The present disclosure relates to the subject matter contained in Japanese Patent Application No. 2004-043554 filed on Feb. 19, 2004, which is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to a stereoscopic two-dimensional image display system and a stereoscopic two-dimensional image display method for displaying a two-dimensional image stereoscopically.
2. Description of the Related Art
In recent years, with respect to interior design appliances, displays for sales promotion, communication terminal devices, game apparatuses, and the like, various attempts have been made to stereoscopically reproduce image information by various methods for the purpose of improving realism, visibility, and amusement features. Generally, binocular parallax (a difference in visual directions or a disparity in retinal images between both eyes occurring when a solid or an object of a different depth is viewed with both eyes) is one physiological factor allowing a human being to view an object stereoscopically. As a method of reproducing a stereoscopic image on the basis of this binocular parallax, a polarization method is known in which a viewer wears polarized glasses and views left and right disparity images based on mutually different polarized states. However, the wearing of the polarized glasses constitutes a troublesome drawback to the viewer.
In contrast, as a method of displaying a stereoscopic image which does not use polarized glasses, a lenticular lens method is known. This is a technique in which a plurality of screens are formed as latent images on one screen, the plurality of screens are viewed through a translucent screen in which semicylindrical lenses of fixed widths are connected in the horizontal direction, so as to enable stereoscopic representation or representation of moving images. Namely, images which are obtained by dividing each of the plurality of images into stripes in the vertical direction in correspondence with the pitches of the semicylindrical lenses are arrayed regularly, and stereoscopic vision is realized on the basis of the focal position of each lens which changes due to the direction in which the screen is viewed and the distance and on the basis of how the image disposed there is viewed. Specifically, for the reproduction of a stereoscopic image, alternately arrayed stripe images are supplied to both eyes of the viewer from two left and right disparity images corresponding to both eyes of the viewer by using the lenticular lenses, so as to allow a stereoscopic image to be recognized (e.g., see JP-A-10-221644).
With the above-described lenticular lens method, since a plurality of screens are formed as latent images on one screen, disparity images corresponding to both eyes of the viewer are required from the imaging step. To supply these images, much operation is required, including such as computer image processing, lenticular lens design, and the operation of accurate combination of the lenses and the image. Accordingly, a display for displaying a stereoscopic two-dimensional image using lenticular lenses tends to be expensive.
To overcome such a drawback, an image display apparatus has been proposed for displaying a stereoscopic two-dimensional image with a simple construction by allowing a two-dimensional image to be formed as a real image by microlens arrays. As shown in
The above-described image display apparatus 1 is capable of easily displaying a two-dimensional image stereoscopically. However, since the display is provided by one display unit 3 alone, even if a two-dimensional image is displayed as a stereoscopically formed image, the image tends to be an isolated image which is unrelated to the surroundings, and the rendering power for visually perceiving the difference in depth has been insufficient. As a result, there has been a limit to the more natural display of stereoscopic two-dimensional images, and it has been impossible to obtain sufficient realism, visibility, and amusement features.
The invention has been devised in view of the above-described circumstances, and one of objects of the present invention is to provide a stereoscopic two-dimensional image display apparatus and a stereoscopic two-dimensional image display method which make it possible to yield a large difference in depth, obtain high rendering power, and display a stereoscopic two-dimensional image more naturally, thereby further improving realism, visibility, and amusement features.
According to a first aspect of the invention, there is provided a stereoscopic two-dimensional image display apparatus including: a display unit having an image display surface for displaying a two-dimensional image; an image transmission panel which has a microlens array disposed in spaced-apart relation to the image display surface, and forms a stereoscopic two-dimensional image by allowing the light emergent from the image display surface by the microlens array; and a two-dimensional image direct viewing panel having an image display surface disposed in an arbitrary space on at least one of upper, lower, left, and right sides relative to the stereoscopic two-dimensional image.
According to a second aspect of the invention, there is provided a stereoscopic two-dimensional image display method including: causing a two-dimensional image displayed on an image display surface of a display unit to form an image by a microlens array disposed in spaced-apart relation to the image display surface, so as to display a stereoscopic two-dimensional image in front of the image display surface; and displaying an image on an image display surface of a two-dimensional image direct viewing panel disposed in an arbitrary space on at least one of upper, lower, left, and right sides relative to the stereoscopic two-dimensional image.
The above objects and advantages of the present invention will become more apparent by describing in detail preferred exemplary embodiments thereof with reference to the accompanying drawings, wherein:
Hereafter, a description will be given of preferred embodiments of a stereoscopic two-dimensional image display apparatus and a stereoscopic two-dimensional image display method in accordance with the invention.
A stereoscopic two-dimensional image display apparatus 100 in accordance with this embodiment has an image display device 21 and a two-dimensional image direct viewing panel 23 as its principal members. In
As will be described later in detail, the image display device 21 includes an image transmission panel 29 having a microlens array 43 (see
In this embodiment, as shown in
In
As for another configuration allowing the two-dimensional image direct viewing panel 23 to be disposed uprightly or horizontally in front of the image display device 21, as shown in
In addition, as shown in
The image display device 21, if largely classified, consists of a display unit 27 and the image transmission panel 29. The display unit 27 has, for example, a color liquid-crystal display (LCD) 31 as its principal member. The LCD 31 has a planar image display surface 31a for displaying a two-dimensional image including a stereoscopic image. The LCD 31 is provided with a flat color liquid-crystal panel 33 for the image display surface 31a, a backlight illuminating portion 35, and a color liquid-crystal drive circuit 37. The color liquid-crystal drive circuit 37 is connected to a video signal supplying unit 39 for supplying a video signal for the two-dimensional image including the stereoscopic image. As the display unit 27, a cathode ray tube, a plasma display, an organic electroluminescence display, or the like may be used instead of the LCD 31.
A support member 41 is fixed to peripheral edges of the LCD 31, and the support member 41 supports the image transmission panel 29. The image transmission panel 29 consists of the microlens array 43 and a lens frame 45 surrounding an effective area of the microlens array 43. The support member 41 supports the lens frame 45, and disposes the image transmission panel 29 in spaced-apart relation to the image display surface 31a of the color liquid-crystal panel 33.
The effective area of the microlens array 43 is set to be identical to the area of the image display surface 31a of the color liquid-crystal panel 33. The lens frame 45 has a dark color such as black, and suppresses the degree by which the viewer becomes conscious of the presence of the microlens array 43.
The microlens array 43 is composed of a plurality of microlenses arranged two-dimensionally. The microlens array 43 is a convex microlens plate formed by integrating two lens array halves 47a and 47b as a set. In the convex microlens plate, a plurality of lens systems each consisting of a pair of convex lenses with their optical axes arranged coaxially are arranged two-dimensionally so that their optical axes become parallel to each other.
It should be noted that the display unit 27 and the microlens array 43 which are shown in the above-described embodiment need not necessarily be disposed in parallel to each other.
The curvature of convex lenses 51 formed on the left-side surface of the left lens array half 47a in
When the microlens array 43 is disposed in parallel to the front surface of the display unit 27 (see
It should be noted that the two-dimensional image displayed on the display unit 27 is temporarily inverted vertically when it passes through one lens array half 47b, but the two-dimensional image is inverted again when it passes through the other lens array half 47a. As a result, the image transmission panel 29 is capable of causing the two-dimensional image displayed on the display unit 27 to be displayed on the image forming plane 53 as an erect stereoscopic two-dimensional image.
It should be noted that the microlens array 43 shown in the above-described embodiment is formed by integrating the two lens array halves 47a and 47b as a set, the invention is not necessarily limited to this arrangement, and the microlens array 43 may be formed by a single lens array half. In such an arrangement, however, since the two-dimensional image which is formed by each of the lenses making up the microlens array half is displayed inversely, it is necessary to arrange the microlens array half such that one lens is allotted to each of the display pixels of the display unit 27.
As shown in
An unillustrated control unit is connected to the video signal supplying unit 39 and the video signal supplying unit 57, and the control unit controls respective display modes of the video signals transmitted to these video signal supplying units as well as the disposed attitude of the two-dimensional image direct viewing panel 23. Namely, as shown in
Next, a description will be given of the operation of the above-described stereoscopic two-dimensional image display apparatus.
In the stereoscopic two-dimensional image display apparatus 100, as shown in
Meanwhile, if the two-dimensional image direct viewing panel 23 is rotated by the rotating shaft 25 (see
In consequence, while during the normal two-dimensional image display mode only the two-dimensional image direct viewing panel 23 can be driven to effect display, during the stereoscopic two-dimensional image display mode the two-dimensional image direct viewing panel 23 can be used as an auxiliary display device for stereoscopic display. Thus the visibility effect can be increased while enhancing the efficiency of utilizing the two-dimensional image direct viewing panel 23. In addition, since during the normal two-dimensional image display mode the image transmission panel 29 can be covered by erecting the two-dimensional image direct viewing panel 23, the effect of protecting the image transmission panel 29 is produced. Also, it becomes possible to view only the image displayed on the two-dimensional image direct viewing panel 23 by shielding the stereoscopic two-dimensional image from the field of view, as required.
Therefore, according to the above-described stereoscopic two-dimensional image display apparatus 100, there are provided the image transmission panel 29 which stereoscopically displays a two-dimensional image by causing the light emitted from the image display surface to form an image by the microlens array 43 disposed in spaced-apart relation to the image display surface, as well as the two-dimensional image direct viewing panel 23 whose image display surface 23a is disposed in an arbitrary one of upper, lower, left, and right planes relative to the stereoscopic two-dimensional image (formed image), and on which an image associated with the stereoscopic two-dimensional image (formed image) is displayed. As such, as the stereoscopic two-dimensional image (formed image) and its associated image on the two-dimensional image direct viewing panel 23 are interlocked, the stereoscopic two-dimensional image (formed image) and its surrounding scene are integrated. Thus it is possible to further improve the stereoscopic visual effect, and obtain high rendering power for expressing different depths. As a result, it is possible to further improve realism, visibility, and amusement features.
In addition, according to the stereoscopic two-dimensional image displaying method, a two-dimensional image is formed by the microlens array 43 and is displayed stereoscopically, and an image associated with the stereoscopic two-dimensional image (formed image) is displayed on the image display surface 23a of the two-dimensional image direct viewing panel 23 disposed in an arbitrary one of upper, lower, left, and right planes relative to the stereoscopic two-dimensional image (formed image). Therefore, by interlocking the stereoscopic two-dimensional image (formed image) and its associated image on the two-dimensional image direct viewing panel 23, the stereoscopic two-dimensional image (formed image) and its surrounding scene can be incorporated as an integral stereoscopic image, making it possible to further improve the stereoscopic visual effect. As a result, it is possible to obtain high rendering power for expressing different depths, and further improve realism, visibility, and amusement features.
Next, a description will be given of a stereoscopic two-dimensional image display apparatus in accordance with a second embodiment of the invention.
A stereoscopic two-dimensional image display apparatus 200 in accordance with this embodiment has the same configuration as that of the above-described stereoscopic two-dimensional image display apparatus 100, but its displaying method differs from that of the above-described stereoscopic two-dimensional image display apparatus 100. Namely, with the stereoscopic two-dimensional image display apparatus 200 in accordance with this embodiment, for instance, a fairy 71, i.e., a stereoscopic two-dimensional image, and its shadow 73, which is displayed on the two-dimensional image direct viewing panel, are displayed in different sizes while being moved.
Therefore, according to this stereoscopic two-dimensional image display apparatus 200, the size and the display position (moving closer to or away from the viewer) of the shadow displayed on the two-dimensional image direct viewing panel change in interlocking relation to the display size of the fairy which is a stereoscopic two-dimensional image, as shown in
Next, a description will be given of a stereoscopic two-dimensional image display apparatus in accordance with a third embodiment of the invention.
In a stereoscopic two-dimensional image display apparatus 300 in accordance with this embodiment, two-dimensional image direct viewing panels 23A, 23B, 23C, and 23D are disposed in all of the upper, lower, left, and right planes relative to the stereoscopic two-dimensional image (formed image). An arbitrary one, e.g., 23A, of the four two-dimensional image direct viewing panels 23A, 23B, 23C, and 23D is provided rotatably by means of the rotating shaft 25, and the other three panels, 23B, 23C, and 23D, are fixedly provided.
In this stereoscopic two-dimensional image display apparatus 300, as the plurality of two-dimensional image direct viewing panels 23A, 23B, 23C, and 23D are provided on the upper, lower, left, and right sides of a stereoscopic two-dimensional image (formed image) 80, all the surrounding scenes encompassing the stereoscopic two-dimensional image (formed image) can be interlocked as associated images. For example, as in the illustrated example, lanes 81 are displayed on the two-dimensional image direct viewing panel 23A for the automobile 80 of the stereoscopic two-dimensional image, rows of trees 83 on the two-dimensional image direct viewing panels 23B and 23D, and clouds 85 on the two-dimensional image direct viewing panel 23C. As a result, all the surrounding planes encompassing the stereoscopic two-dimensional image (formed image) are effectively utilized, and the stereoscopic visual effect is enhanced to a maximum.
Therefore, according to this stereoscopic two-dimensional image display apparatus 300, it is possible to obtain optimum rendering power for expressing different depths, and maximally improves realism, visibility, and amusement features. In addition, it is possible to realize with a simple structure the arrangement in which the stereoscopic two-dimensional image (formed image) is encompassed by the upper, left, left, and right two-dimensional image direct viewing panels 23A, 23B, 23C, and 23D, and one panel 23A among them is disposed uprightly in front of the image transmission panel 29. Furthermore, when one two-dimensional image direct viewing panel 23A is disposed uprightly, the space for forming the stereoscopic two-dimensional image (formed image) can be hermetically sealed, so that it is also possible to obtain the dust-proofing effect for preventing the entry of dust or the like into the space for forming the stereoscopic two-dimensional image (formed image).
Although the present invention has been shown and described with reference to specific preferred embodiments, various changes and modifications will be apparent to those skilled in the art from the teachings herein. Such changes and modifications as are obvious are deemed to come within the spirit, scope and contemplation of the invention as defined in the appended claims.
Number | Date | Country | Kind |
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P2004-043554 | Feb 2004 | JP | national |