging light is not single but has a range.

  The microlens array 25 forms a two-dimensional image emitted from the image display surface of each display unit in a space separated by a predetermined distance on the opposite side of the image display surface, whereby the two-dimensional image displayed on the image display surface is displayed. A stereoscopic two-dimensional image is displayed by forming the two-dimensional image on an imaging plane which is a two-dimensional plane in space.

  This imaged two-dimensional image is displayed floating in space when the image has a sense of depth or when the background image on the display is black and the contrast is emphasized. Therefore, it looks as if a stereoscopic image is projected from the front observer. That is, the two-dimensional image displayed on the image plane is recognized by the observer as a pseudo three-dimensional image, that is, a three-dimensional two-dimensional image.

  The microlens array 25 allows light corresponding to the image incident from each display unit to be incident from the lens array halves 25a and 25b, inverted once inside, and then emitted from the lens array halves 25a and 25b. Is desirable. Thereby, the microlens array 25 can display the two-dimensional image displayed on each display unit as an upright three-dimensional two-dimensional image on the imaging plane.

Note that the microlens array 25 is not limited to one in which the lens array halves 25a and 25b are integrated in a pair, but may be composed of one or a plurality of two or more. Good. However, when image-corresponding light is transmitted through such a single micro-convex lens or when image-corresponding light is transmitted through three micro-convex lenses, after the incident light is inverted once inside, The image is displayed as an upright stereoscopic two-dimensional image.
With such a configuration of the microlens array 25, the working distance for imaging the light is not a single, but has a certain effective range, so that a plurality of three-dimensional two-dimensional images can be combined. It becomes possible to image. That is, it becomes possible to observe a plurality of imaging planes.

  As described above in detail, according to the stereoscopic two-dimensional image display device (100, 150, 200, 250, 300, 350) according to each embodiment of the present invention, light is imaged on one optical axis. An image transmission panel 17 that displays a stereoscopic two-dimensional image, and an image display surface (11a, 27a) that is spaced apart from the image transmission panel 17 on the one optical axis and displays a two-dimensional image, A plurality of display units (11, 27) for emitting light from the image display surfaces (11a, 27a) to the image transmission panel 17, and each of the display units (11, 27) and the image transmission panel 17 Since the separation distances are individually set to display a plurality of stereoscopic two-dimensional images (13a, 13b) in the space 15, the plurality of image planes 21a, 21b are displayed in the space 15. Can form and float With the effectively-unexpectedness can be improved, sufficient stereoscopic effect can be obtained, it is possible to sustain a high stage effect.

  In addition, according to the stereoscopic two-dimensional image display method according to each embodiment of the present invention, the image transmission panel 17 that displays a stereoscopic two-dimensional image by imaging light on one optical axis, and the image transmission panel A plurality of display units (11a, 27a) that are spaced apart from 17 and display a two-dimensional image, and that emit light from the image display surfaces (11a, 27a) to the image transmission panel 17 ( 11, 27), a stereoscopic two-dimensional image display method in an apparatus (100, 150, 200, 250, 300, 350) provided with an individual display unit (11, 27) and an image transmission panel 17 Since the three-dimensional two-dimensional images are displayed in space by individually setting the separation distances of the two, the conventional imaging plane is placed in the viewing direction of the observer. Multiple can be arranged, Imaging surface 21a of respectively, by displaying an image based on the perspective to 21b, it is possible to greatly improve the stereoscopic effect as compared with the prior art.

It is a figure which shows the structure of the three-dimensional two-dimensional image display apparatus which concerns on 1st Embodiment. It is an AA arrow line view of FIG. It is a figure which shows the structure of the three-dimensional two-dimensional image display apparatus which concerns on 2nd Embodiment. It is a figure which shows the structure of the three-dimensional two-dimensional image display apparatus which concerns on 3rd Embodiment. It is a figure which shows the structure of the three-dimensional two-dimensional image display apparatus which concerns on 4th Embodiment. It is a figure which shows the structure of the three-dimensional two-dimensional image display apparatus which concerns on 5th Embodiment. It is a figure which shows the structure of the three-dimensional two-dimensional image display apparatus which concerns on 6th Embodiment. It is a block diagram which shows schematic structure of a video signal supply part. It is explanatory drawing showing the example of an image | video displayed on a 1st display part and a 2nd display part. FIG. 10 is an explanatory diagram showing an image observed by an observer when the image of FIG. 9 is formed on the imaging plane. It is operation | movement explanatory drawing at the time of utilizing a DFD system for the three-dimensional two-dimensional image display apparatus which concerns on this invention. It is a block diagram of an image transmission panel.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 1st display part 11a, 27a, 33a Image display surface 13a, 13b Three-dimensional two-dimensional image 17 Image transmission panel 19 Half mirror 21b Image formation surface near an observer 21a Image formation surface far from an observer 23 Micro convex lens (lens)
25 Microlens array 27 Second display unit 33 Light transmissive second display unit 100, 150, 200, 250, 300, 350 Stereoscopic two-dimensional image display device

Claims (12)

A microlens array that inverts incident light and then emits it to form a stereoscopic two-dimensional image that is an erecting equal-magnification image on one optical axis;
A plurality of display units that include an image display surface that is spaced apart from the microlens array on the one optical axis and displays a two-dimensional image, and that emits light from the image display surface to the microlens array. When,
A video signal supply unit that distributes a video signal that is a source of the stereoscopic two-dimensional image and supplies the video signal to each of the plurality of display units;
With
The microlens array has a range, not a single working distance for imaging light,
The distance between each of the display units and the microlens array is individually set, thereby displaying a plurality of stereoscopic two-dimensional images in space.
The video signal supply unit performs control so as to individually change each video signal supplied to the plurality of display units,
The plurality of display units are arranged to be inclined from a vertical plane with respect to the one optical axis,
A three-dimensional two-dimensional image display device, wherein each of the plurality of three-dimensional two-dimensional images is set so that the image planes thereof are not parallel to each other and intersect each other . The microlens array is
The stereoscopic two-dimensional image display device according to claim 1, comprising a plurality of lenses arranged two-dimensionally, and each of the plurality of lenses comprising at least a pair of convex lenses arranged coaxially. The stereoscopic two-dimensional image display device includes:
2. The apparatus according to claim 1, further comprising means for transmitting light from the display unit and reflecting light from the other display units to combine the plurality of display units on the one optical axis. 3. A stereoscopic two-dimensional image display device according to 2.   The at least one display unit among the plurality of display units has a light transmission property from a surface facing the image display surface toward the image display surface. Stereoscopic two-dimensional image display device.   5. The stereoscopic two-dimensional image according to claim 1, further comprising a display unit on the one optical axis opposite to the display unit across the microlens array. 6. Display device. The microlens array is
6. The stereoscopic two-dimensional image display device according to claim 1, wherein the stereoscopic two-dimensional image display device has an imaging position variable function. A microlens array that inverts incident light and then emits it to form a stereoscopic two-dimensional image that is an erecting equal-magnification image on one optical axis;
A plurality of display units that include an image display surface that is spaced apart from the microlens array on the one optical axis and displays a two-dimensional image, and that emits light from the image display surface to the microlens array. When,
A video signal supply unit that distributes a video signal that is a source of the stereoscopic two-dimensional image and supplies the video signal to each of the plurality of display units;
A stereoscopic two-dimensional image display method in an apparatus comprising:
The microlens array has a range, not a single working distance for imaging light,
By individually setting the separation distance between each of the display units and the microlens array, a plurality of stereoscopic two-dimensional images are displayed in space,
The video signal supply unit performs control so as to individually change each video signal supplied to the plurality of display units,
The plurality of display units are arranged to be inclined from a vertical plane with respect to the one optical axis,
A method of displaying a stereoscopic two-dimensional image, characterized in that each of the plurality of stereoscopic two-dimensional images is set so that the image planes thereof are not parallel to each other and intersect each other .   The stereoscopic two-dimensional image display method according to claim 7, wherein an image drawn by perspective is displayed on the display unit.   Of the images formed on a plurality of imaging planes, a near-field image is displayed large on the imaging plane close to the observer, and a distant image is displayed small on the imaging plane far from the observer. The stereoscopic two-dimensional image display method according to claim 7 or 8.   The stereoscopic two-dimensional image display method according to any one of claims 7 to 9, wherein when a moving image is displayed, a near-field object moves fast and a distant object moves slowly.   The three-dimensional two-dimensional image display method according to any one of claims 7 to 10, wherein the same object image is displayed simultaneously or continuously on the front and back imaging planes in a plurality of imaging planes.   The stereoscopic display according to any one of claims 7 to 11, wherein a luminance modulation type stereoscopic display image is displayed by overlapping and displaying a plurality of stereoscopic two-dimensional images displayed in the space with a luminance difference. Two-dimensional image display method.

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