JP6604493B2 - Stereoscopic image display device and terminal device - Google Patents

Description

  The present invention relates to a device for displaying a stereoscopic image, and more particularly to a stereoscopic image display device that displays an image corresponding to each of a plurality of viewpoints, a terminal device including the device, a stereoscopic image display method, and a program thereof.

  2. Description of the Related Art Conventionally, there are stereoscopic image display devices that realize stereoscopic viewing without glasses by providing different images toward a plurality of viewpoints and projecting images with different parallaxes on the left and right eyes of an observer.

  As a stereoscopic image display method in the apparatus, image data for respective viewpoints are combined and displayed on a display unit, and the displayed combined image is optically composed of a barrier (light-shielding plate) having a lens and a slit. A system is known in which separation is performed by separation means (optical separation means) and these are provided to each viewpoint of an observer.

  As the optical separation means employed here, a parallax barrier composed of a barrier having a large number of striped slits or a lenticular lens in which cylindrical lenses having a lens effect in one direction are arranged is generally employed.

  In a stereoscopic image display device that adopts such a display method, it is necessary to project appropriate parallax images to the left and right eyes of the observer, so the spatial area (stereoscopic viewing area) in which the observer can visually recognize a stereoscopic image normally is It will be limited. Therefore, if the positions of the left and right eyes of the observer deviate from this stereoscopic viewing area, the presence of a crosstalk area where the parallax images overlap and a double image is visually recognized and a reverse viewing area where each parallax image is projected in reverse This causes a problem that an appropriate stereoscopic image cannot be visually recognized.

  One method for improving this problem is to detect the position of the observer's eyes and to perform parallax image switching control using this detection result. Display devices that improve the visibility of stereoscopic images in a reverse viewing region are known (for example, Patent Documents 1 to 5).

  In Patent Document 1, in a stereoscopic display device in which the resolution of a parallax barrier is doubled, there is a technical content of performing parallax barrier control and image switching control when an observer is positioned in a crosstalk region or a reverse viewing region. It is disclosed. In addition, the display device in Patent Document 2 includes a light source unit that has four times the resolution of 3D resolution on the backlight side and a light source control unit that controls the light source unit. Here, the light source that constitutes the light source unit The technical content that the light beam control unit switches and controls the function according to the observer position is disclosed.

  That is, Patent Documents 1 and 2 disclose a display device that presents an image with less discomfort according to the position of the detected observer by providing a light distribution unit that exceeds the resolution of the display panel. In the display device, the countermeasure for reverse vision is taken by increasing the number of device viewpoints (the number of areas on which so-called parallax images are projected) determined by the relationship between the display panel and the light beam separating means.

  In the image display device in Patent Document 3, when it is detected that there are a plurality of observers, an uncomfortable feeling at the time of visual recognition is suppressed by a technique of outputting a 2D image by turning off the parallax barrier function. Further, in the stereoscopic image display device disclosed in Patent Document 4, the discomfort is reduced by a technique for controlling the amount of parallax according to the position of the observer.

  In Patent Document 5, the lobe control means configured to include a parallax barrier performs stereoscopic viewing area switching control, so that even when tracking is not used, side lobes are used to achieve multiple viewpoints. The technical content of realizing is disclosed. Further, in the stereoscopic display device here, due to the technology combining tracking and processing by the lobe control means, the viewer feels uncomfortable in a state where one eye of the observer is located in the main lobe and the other eye is located in the side lobe. We are trying to reduce it.

Japanese Patent Laid-Open No. 10-333091 JP 2011-215499 A JP 2012-120194 A JP 2012-60607 A JP 2005-91447 A

  However, the following problems also exist in the display device according to each of the above patent documents that employs parallax image switching control based on the detection result of the binocular position of the observer.

  In the display device disclosed in Patent Document 1 or 2, a high-definition light separation means having a resolution twice or more that of the display panel is required, which causes a problem of an increase in structure or manufacturing cost. Further, although predetermined image processing can be performed within the range of the number of device viewpoints, there is a disadvantage that only repeated images can be viewed at a viewing angle exceeding the number of device viewpoints.

  Patent Documents 3 and 4 disclose an image display device that has a configuration for effectively acting within the number of device viewpoints, that is, a countermeasure technique for suppressing image quality degradation in a reverse viewing region. Since nothing is employed, there is a problem that in the reverse viewing region, a sense of incongruity occurs during visual recognition. Further, in Patent Document 5, since the parallax barrier is provided in the lobe control means, there is a disadvantage that the transmittance is low.

(Object of invention)
An object of the present invention is to provide a stereoscopic image display device and a terminal device that improve the inconveniences of the related art and generate and display a significant parallax image corresponding to the position of an observer.

  In order to achieve the above object, in the stereoscopic image display device according to the present invention, a display panel in which a plurality of pixels are arranged, and a plurality of pixels according to the arrangement direction of the pixels provided on the display surface side of the display panel. A stereoscopic image display panel comprising: a light beam separating means for separating a parallax image from each pixel toward N viewpoints (N is a natural number of 2 or more); and an observation position of an observer facing the display surface An observer position measurement unit that measures the relative position of the observer based on the measurement result, a relative position calculation unit that calculates the relative position of the observer with respect to the stereoscopic image display panel, and a preset J viewpoint (J> N) Image generation processing having a function of generating a viewpoint image, generating one or more viewpoint images corresponding to each viewpoint constituting the N viewpoints in association with the relative position, and outputting the generated images to the stereoscopic image display panel And the Then, when the number N of viewpoints is 3 or more, the image generation processing unit sets a viewpoint image to a viewpoint area where none of the left and right eyes of the observer is located in the moving direction of the observer. And selecting the selected viewpoint image for output to the stereoscopic image display panel.

  In addition, the terminal device according to the present invention has a configuration in which the stereoscopic image display device that displays an image corresponding to each of a plurality of viewpoints and a casing that includes the stereoscopic image display device are included.

  Furthermore, in the stereoscopic image display method according to the present invention, a display panel in which a plurality of pixels are arranged, and a plurality of N viewpoints (N is 2 or more) provided on the display surface side of the display panel according to the arrangement direction of the pixels. 3D natural number), a stereoscopic image display panel including a light beam separating means for separating a parallax image from each pixel, an observer position measuring unit for measuring the position of the observer facing the display surface, and the measurement result And a display controller that generates the parallax image according to the three-dimensional image display device, wherein the observer position measurement unit measures the observation position of the observer, and the stereoscopic image display is performed based on the measurement result The display controller calculates the relative position of the observer with respect to the panel, and the display controller generates viewpoint images for J viewpoints (J> N) set in advance, and the generated viewpoint images. A plurality of viewpoint images to identify said display controller in accordance with the relative position from within, a plurality of viewpoint images obtained by this particular the display controller and outputs toward the three-dimensional image display panel.

  In the stereoscopic image display program according to the present invention, a display panel in which a plurality of pixels are arranged, and a plurality of N viewpoints (N is two or more) provided on the display surface side of the display panel according to the arrangement direction of the pixels. 3D natural number), a stereoscopic image display panel including a light beam separating means for separating a parallax image from each pixel, an observer position measuring unit for measuring the position of the observer facing the display surface, and the measurement result And a display controller that generates the parallax image in response to an observer measuring means for measuring the observation position of the observer, and the stereoscopic image display panel based on the measurement result. An observer position calculation means for calculating the relative position of the observer, and after generating viewpoint images for preset J viewpoints (J> N), the relative position is generated from the generated viewpoint images. A plurality of corresponding viewpoint images are specified, and a computer provided in advance in the display controller is caused to function as an image generation processing unit that outputs the specified plurality of viewpoint images toward the stereoscopic image display panel. Features.

  According to the present invention, it is possible to provide a stereoscopic image display device and a terminal device that particularly generate and display a significant parallax image corresponding to the position of the observer.

It is a block diagram which shows the function structure of the stereo image display apparatus in 1st Embodiment of this invention. It is the schematic which shows the structural example of the stereo image display apparatus disclosed in FIG. FIG. 3 shows an example of image information for two viewpoints input to each viewpoint pixel included in the stereoscopic image display device disclosed in FIG. 1, and FIG. 3A is a first viewpoint image, and FIG. Is a diagram corresponding to a second viewpoint image. It is a figure which shows an example of the production | generation method of the image for 1st viewpoints shown in FIG. 3, and the image for 2nd viewpoints. It is a figure which shows the state of the light ray separation by the three-dimensional image display panel disclosed in FIG. 1, and a three-dimensional viewing area. It is a figure which shows the state of light beam separation by the stereoscopic image display panel disclosed in FIG. FIGS. 7A and 7B show an example of image information input to the two-viewpoint stereoscopic image display panel disclosed in FIG. 1, FIG. 7A is a first viewpoint image, FIG. 7B is a second viewpoint image, 7C corresponds to the third viewpoint image, FIG. 7D corresponds to the fourth viewpoint image, FIG. 7E corresponds to the fifth viewpoint image, and FIG. 7F corresponds to the sixth viewpoint image. FIG. It is a figure which shows an example of the production | generation method of the image for 6th viewpoints from the image for 1st viewpoints shown in FIG. FIG. 9 is a situation diagram showing the relationship between the state of light separation by the stereoscopic image display panel disclosed in FIG. 1 and the binocular position of the observer. FIG. 9A shows the first viewpoint region 50a for the left eye and the right eye for 9B, the left eye is in the first viewpoint area 51b and the right eye is in the second viewpoint area 50a, and FIG. 9C is the first eye in the second viewpoint area 50b. A case where the region 51a and the right eye are present in the second viewpoint region 51b is shown. FIG. 10C is an enlarged view of FIG. 9C and exemplifies each sub-region provided by dividing the first viewpoint region into four. FIG. 10 is a table showing a correspondence relationship between viewpoint areas in which the left and right eyes of the observer are located and image data to be displayed in the first viewpoint area and the second viewpoint area based on each stereoscopic viewing area disclosed in FIG. 9. is there. It is a figure which shows the state of the ray separation by the general | schematic 6 viewpoint stereoscopic image display panel. It is a figure which shows the state of the light ray separation by the three-viewpoint stereoscopic image display panel in 1st Embodiment. It is a figure which shows an example of the image data input into the stereo image display panel of 3 viewpoints in FIG. 13, and the stereo image display panel in 2nd and 3rd embodiment. As shown in FIG. 13, when the observer moves in the negative direction of the x-axis, a table showing the relationship between the viewpoint areas where the left and right eyes are located and the image data of the first to third viewpoint areas. It is. FIG. 14 is a table showing the relationship between the viewpoint area where each of the left and right eyes is located and the image data of the first to third viewpoint areas when the observer shown in FIG. 13 moves in the positive direction of the x axis. . It is a figure which shows the state of the light ray separation by the 4 viewpoint stereo image display panel in 1st Embodiment. FIG. 18 is a table showing a relationship between viewpoint areas where the left and right eyes are located and image data of the first to fourth viewpoint areas when the observer shown in FIG. 17 moves in the negative direction of the x axis. . FIG. 18 is a table showing a relationship between viewpoint areas where the left and right eyes are located and image data of the first to fourth viewpoint areas when the observer shown in FIG. 17 moves in the positive direction of the x axis. . 3 is a flowchart illustrating an operation of the stereoscopic image display device disclosed in FIG. 1. It is a figure which shows the state of the light ray separation by the stereo image display panel of 2 viewpoints in 2nd Embodiment. It is a figure which shows the 3D crosstalk characteristic in the center part of the display surface of the stereo image display panel disclosed in FIG. FIG. 23 is a diagram illustrating a viewpoint region where left and right eyes are located when an observer moves to the minus side in the x-axis direction from the state disclosed in FIG. 22. 24 is a table showing the relationship between the viewpoint area where the left and right eyes of the observer are located and the image data of the first viewpoint area and the second viewpoint area based on the observer position disclosed in FIG. As a comparative example of FIG. 23, a stereoscopic image display panel having a relationship of “d <e (observer's binocular interval: d, viewpoint pitch between the first viewpoint area and the second viewpoint area: e)” is used. It is a figure which shows the viewpoint area | region where the left and right eyes of an observer are located. FIG. 26 is a table showing a relationship between a viewpoint area where the left and right eyes of the observer are located and image data of the first viewpoint area and the second viewpoint area based on the observer position disclosed in FIG. 25. It is a figure which shows the state of the light beam separation by the 4 viewpoint stereo image display panel in 3rd Embodiment. It is a figure which shows the positional relationship of an observer and each viewpoint area | region when an observer moves to the minus direction side to the x-axis. FIG. 29 is a table showing a relationship between a viewpoint area where the left and right eyes of the observer are located and image data from the first viewpoint area to the fourth viewpoint area based on the observer position of FIG. 28. It is the schematic which shows the structure of the stereo image display panel concerning 4th Embodiment of this invention. Among the diagrams showing the pixels in which the sub-pixels composed of the four primary colors are arranged in a matrix, FIG. 31 (a) is a diagram showing the positional relationship between the pixels composed of 4 × 4 sub-pixels and the lens elements. FIG. 31B is a diagram showing a state in which the pixels and lens elements disclosed in FIG. 31A are arranged in a matrix. It is a figure which shows the pixel and lens array element of a 4x4 sub pixel structure in the 1st arrangement | positioning state disclosed to Fig.31 (a). FIG. 33 is a diagram illustrating a relationship between an input image and sub-pixels (sub-pixel groups) when the pixel and lens array elements disclosed in FIG. 32 are rotated 90 degrees to the right. It is a figure which shows the light beam separation at the time of separating an image only to one direction using the active light beam separation means corresponding to the pixel of 4x4 sub pixel structure disclosed to Fig.31 (a). It is a figure which shows the relationship between the position of the observer corresponding to FIG. 34, and 3D crosstalk characteristic. FIG. 36 is a diagram showing a relationship between a viewpoint area where the left and right eyes of the observer are located and image data of the first viewpoint area and the second viewpoint area based on the observer position disclosed in FIG. 35. Based on the 4 × 4 sub-pixel configuration and the lens array element disclosed in FIG. 31A, FIG. 37A shows the input image and sub-pixel (sub-pixel group) in the first arrangement state. FIG. 37B is a diagram illustrating the relationship between the input image and the sub-pixel (sub-pixel group) in the second arrangement state. FIG. 38 is a diagram illustrating an example of image information input to a 2 × 2 viewpoint stereoscopic image display panel including the pixels disclosed in FIG. 37. It is a figure which shows the light beam separation at the time of separating an image into two directions using the active light beam separation means corresponding to the pixel of the 4 × 4 sub-pixel configuration disclosed in FIG. FIG. 40 is a diagram illustrating a relationship between a viewpoint area where the left and right eyes of the observer are located and image data of the first viewpoint area and the second viewpoint area based on the observer position disclosed in FIG. 39. It is the schematic which shows the terminal device which includes the three-dimensional image display apparatus concerning 4th Embodiment of this invention. It is a block diagram which shows the function structure of the three-dimensional image display apparatus in 4th Embodiment of this invention. 43 is a flowchart illustrating an operation of the stereoscopic image display device disclosed in FIG. It is a figure which shows a mode that the image corresponding to each of two directions according to a viewer's position is shown to this observer using the stereoscopic image display apparatus which has the light beam separation means of one direction disclosed in FIG. FIG. 45 is a diagram showing a relationship between a viewpoint area where the left and right eyes of the observer are located and image data of the first viewpoint area and the second viewpoint area in association with each position of the observer disclosed in FIG. 44.

[First Embodiment]
1st Embodiment of the stereo image display apparatus concerning this invention is described based on FIG. 1 thru | or FIG.

(Overall configuration)
As illustrated in FIG. 2, the stereoscopic image display apparatus 1 that displays an image corresponding to each of a plurality of viewpoints is provided with a camera capable of capturing visible light and infrared light, and measures the position of the observer 100. Unit 45, a display controller (not shown) that generates 3D data based on the measurement result acquired from the observer position measuring unit 45, and an image based on 3D data and control signals output from the display controller. A stereoscopic image display panel 10 that separates and emits.

The stereoscopic image display panel 10 includes a display panel 11 in which pixels including at least sub-pixels that display an image for a first viewpoint and sub-pixels that display an image for a second viewpoint are arranged in a matrix, and the display panel 11 is provided on the display surface side, and separates the parallax images from the pixels toward each viewpoint.
The light beam separating unit 12 employs a configuration in which lenses 15 corresponding to the respective pixels arranged on the display panel 11 are arranged in an array, so that each viewpoint image can be separated in a predetermined different direction. it can.

With this configuration, the stereoscopic image display panel 10 can project different images toward at least two viewpoints, that is, perform light beam separation.
With respect to the direction of the light beam separation, as shown in FIG. 2, the arrangement direction of the lenses 15 (first pixel arrangement direction) is the x axis, and the direction extending from the display panel 11 to the viewer 100 is perpendicular to the x axis. A direction (second pixel arrangement direction) perpendicular to the axis and both the x-axis and the z-axis is defined as the y-axis. In addition, the intersection (origin) of these axes is assumed to be located at the center of the stereoscopic image display panel 10, and is hereinafter also referred to as the origin (display surface center) of the stereoscopic image display panel 10. In this case, a straight line connecting the left eye 101 and the right eye 102 of the observer 100 is in a state substantially parallel to the x axis.

  The observer position measurement unit 45 is configured to take an image of the observer 100 with a camera provided therein and measure the positions of the left eye 101 and the right eye 102 of the observer 100 based on the photographed image.

When the observer position measurement unit 45 measures the positions of both eyes (the left eye 101 and the right eye 102), various methods can be used.
For example, the position in the x and y axis directions is measured by detecting the position of the face and eyes from an image photographed with visible light using pattern matching, and the z axis is based on the interocular distance derived from the measurement result. The position in the z-axis direction is measured from the method of measuring the position or the time difference (phase difference) of the light flight until the observer 100 is irradiated with infrared sine wave light and the reflected sine wave light arrives at the camera. A method called a TOF method can be employed.

As the display panel 11, various electro-optical elements such as a liquid crystal display element, an organic electroluminescence display element, an electrophoretic element, and an electrochromic element can be used.
As the light beam separating means 12, in addition to an optical element such as a lenticular lens, a fly-eye lens, or a parallax barrier, a liquid crystal lens having a refractive index control function or an electro-optical element such as a liquid crystal barrier having a light shielding control function is used. Can be used. From the viewpoint of transmittance, lenticular lenses, fly-eye lenses, and liquid crystal lenses are preferable.

  First, in order to simplify the description, an example in which a two-viewpoint stereoscopic image display panel is employed as the stereoscopic image display panel 10 will be described. Here, the N-viewpoint stereoscopic image display panel (N is a natural number of 2 or more) refers to a stereoscopic image display panel that separates and emits two-dimensional image data having parallax for stereoscopic display toward the N viewpoint.

FIG. 3 illustrates image information for two viewpoints input to each viewpoint pixel of the stereoscopic image display panel 10. FIG. 3A shows a first viewpoint image 60a, and FIG. 3B shows a second viewpoint image 60b.
Between the viewpoint images, the size of the “5” surface of the dice and the size of the “3” surface are different. That is, between the viewpoint images, as shown in FIG. 3, the surface “5” is relatively large in (a) corresponding to the first viewpoint image 60a, and corresponds to the second viewpoint image 60b. (B) adopts a configuration in which the surface of “3” is relatively large.

Next, FIG. 4 shows an example of a method for generating the first viewpoint image and the second viewpoint image shown in FIG. FIG. 4 is an explanatory diagram relating to an imaging method called a crossing method. Here, the intersection 66 of the optical axes of the first viewpoint camera 65a and the second viewpoint camera 65b is on a normal screen, that is, a screen. Set to the playback position of the screen. The horizontal direction of the screen surface is the x-axis, the direction orthogonal to the x-axis is the y-axis (not shown), the direction orthogonal to the xy plane is the z-axis, and the intersection 66 is the origin where these axes intersect, The positive and negative directions on the x-axis and z-axis are as shown in FIG.
Here, the arrangement positions of the first viewpoint camera 65a and the second viewpoint camera 65b are set to have the same value on the y axis (so that the y coordinate values are equal: horizontal state).

  In this state, the 3D object 64 of the dice having the three-dimensional information of the xyz value is imaged by the first viewpoint camera and the second viewpoint camera (65a, 65b), so that FIG. 3 (a) and FIG. 3 (b). An image as shown in FIG.

  As shown in FIG. 3, the positions of corresponding points (corresponding points) are different between the images captured and generated in this way. That is, corresponding points (for example, each vertex of a dice) between FIG. 3A and FIG. 3B are different in both images, and this different size is the amount of parallax. The magnitude of the amount of parallax is determined by the camera position (x, z value), camera angle of view, camera interval, 3D object position (z value), and the like.

Next, FIG. 5 shows a state of light separation of the stereoscopic image display panel 10. This is a cross-sectional view of the zx plane when viewed from the positive direction of the y-axis. In FIG. 5, the left eye of the observer 100 is denoted as “L” and the right eye is denoted as “R”, and the same applies to the following drawings.
The first viewpoint areas 50a, 51a, 52a,... And the second viewpoint areas 50b, 51b, 52b,. The images are separated so as to repeat alternately along the direction.

  When each first viewpoint area (50a, 51a, 52a) is a left-eye area and each second viewpoint area (50b, 51b, 52b) is a right-eye area, for example, each first viewpoint area has a first Assuming that the viewpoint image 60a (FIG. 3) and the second viewpoint image 60b (FIG. 3) are projected on each second viewpoint area, the stereoscopic image display panel 10 displays the left eye on the left eye area 50a. 101 is configured to form a stereoscopic viewing area 80 where the viewer 100 can perceive a stereoscopic image when the right eye 102 is placed in the right eye region 50b (FIG. 5).

Here, the observer 100 is in a state of being separated from the stereoscopic image display panel 10 by the optimum observation distance (optimum viewing distance) OD that maximizes the stereoscopic viewing area.
The symbol e indicates the viewpoint pitch between the viewpoint regions at the optimum viewing distance. In FIG. 5, the viewpoint pitch e is equal to the binocular interval d. Reference numerals “1” and “2” correspond to the first viewpoint image 60a and the second viewpoint image 60b, respectively.

  Similarly, the stereoscopic image display panel 10 forms a stereoscopic viewing area 81 when both eyes of the observer 100 correspond to the left eye area 51a and the right eye area 51b based on a signal from the display controller or the like. The stereoscopic viewing area 82 is formed when both eyes of the observer 100 correspond to the left eye area 52a and the right eye area 52b.

  Here, a stereoscopic viewing area 80 including a z-axis extending perpendicularly from the display surface center (image display center) of the stereoscopic image display panel 10 is set as a main lobe, and an observer 100 is connected to the plus side in the x-axis from the main lobe. The stereoscopic viewing areas 81 and 82 that appear when moving in each direction on the minus side are defined as side lobes.

  In addition to the above two stereoscopic viewing areas, one corresponding to the position of the viewer 100 on each of the minus direction side on the x axis of the stereoscopic viewing area 81 and the plus direction side on the x axis of the stereoscopic viewing area 82 or The stereoscopic image display panel 10 may be configured so that a plurality of side lobes appear.

  In the region where the observer 100 is moving from the main lobe to the side lobe, the right eye region corresponds to the left eye 101 and the left eye region corresponds to the right eye 102 as shown in FIG. In this state, a reverse viewing region 85 is formed by the stereoscopic image display panel 10. At this time, the observer 100 perceives the second viewpoint image 60 b (2) with the left eye 101 and the right eye 102 with the first viewpoint image 60 a (1).

  Next, FIG. 1 shows each functional configuration of the stereoscopic image display apparatus 1 in the first embodiment. As shown in this block diagram, the stereoscopic image display device 1 has a function of driving the display panel 11 and a function of controlling the light beam separating unit 12 together with the display panel 11, the light beam separating unit 12, and the observer position measuring unit 45 described above. The display controller 24 is provided.

  The display controller 24 includes a relative position calculation unit 40 that calculates the relative positions of the left eye 101 and the right eye 102 of the observer 100 with respect to the stereoscopic image display panel 10 based on the measurement result (measurement information) by the observer position measurement unit 45. An image generation processing unit 30 that generates 3D data (parallax image) and a control signal based on position information (relative position information) from the relative position calculation unit 40, and 3D data from the image generation processing unit 30 Based on a display panel drive circuit (display panel drive unit) 21 that drives the display panel 11 based on this, and an image distribution control circuit (image that controls the operation of the light beam separating means 12 based on a control signal from the image generation processing unit 30). A distribution control unit) 22.

  More specifically, based on the measurement information from the observer position measurement unit 45, the relative position calculation unit 40 is a coordinate value (x1, x1) indicating the relative position of the left eye 101 of the observer 100 with respect to the origin of the stereoscopic image display panel 10. y1, z1) and a coordinate value (x2, y2, z2) indicating the relative position of the right eye 102 with respect to the origin (see FIG. 2). Further, for example, a functional configuration for calculating the viewing angle θ1 (= atan (x1 / z1)) of the left eye 101 from these calculated values may be provided in the relative position calculation unit 40.

  The image generation processing unit 30 includes a computing unit 31 that executes image processing, a data storage unit 32 that stores display target data to be displayed on the display panel 11, and a memory 33 that stores an operation control program of the computing unit 31. And an external IF (Interface) 34 that mediates exchange of information with the outside. Since each of these components functions effectively, the image generation processing unit 30 can generate significant image data (3D data) corresponding to each viewpoint according to the signal received from the relative position calculation unit 40. it can.

  In the memory 33, in addition to the operation control program of the computing unit 31, information on the relative positions of the left eye 101 and the right eye 102 obtained from the relative position calculation unit 40, and information on the stereoscopic viewing area of the stereoscopic image display panel 10 Etc. are stored, and the calculator 31 determines whether the left and right eyes of the observer 100 are based on information stored in the memory 33 and information appropriately obtained from a sensor (not shown) of the observer position measuring unit 45. It has a function of determining which viewpoint area is located (a function of specifying a viewpoint area where the left and right eyes of the observer are located).

  The generation of the image data in the image generation processing unit 30 is realized by performing image processing on the arithmetic unit 31 that has read the display target data stored in the data storage unit 32. If the display target data is three-dimensional data including depth information, the computing unit 31 performs rendering processing on the three-dimensional data, whereby two-dimensional image data for each viewpoint having parallax (3D used for stereoscopic display). Data) is preferably used.

  That is, when generating 3D data to be used for stereoscopic display, the calculator 31 is configured to set a virtual camera having a predetermined number of viewpoints for the three-dimensional data and to perform rendering processing on each of them. For example, for the two-dimensional image data for each viewpoint having parallax as shown in FIG. 3, the computing unit 31 in which a virtual camera having a predetermined number of viewpoints (here, two viewpoints) is set for each of the three-dimensional data. The configuration is such that it is generated by rendering processing.

  Here, it is preferable to use a generation method based on three-dimensional data including depth information for generation of image data by the image generation processing unit 30. However, a configuration may be adopted in which display target data that has been subjected to rendering processing in advance is stored in the data storage unit 32 and is selectively read out.

  That is, display target data in the form of two-dimensional image data corresponding to FIG. 3 is stored in advance in the data storage unit 32, from which the computing unit 31 selects image data corresponding to stereoscopic display or planar display. You may take the method of reading. If such a method is employed, rendering processing is not required, and therefore the computing unit 31 having a lower processing capability and computation speed than the above-described generation method requiring rendering processing can be employed. The advantage is that it can be configured at low cost.

  The image generation processing unit 30 is configured to generate 3D data according to the position information received from the relative position calculation unit 40, and output the 3D data to the display panel drive circuit 21, and further output the 3D data. In doing so, it has a function of outputting a control signal (a signal for enabling the liquid crystal lens, etc.) generated at the same time to the image distribution control circuit 22.

  The display panel drive circuit 21 has a function of generating a signal (synchronization signal or the like) necessary for driving the display panel 11, and the image distribution control circuit 22 outputs a signal for driving the light beam separating unit 12. It has a function to generate.

In addition to the liquid crystal lens, an active element that can be controlled by an electric signal such as a liquid crystal barrier element can be used as the light beam separating unit 12.
In addition, a static element that cannot be controlled by an electrical signal, such as a lenticular lens, a fly-eye lens, a parallax barrier, or a ponthole, may be used as the light beam separating means 12. By doing so, it is not necessary to provide the image distribution control circuit 22 in the display controller 24, so that the cost can be reduced by simplifying the configuration.

  By the way, the image generation processing unit 30 having the above-described configuration has a function of generating images for J viewpoints (J> N) set in advance based on display target data in the data storage unit 32. Have.

  Therefore, when the contents up to now are summarized, the stereoscopic image display device 1 for displaying an image corresponding to each of a plurality of viewpoints is provided on the display panel 11 in which a plurality of pixels are arranged and the display surface side thereof, and each of the above-described pixels. A stereoscopic image display panel 10 including a light beam separating unit 12 that separates parallax images from each pixel toward a plurality of N viewpoints according to the arrangement direction (x-axis direction) of the viewer, and an observer facing the display surface An observer position measurement unit 45 that measures an observation position, a relative position calculation unit 40 that calculates a relative position of the observer with respect to the stereoscopic image display panel 10 based on the measurement result, and a preset J viewpoint ( And an image generation processing unit 30 that generates a viewpoint image corresponding to the relative position and outputs the viewpoint image to the stereoscopic image display panel. It has adopted a formation.

  Therefore, the image generation processing unit 30 can generate images larger than two viewpoints, for example, six viewpoints.

  Here, FIG. 7 shows images for six viewpoints as an example of image information input to the two-viewpoint stereoscopic image display panel 10 according to the first embodiment. 7A shows the first viewpoint image 61a, FIG. 7B shows the second viewpoint image 61b, FIG. 7C shows the third viewpoint image 61c, FIG. 7D shows the fourth viewpoint image 61d, and FIG. The fifth viewpoint image 61e, (f) is the sixth viewpoint image 61f.

  As shown in FIG. 7, the size of the “5” surface of the dice and the size of the “3” surface are different between the respective viewpoint images. That is, the first viewpoint image 61a has the largest “5” plane, and the sixth viewpoint image 61f has the largest “3” plane. Further, the “5” surface gradually decreases from (a) to (f), and the “3” surface gradually increases.

Next, FIG. 8 shows an example of a generation method from the first viewpoint image to the sixth viewpoint image shown in FIG.
Basically, similarly to the configuration shown in FIG. 4, the first viewpoint camera 65a, the second viewpoint camera 65b, the third viewpoint camera 65c, the fourth viewpoint camera 65d, and the fifth viewpoint camera 65e. And the sixth viewpoint camera 65f, and the first to sixth viewpoint cameras (65a to 65f) capture the 3D object 64 of the dice having the three-dimensional information of the xyz value. Images as shown in 7 (a) to (f) are generated.
Also, the magnitude of the difference in position between corresponding points in FIGS. 7A to 7F is the amount of parallax between the images.

  When the observer 100 moves outside the main lobe of the stereoscopic image display panel 10, the image generation processing unit 30 is configured to generate a new image corresponding to the viewpoint according to the observation direction. That is, when images for six viewpoints as illustrated in FIG. 7 are generated, the image generation processing unit 30 generates images for all six viewpoints in advance and performs storage processing for observation from here. May be selected as appropriate according to the movement of the viewer, or only the viewpoint image in the vicinity of the observer position may be generated as appropriate.

  FIG. 9 shows a state of light separation by the stereoscopic image display panel 10 when the image generation processing unit 30 generates images for six viewpoints in this way. Similarly to FIG. 5 described above, this is a cross-sectional view of the zx plane when viewed from the positive direction of the y-axis (see FIG. 2).

FIG. 9A shows an image generation process when the left eye 101 of the observer 100 exists in the first viewpoint region 50a and the right eye 102 exists in the second viewpoint region 50b based on the calculation result (position information) by the relative position calculation unit 40. It is the figure which illustrated the scene which the part 30 judges.
In this case, the image generation processing unit 30 uses the image data of the third viewpoint image 61c (FIG. 7) for the first viewpoint area 50a and the fourth viewpoint image 61d (FIG. 7) for the second viewpoint area 50b. Are generated and output to the display panel drive circuit 21 as 3D data. That is, “3” and “4” attached here correspond to the third viewpoint image 60c and the fourth viewpoint image 60d, respectively.
As a result, a stereoscopic viewing area 90 in which the observer 100 can perceive a stereoscopic image is formed. The stereoscopic viewing area 90 as the main lobe here is formed at a position substantially coincident with the stereoscopic viewing area 80 as the main lobe described with reference to FIG. 5, as shown in FIG.

Similarly, in FIG. 9B, when the left eye 101 of the observer 100 exists in the second viewpoint region 51 b and the right eye 102 exists in the first viewpoint region 50 a based on the calculation result by the relative position calculation unit 40, the image generation processing unit 30. This is an example of a scene that Judgment makes.
In this case, the image generation processing unit 30 uses the image data of the second viewpoint image 61b (FIG. 7) for the first viewpoint region 51b and the third viewpoint image 61c (FIG. 7) for the second viewpoint region 50a. Are generated and output to the display panel drive circuit 21 as 3D data. That is, “2” and “3” attached here correspond to the second viewpoint image 60b and the third viewpoint image 60c, respectively.
Thereby, a stereoscopic viewing area 91 where the observer 100 can perceive a stereoscopic image is formed, and the position of the stereoscopic viewing area 91 substantially coincides with the position of the reverse viewing area 85 described with reference to FIG. .

Similarly, in FIG. 9C, from the calculation result by the relative position calculation unit 40, when the left eye 101 of the observer 100 exists in the first viewpoint region 51 a and the right eye exists in the second viewpoint region 51 b, the image generation processing unit 30. This is an example of a scene to be judged.
In this case, the image generation processing unit 30 uses the image data of the first viewpoint image 61a (FIG. 7) for the first viewpoint region 51a and the second viewpoint image 61b (FIG. 7) for the second viewpoint region 51b. Are generated and output to the display panel drive circuit 21 as 3D data. That is, “1” and “2” attached here correspond to the first viewpoint image 60a and the second viewpoint image 60b, respectively.
As a result, a stereoscopic viewing area 92 where the observer 100 can perceive a stereoscopic image is formed, and the position of the stereoscopic viewing area 92 substantially coincides with the position of the side lobe 81 described with reference to FIG.

Here, the stereoscopic viewing areas 92, 91, 90 and two stereoscopic viewing areas (see FIG. 9) generated on the positive side of the x-axis by the same regularity as the stereoscopic viewing areas A to E, respectively. FIG. 11 shows a table summarizing the correspondence between the viewpoint area where the left and right eyes of the observer 100 are located and the image data to be displayed in the first viewpoint area and the second viewpoint area.
The remarks column in FIG. 11 shows the correspondence between the positions of the stereoscopic viewing areas A to E and the positions of the stereoscopic viewing areas (main lobe and side lobe) and the reverse viewing area shown in FIGS. .

In the above-described image display based on the two-viewpoint stereoscopic image display panel 10 and the image data for the two viewpoints, the observer 100 can only perceive the same image in the main lobe and the side lobe, and the main lobe and the side lobe. In the region between and the reverse viewing state occurs.
On the other hand, if the above-described configuration is adopted that has a function of generating images for six viewpoints and appropriately forms a stereoscopic viewing zone corresponding to the viewer 100 based on these images, two viewpoints are adopted. Even in the stereoscopic display, the observer 100 can perceive different images in each of the stereoscopic viewing areas A to E, that is, motion parallax is given, and this contributes to the improvement of the realism of the stereoscopic image quality. It becomes possible to do.

  In general, as a stereoscopic image display device adopting a configuration for imparting motion parallax, a device that forms a stereoscopic viewing area as shown in FIG. 12 using a stereoscopic image display panel with six viewpoints is known. The stereoscopic viewing areas 92a to 92e in FIG. 12 are formed at positions corresponding to the stereoscopic viewing areas A to E shown in FIG. Further, “1”, “2”, “3”, “4”, “5”, and “6” attached here are images for the first viewpoint 60a, the second viewpoint image 60b, and the third viewpoint, respectively. This corresponds to the image 60c, the fourth viewpoint image 60d, the fifth viewpoint image 60e, and the sixth viewpoint image 60f.

  Such a general six-viewpoint stereoscopic image display panel may be effective when observing by a large number of people, but it is necessary to be configured so that light rays are always separated into a space for six viewpoints. Compared with the stereoscopic image display panel, the 3D resolution is reduced to 1/3 in the horizontal direction, and when the vertical direction is adjusted in accordance with the reduction in resolution in the horizontal direction, the overall resolution is reduced to 1/9 Therefore, there is a disadvantage that the stereoscopic image quality is greatly impaired.

  In this regard, the stereoscopic image display apparatus 1 according to the first embodiment described with reference to FIGS. 7 to 11 has a function of generating images for six viewpoints, and the viewer 100 uses these images. Since a configuration in which a stereoscopic viewing area corresponding to the position is appropriately formed is adopted, motion parallax can be effectively applied without reducing the resolution as described above.

  An example of stereoscopic image display using a stereoscopic image display panel with two viewpoints and image data for six viewpoints has been shown so far, but the configuration according to the first embodiment is not limited to this. That is, a configuration using a combination of a 2-viewpoint stereoscopic image display panel and image data for 10 viewpoints, a combination of a 4-viewpoint stereoscopic image display panel and image data for 12 viewpoints, or the like may be adopted. Even in such a configuration, the same effect as described above can be obtained.

Therefore, in consideration of the combination of the stereoscopic image display panel and the image data, the configuration content according to the first embodiment is generally expressed by assuming that the number of viewpoints of the stereoscopic image display panel is N (N is a natural number of 2 or more). Then, it becomes as follows.
In a stereoscopic image display panel configured so that a main lobe exists in front of the display surface, when J is the number of viewpoint image data input to the stereoscopic image display panel, the relationship “J> N” In addition to this, in addition to this, it is more desirable to configure so as to satisfy the relationship of “J = s × N (s is an integer of 2 or more)”.
Here, the front facing the display surface refers to the direction of the observer 100 when the observer 100 is located on the normal from the display surface starting from the image display center (hereinafter referred to as the display normal). Indicates.

  As shown in FIG. 5 exemplifying a state in which the center line of the main lobe and the display normal line substantially coincide with each other, in an even viewpoint (N = 2, 4, 6,. Designed to match.

On the other hand, in the odd viewpoint (first adjacent viewpoint area: N = 3, 5, 7,...), The center line of the main lobe may coincide with the display normal, and the viewpoint pitch corresponds. In some cases, it is shifted from the display normal by a size less than the angle.
In the latter case, the angle formed by the center line of the main lobe and the display normal is within a predetermined angle (within the angle of antan (e / OD) where e is the viewpoint pitch at the optimum observation distance OD). Then, from the viewpoint of symmetry between the main lobe and the side lobe, the value of the coefficient s is desirably set to an odd number of 3 or more. In this way, the side lobes can appear almost symmetrically.
On the other hand, if the angle formed between the center line of the main lobe and the display normal is equal to or greater than the predetermined angle, the value of the coefficient s may simply be set to 2 or greater, and no particular limitation is required.

The value of the coefficient s may be stored in advance in the memory 33 shown in FIG. 1, or a predetermined value may be read as the coefficient s via the external IF 34.
In any case, the image generation processing unit 30 is configured to generate images for J (= s × N) viewpoints based on the value of the coefficient s according to the number N of viewpoints of the stereoscopic image display panel 10. Is done.

  Further, the relative position calculation unit 40 or the image generation processing unit 30 is provided with an angle measurement function for measuring an angle formed by the center line of the main lobe and the display normal based on the position information. A comparison setting function for setting the coefficient s to an odd number of 3 or more may be provided if the formed angle is compared with atan (e / OD) and this is less than atan (e / OD). In this way, the side lobes can appear almost symmetrically under certain conditions.

As for image generation, a camera for virtually the number of viewpoints is arranged from three-dimensional polygon data in the data storage unit 32 and real-time rendering is performed by the computing unit 31, or images for the number of viewpoints are generated from CZ data. Various methods exist, such as a method to do.
When generating an image, the image generation processing unit 30 may use a method set in advance from among these various methods, or may be configured to be appropriately selected and used according to a use environment or an external signal. Also good. Alternatively, the image generation processing unit 30 may generate an image for J viewpoints in advance and store the image in the data storage unit 32.
As a result, motion parallax can be imparted as multiple viewpoints while maintaining high resolution with a small number of viewpoints.

  Furthermore, when the number of viewpoints N is 3 or more, it is possible to update the image data output to the target viewpoint area according to the moving direction of the observer 100.

  Here, FIG. 13 illustrates the relationship between the light beam separation state and the observer's position when a stereoscopic image display panel with three viewpoints (number of viewpoints N = 3) is adopted as the stereoscopic image display panel 10. In FIG. 13, viewpoint areas 50a, 51a, and 52a that are first viewpoint areas, viewpoint areas 50b, 51b, and 52b that are second viewpoint areas, The viewpoint areas 50c, 51c, and 52c, which are three viewpoint areas, are shown, and the positions of the observer are a position 110a and a position 110b.

  FIG. 14 shows an example of image data input to each viewpoint area via the three-viewpoint stereoscopic image display panel 10 in FIG. FIG. 14 shows B1, B2, B3, B4, B5, B6, B7, B8, B9,... As the image data for each viewpoint area. Between the images for use, the size of the “5” surface of the dice and the size of the “3” surface are different. That is, as shown in FIG. 14, the “5” surface gradually decreases from B1 to B9, and the “3” surface gradually increases.

  The image generation method shown in FIG. 14 is basically the same as the method described with reference to FIG. That is, each viewpoint camera corresponding to the number of image data is arranged substantially in parallel with the x-axis, and an image is generated by capturing a 3D object.

  Furthermore, in the two cases of the case where the observer moves from the position 110a to the position 110d (FIG. 13: ←) and the case where the observer moves from the position 110d to the position 110a (FIG. 13: →), FIG. 15 and FIG. 16 show the relationship between the viewpoint area where the eye is located and the parallax image data input to the first, second and third viewpoint areas.

FIG. 15 is a table showing a case where the observer moves from the position 110a to the minus side (left side) in the x-axis direction.
First, when the state where the observer is at the position 110a is (A), in this state (A), the viewpoint area where the left eye of the observer is located is 50b, and the viewpoint area where the right eye is located is 50c. It is. In the image data, image data B6 is input to the viewpoint area 50b, and image data B7 is input to the viewpoint area 50c. Either the image data B5 or B8 is input to the viewpoint area 50a where neither the left eye nor the right eye is located.

Next, assume that the observer's left eye is positioned in the viewpoint area 50a and the right eye is positioned in the viewpoint area 50b (B), and the observer has moved from the state (A) to the state (B). To do. In the state (B), image data B5 is input to the viewpoint area 50a, and image data B6 is input to the viewpoint area 50b.
Incidentally, although not shown in FIG. 15, if the observer moves from the state (A) to the plus side (right side) in the x-axis direction, the viewpoint region where the observer's right eye is located is 52a. In this case, the image data B8 is input to the viewpoint area 52a.

In the state (B), it seems that there is no problem even if the input of the image data B7 is originally maintained in the viewpoint area 51c where neither the left eye nor the right eye is located.
However, in the first embodiment, the display controller 24 considers the moving direction (left side) from (A) to (B), and the viewpoint where the left eye of the observer can be positioned by the subsequent movement in the same direction. A configuration is adopted in which the image data for the region 51c is switched in advance to the image data B4 corresponding to the state (C).

  More specifically, the image generation processing unit 30 moves the observer indicated by the positional information from the relative position calculating unit 40 over time or the information from the sensor (not shown) in the observer position measuring unit 45. Based on the direction, an image data switching processing function (not shown) for estimating the next moving position of the observer and outputting image data (viewpoint image) corresponding to the estimated position to the display panel drive circuit 21 is provided. Have.

That is, when the stereoscopic image display panel 10 separates the parallax images toward three or more viewpoints (N ≧ 3), the image generation processing unit 30 uses the image data switching processing function to select any of the left and right eyes of the observer. A configuration is adopted in which a viewpoint image to a viewpoint area where no eye is located is selected according to the moving direction of the observer and is output to the stereoscopic image display panel 10.
Here, for example, in the state (B), a viewpoint area having a relationship like the viewpoint area 51c when viewed from the viewpoint area 50a is referred to as an adjacent viewpoint area.

Similarly to the above, when the state (B) is moved to the state (C) (the left eye of the observer is located in the viewpoint region 51c and the right eye is located in the viewpoint region 50a), the state (C) Then, as shown in FIG. 15, the state in which the image data B4 is input to the viewpoint area 51c where the left eye of the observer is located is maintained.
Further, the display controller 24 considers the moving direction from (B) to (C), and previously stores image data to the viewpoint region 51b where the left eye of the observer can be positioned by the subsequent movement in the same direction ( A configuration is adopted in which the image data B3 is switched in accordance with the state of D).

The display controller 24 similarly repeats these processing operations even in the following states (D) and (E). By adopting such a configuration, it is possible to present a stereoscopic image with very little discomfort even when the moving speed of the observer is high.
In FIG. 15, each underlined image data is the image data after the switching process based on the estimation result of the movement position of the observer.

  FIG. 16 shows a case where the observer moves from the position 110d to the plus side (right side) in the x-axis direction. In the state (E) where the observer is at the position 110d, the image data B3 is input to the viewpoint area 51b where the right eye of the observer is located.

  Here, in consideration of the movement direction (right side) from (E) to (D), the right eye of the observer is positioned in the first viewpoint area by the subsequent movement in the same direction when in the state (c). It is. Therefore, in the first embodiment, when moving from the state (E) to the state (D), the image data to the first viewpoint area (the viewpoint area 52a, etc.) is pre-corresponding to the state (C). The image data is switched to the image data B5.

  Then, when moving from the state (D) to the state (C), the input of the image data B5 to the viewpoint region 50a where the observer's right eye is located is maintained, and this state is also in the state (C). Is preserved.

  Also, considering the movement direction (right side) from (D) to (C), the right eye of the observer is positioned in the second viewpoint region by the subsequent movement in the same direction when in the state (B). is there. Therefore, similarly to the above, in the state (C), the image data for the second viewpoint area (viewpoint area 50b or the like) is switched in advance to the image data B6 corresponding to the state (B).

  Similarly, in the state of (B), considering the movement direction (right side) from (C) to (B), the movement to the viewpoint region 50c where the observer's right eye can be located by the subsequent movement in the same direction. The image data is configured to be switched in advance to image data B7 corresponding to the state (A).

That is, the display controller 24 adopts a configuration in which the processing operation is repeated in the same manner as described above in the following states (B) and (A). By adopting such a processing operation, it is possible to present a stereoscopic image with very little discomfort even when the movement speed of the observer is high.
Also in FIG. 16, each underlined image data is image data after the switching process based on the estimation result of the movement position of the observer.

Incidentally, it is desirable that the time required for the processing from the observer position measuring unit 45 to the relative position calculating unit 40 described with reference to FIG. 1 and the like is ideally close to zero. However, in reality, it often takes 0.1 seconds or more due to data transfer or computation.
In such a case, when outputting the image data from the image generation processing unit 30 based on the signal (position information) from the relative position calculation unit 40, there is a situation in which the observer does not stay at the measured position. Can occur. In particular, when the movement speed of the observer is high, the left and right eyes of the observer are outside the assumed viewpoint area, and in the worst case, a predetermined stereoscopic image may not be perceived.

  In view of such a problem, the first embodiment employs a configuration in which image data selected in advance in consideration of the direction of movement of the observer is input in advance toward the target viewpoint area as described above. It is possible to give smooth motion parallax to a viewer who moves at a high speed without impairing stereoscopic visibility.

  That is, since the image data in FIG. 15 and FIG. 16 is underlined and clearly shown, the configuration is adopted in which significant image data corresponding to the direction in which the observer moves is input prior to the movement of the observer. Accordingly, even when the moving speed of the observer is high, it is possible to present a stereoscopic image without a sense of incongruity.

  Next, FIG. 17 illustrates the relationship between the light beam separation state and the observer when a stereoscopic image display panel with four viewpoints (number of viewpoints N = 4) is adopted as the stereoscopic image display panel 10. In FIG. 17, viewpoint areas 50a, 51a, and 52a that are first viewpoint areas, viewpoint areas 50b, 51b, and 52b that are second viewpoint areas, and third viewpoint areas are formed corresponding to the position of the observer. The viewpoint areas 50c, 51c, and 52c that are the viewpoint areas and the viewpoint areas 50d, 51d, and 52d that are the fourth viewpoint areas are shown, and the positions 111a and 111b are shown as the positions of the observers.

  Further, the parallax image data input to each viewpoint area via the stereoscopic image display panel 10 will be described with reference to FIG. 14 as in the case of FIG.

  Furthermore, in the two cases of the case where the observer moves from the position 111a to the position 111d (FIG. 17: ←) and the case where the observer moves from the position 111d to the position 111a (FIG. 17: →), FIG. 18 and FIG. 19 show the relationship between the viewpoint area where the eye is located and the parallax image data input to the first, second, third and fourth viewpoint areas.

FIG. 18 is a table showing a case where the observer moves from the position 111a shown in FIG. 17 to the minus side (left side) in the x-axis direction.
First, assuming that the state where the observer is at the position 111a is (A), in this state (A), the viewpoint area where the left eye of the observer is located is 50b, and the viewpoint area where the right eye is located is 50c. It is. In the image data, image data B6 is input to the viewpoint area 50b, and image data B7 is input to the viewpoint area 50c. Image data B5 is input to the viewpoint area 50a where neither the left eye nor the right eye is positioned, and B8 is input to the viewpoint area 50d.

  Even when the observer moves from the state (A) to the state (B), the image data B5 is continuously input to the viewpoint area 50a. That is, the image data B5 is input to the viewpoint area 50a where the left eye of the observer is located in the state (B), as in the state (A).

  Further, when the observer moves from the state (A) to the state (B), input of the image data B8 and B7 may be maintained in the viewpoint areas 51d and 51c where neither the left eye nor the right eye is positioned. However, as in the case of the three-viewpoint stereoscopic image display panel (FIG. 13) described above, the movement in the same direction continues in consideration of the movement direction (left side) from (A) to (B). Thus, the image data for the viewpoint area 51d where the left eye of the observer can be positioned is previously switched to the image data B4 corresponding to the state (C).

In addition, in the stereoscopic image display apparatus 1 according to the first embodiment that employs a four-viewpoint stereoscopic image display panel, the display controller 24 moves the viewer's left eye by moving in the same direction at the same time as the switching process. Is selected and switched according to the magnitude of the moving speed v1 from (A) to (B).
Here, for example, in the state (B), viewpoint regions having a relationship such as the viewpoint regions 51d and 51c when viewed from the viewpoint region 50a are referred to as a first adjacent viewpoint region and a second adjacent viewpoint region, respectively.

  More specifically, the image generation processing unit 30 uses the positional information from the relative position calculation unit 40 over time or information on the moving speed of the observer from a sensor (not shown) in the observer position measurement unit 45. Based on this, it has an image data selection processing function (not shown) for generating in advance image data for a viewpoint area where the observer's eyes can be located by further movement and outputting the image data to the display panel drive circuit 21.

  That is, when the stereoscopic image display panel 10 separates the parallax images toward four or more viewpoints (N ≧ 4), the image generation processing unit 30 can select any of the left and right eyes of the observer with the image data selection processing function. The viewpoint image to the viewpoint area where the eye is not located is selected according to the moving direction and moving speed of the observer, and is output to the stereoscopic image display panel 10 in advance. .

This image data selection processing function is a function for executing selection of the image data by comparing the moving speed v1 with a preset threshold value vth. More specifically, when the moving speed v1 is equal to or less than the threshold value vth ( The image data B7 is selected for (v1 ≦ vth), and the image data B3 is selected when the moving speed v1 is larger than the threshold value vth (v1> vth).
That is, when the moving speed v1 is equal to or less than the threshold value vth, the image data B7 is maintained as it is, and when the moving speed v1 is larger than the threshold value vth, the image data is switched to B3.

  As shown by underlining in FIG. 18, each of the components in the display controller 24 is also displayed when moving from the state (B) to the state (C) or when moving further to the states (D) and (E). Since the constituent members function effectively and are configured to perform the same processing operation, it is possible to present a stereoscopic image that does not feel uncomfortable for an observer with a high moving speed.

  FIG. 19 shows an example of a case where the observer moves from the position 111d shown in FIG. 17 to the plus side (right side) in the x-axis direction. First, when the state where the observer is at the position 111d is (E), in this state (E), the viewpoint area where the left eye of the observer is located is 51b, and the viewpoint area where the right eye is located is 51c. It is. As for image data, image data B2 is input to the viewpoint area 51b, and image data B3 is input to the viewpoint area 51c. Image data B1 and B4 are input to the viewpoint areas 51a and 51d where neither the left eye nor the right eye is positioned, respectively.

  When the observer moves from the state (E) to the state (D), the image data B5 is continuously input from the state (E) to the viewpoint area 51d where the right eye is located.

  In this movement, as described with reference to FIG. 18, the left eye of the observer is positioned by the subsequent movement in the same direction in consideration of the movement direction (right side) from (E) to (D). At the same time, the image data for the possible viewpoint area 50a is switched to the image data B5 corresponding to the state (C) in advance, and at the same time, the movement to the viewpoint area 51b where the left eye of the observer can be located by the same movement in the same direction. The image data is selected and switched according to the magnitude of the moving speed v2 from (E) to (D) (image data selection processing function).

  That is, similarly to the above, the display controller 24 uses the image data selection processing function (not shown) included in the image generation processing unit 30 when the moving speed v2 is equal to or lower than the threshold value vth (v2 ≦ vth) as it is. The image data B6 is selected and switched when the moving speed v2 is larger than the threshold value vth (v2> vth).

  Further, as shown by underlining in FIG. 19, when the display controller moves from the state (D) to the state (C), or when it further moves to the state (B) or (A), the display controller. Since each component in 24 functions effectively and executes the same processing operation, it is possible to present an uncomfortable stereoscopic image corresponding to an observer with a high moving speed. .

  Here, when FIG. 18 and FIG. 19 are illuminated, it can be read that the underlined image data (the viewpoint area according to the underlined image data) differs depending on the direction in which the observer moves, This indicates that the stereoscopic image display apparatus 1 according to the first embodiment realizes flexible presentation of image data according to the moving direction and moving speed of the observer.

  In this way, when the observer's moving speed is high, not only the next viewpoint area (first adjacent viewpoint area) in which the left eye of the observer moves, but also successive viewpoint areas in which the observer can be located by further movement. By adopting a configuration in which corresponding image data is input in advance for the (second adjacent viewpoint region), it is possible to present a stereoscopic image that is more comfortable.

  As described with reference to FIG. 17 and the like, the processing operation of selecting image data according to the moving direction and moving speed of the observer is a configuration content applied when the number of viewpoints N is 4 or more. The target viewpoint area (selection input target area) when selecting and inputting image data with the data selection processing function (not shown) starts from one of the left and right eye viewpoint areas. , First adjacent, second adjacent,..., (N-2) adjacent viewpoints.

  That is, when the number N of viewpoints is 4 or more (N ≧ 4), the image generation processing unit 30 sets the viewpoint area in which none of the left and right eyes of the observer is located immediately before the observer moves. A configuration is adopted in which the first to (N−2) -th adjacent viewpoint areas starting from the positioned viewpoint area are selected by the image data selection processing function.

In the above description, an example in which one image data is used for each viewpoint area has been described. However, the present invention is not limited to this, and two or more image data are used for each viewpoint area. It is also possible.
Therefore, as an example, a case will be described in which four image data are used for each viewpoint region with respect to a two-viewpoint stereoscopic image display panel.

  Here, FIG. 10, FIG. 9, FIG. 14, and FIG. 10 which is an enlarged view of FIG. 9C will be described first, and the case where the position of the observer 100 is FIG. 9C will be described.

In FIG. 10, which is an enlarged view of FIG. 9C, the first viewpoint area 51a where the left eye is located is divided into four in the x direction, and 51aa, 51ab, 51ac, and 51ad are provided as the first viewpoint area sub-areas. Indicates the state.
One image data out of the image data B1, B2, B3, and B4 shown in FIG. 14 according to the position where the left eye of the observer 100 moves in the direction from −x to + x (the positive direction of the x axis). Are displayed in each of the first viewpoint area sub-areas.
Specifically, when the left eye of the observer 100 is located at 51aa, the image data B1 is located. When the left eye is located at 51ab, the image data B2 is located. When 51ac is located, the image data B3 is located at 51ad. In this case, the image data B4 is displayed.

  Similarly, the second viewpoint image in which the right eye is located is divided into four in the x direction (not shown), and the image is displayed in accordance with the position where the right eye of the observer 100 moves in the direction from -x to + x. One image data among the image data B5, B6, B7, and B8 shown in FIG. 14 is displayed in each second viewpoint region sub-region (not shown).

  These image data B1 to B8 are generated by the image generation unit 30 shown in FIG. 1, and the image generation unit 30 is configured to output to the display panel drive circuit 21 as 3D data.

  Next, when the position of the observer 100 moves to FIG. 9B, each sub-region (FIG. 9) of the second viewpoint region 51b where the left eye is located is the same as in the case of FIG. 9C described above. Image data B5, B6, B7, and B8 shown in FIG. 14 for the sub-region (not shown) of the first viewpoint region 50a where the right eye is located. B9, B10, B11, and B12 (not shown after B10) are displayed.

  Further, when the position of the observer 100 moves to FIG. 9A, each sub-region (not shown) of the first viewpoint region 50a where the left eye is located is the same as in the case of FIG. 9B described above. 14), image data B9, B10, B11, and B12 (not shown after B10) are shown for each sub-region (not shown) of the second viewpoint region 50b where the right eye is located. The image data B13, B14, B15, and B16 (not shown) shown in FIG. 14 are respectively displayed.

  As described above, when four image data are used for each viewpoint area, the four image data are handled as one image data group (for example, image data surrounded by a broken line in FIG. 14), so that the number of viewpoints described above is obtained. When N is 3 viewpoints, the image data group is switched according to the moving direction of the observer 100. When the number N of viewpoints is 4 or more, the image is associated with the moving direction and moving speed of the observer 100. The processing content of switching the data group can be realized, and it is possible to present a stereoscopic image in which the uncomfortable feeling caused by the movement of the observer 100 is greatly reduced.

  Although an example in which four image data are handled as one image data group is shown here, the stereoscopic image display apparatus 1 according to the first embodiment is not limited to this, that is, from the first viewpoint to the fourth. Each viewpoint area divided into four is set as an apparent viewpoint area, and image data to be appropriately displayed in the apparent viewpoint area is selected in accordance with the moving direction and moving speed of the observer 100 and switched. You may take the structure of these. In this way, it is possible to present a stereoscopic image that greatly reduces the sense of discomfort with respect to the movement of the observer.

  As the number of image data for each viewpoint region is increased, a very smooth motion parallax can be obtained. When the number of image data is increased, it is desirable to increase the capacity of the data storage unit 32 and the memory 33 in the display controller 24 and increase the processing capacity of the computing unit 31 accordingly.

  For example, when 20 image data is used for each viewpoint area in a two-viewpoint stereoscopic image display panel, the motion parallax corresponding to the 120-viewpoint stereoscopic image display panel is considered even if the main lobe and the side lobes only on both sides thereof are considered. Can be obtained.

Here, since the stereoscopic image display panel with 120 viewpoints generally has a 3D resolution of 1/60 as compared with the stereoscopic image display panel with two viewpoints, the 3D image quality is extremely deteriorated.
However, if the above configuration according to the first embodiment is adopted, as described above, both high 3D resolution and smooth motion parallax can be achieved.

(Description of operation)
Next, the operation content of the stereoscopic image display apparatus 1 described with reference to FIGS. 1 to 19 will be briefly described based on the flowchart shown in FIG.

First, the observer position measuring unit 45 measures the position of the observer 100 using a camera provided therein, and outputs the measurement result (FIG. 20: S101).
Next, based on the measurement result acquired from the observer position measurement unit 45, the relative position calculation unit 40 performs the left eye 101 and the right eye with respect to a reference point (here, the image display center) preset on the stereoscopic image display panel 10. The relative position with respect to 102 is calculated, and the calculation result (position information) is output (FIG. 20: S102).

Next, the image generation processing unit 30 generates and outputs 3D data and a control signal based on the position information acquired from the relative position calculation unit 40 (FIG. 20: S103).
Here, the image generation processing unit 30 in the case of adopting a three-viewpoint stereoscopic image display panel estimates the next movement position of the observer based on information on the movement direction of the observer, and Image data of a viewpoint area in which neither eye is located is generated in association with the estimated position and output to the display panel drive circuit 21 (image data switching processing function) (FIG. 20: S103).
In addition, the image generation processing unit 30 in the case where a stereoscopic image display panel with four or more viewpoints is adopted, based on information on the movement speed of the observer, image data of a viewpoint area in which neither of the observer's eyes is located Is generated in advance and output to the display panel drive circuit 21 (image data selection processing function) (FIG. 20: S103).

  Subsequently, the display panel drive circuit 21 drives the display panel based on the 3D data acquired from the image generation processing unit 30, and the image distribution control circuit 22 performs the light separation unit 12 according to the control signal from the image generation processing unit 30. The operation is controlled (FIG. 20: S104).

  The execution contents of each step in the above steps S101 to S104 (FIG. 20) may be programmed and the series of control programs may be realized by a computer.

(Effects of the first embodiment)
In the first embodiment, since the configuration for expanding the number of viewpoints determined by the device configuration is adopted, motion parallax can be imparted without reducing the resolution.
In addition, according to the stereoscopic image display apparatus that performs image control according to the moving direction and moving speed of the observer, it is possible to provide a stereoscopic image that is more comfortable.
Furthermore, even when a stereoscopic image display panel with a small number of viewpoints is adopted, as described above, since image switching processing using a plurality of viewpoint images can be performed as appropriate, a stereoscopic image having high resolution and smooth motion parallax. Can be projected.

  Further, based on the measurement result from the observer position measurement unit 45, the relative position calculation unit 40 calculates the relative position of each eye of the observer, and based on this calculation result, the image generation processing unit 30 obtains a significant image. Since the configuration is such that the control signal is generated and output, the stereoscopic image display apparatus according to the first embodiment can generate and display a significant parallax image corresponding to the position of the observer.

[Second Embodiment]
A second embodiment of the image display apparatus according to the present invention will be described with reference to FIGS. Constituent members and the like equivalent to those of the first embodiment described above are denoted by the same reference numerals.

  First, FIG. 21 shows a state of light separation by the two-viewpoint stereoscopic image display panel 10 in the second embodiment. This is also a cross-sectional view of the zx plane when viewed from the positive direction of the y-axis, as in FIG. 5 and the like described above (see FIG. 1).

  Here, assuming that the distance between the eyes of the observer is d (generally d = 65 mm) and the viewpoint pitch between the first viewpoint area and the second viewpoint area adjacent thereto is e, generally 2 In order to secure a predetermined stereoscopic viewing area on the stereoscopic image display panel at the viewpoint, the relationship “d ≦ e” is necessary, and each member is configured based on such a premise.

  However, as shown in FIG. 21, the two-viewpoint stereoscopic image display panel 10 here has an observer's binocular interval d, a first viewpoint area 50a, and a second viewpoint area 50b or 51b adjacent thereto. It is characterized in that the relationship with the viewpoint pitch e is such that “d> e”. Other configuration contents are the same as the state of FIG. 9A in the first embodiment described above.

In order to explain the viewpoint pitch from the viewpoint of 3D crosstalk, FIG. 22 shows the 3D crosstalk characteristics of the central portion of the display surface. Here, the horizontal axis represents the x-axis direction at the optimum viewing distance (OD: see FIG. 5), and the vertical axis represents the 3D crosstalk value (3D crosstalk value).
In the second embodiment, the horizontal axis is the x-axis size (the distance in the x-axis direction), but the horizontal axis related to this 3D crosstalk characteristic is calculated by the tangent of the x-axis size with respect to the optimum viewing distance. The viewing angle may be configured as shown.

  3D crosstalk is defined as the amount of leakage of the image of the opposite eye with respect to the left and right eyes. Therefore, the state where the 3D crosstalk is 100% is a state where the image for the left eye and the image for the right eye are mixed at a ratio of 1: 1. Further, since the viewpoint pitch and the x-axis range between the points where the 3D crosstalk is 100% are equivalent, the same symbol “e” is used in FIG.

  When this 3D crosstalk value increases, the stereoscopic effect is lost, and there is a risk of eye fatigue and other undesirable effects on the observer. Therefore, the crosstalk value (crosstalk amount) is set in advance. It is desirable to set it below the set reference value CT1. This reference value CT1 is generally set to 10% or less, and if it is further set to 5% or less, the above problem can be reduced more effectively.

FIG. 22 shows a part of the visual field range defined by the reference value CT1, where f is the low 3D crosstalk range and c is the high 3D crosstalk range.
If the left and right eyes of the observer are in the low 3D crosstalk range f, the observer 100 can visually recognize a good stereoscopic image.

  70a and 72a indicated by solid lines correspond to the first viewpoint areas 50a and 52a shown in FIG. 21, respectively, and 70b and 71b indicated by broken lines respectively correspond to the second viewpoint areas 50b and 51b shown in FIG. To do.

  When the size of the binocular distance d exceeds the size of the viewpoint pitch (e + f), the viewer 100 cannot visually recognize the stereoscopic image, and there is no so-called stereoscopic viewing area. Accordingly, the second embodiment is configured to satisfy the relationship “(e + f)> d> e”.

In FIG. 23, when the observer moves from the state (A) in the state shown in FIG. 22 to the minus side in the x-axis direction, that is, from the state (A), (B), (C), (D ) Indicates a viewpoint area (including a crosstalk area) where the left and right eyes of the observer are located.
FIG. 24 shows the correspondence between the viewpoint area where the left and right eyes of the observer are located and the image data of the first viewpoint area and the second viewpoint area. Here, an example using the image data shown in FIG. 7 is shown.

  Furthermore, as a comparative example, FIG. 25 and FIG. 26 show the same correspondence relationship as described above when a stereoscopic image display panel having a relationship of “d <e” is used.

  “2”, “3”, and “4” shown in the image data column (in parentheses) of FIG. 21 or FIG. 24 and FIG. 26 are the second viewpoint image 60b, the third viewpoint image 60c, and the second viewpoint image, respectively. This corresponds to the 4-viewpoint image 60d. 24 and 26 show the range in which each eye of the observer is located (low 3D crosstalk range: f, high 3D crosstalk range: c).

  Here, when FIG. 23 and FIG. 25 are compared, when the position of the observer is (A) or (D), both the left and right eyes are in a state of entering the low 3D crosstalk region, In the case of the position (B) or (C), the two eyes agree with each other in the state where one of the left and right eyes enters the low 3D crosstalk region and the other enters the high 3D crosstalk region.

However, when the observer moves from (A) to (B) and “d> e” as in the second embodiment (FIG. 23), a high 3D crosstalk region is generated from the left eye. On the other hand, when “d <e” as in the comparative example (FIG. 25), the high 3D crosstalk region is generated from the right eye.
The same applies to the case where the observer moves from (B) to (C).

  In the case of (B) or (C), the image data projected on the first viewpoint area and the second viewpoint area is based on the state before movement of the observer, which of the left and right eyes of the observer after movement is. It is determined by whether or not it exists in the low 3D crosstalk region f. That is, in such a state, the display controller 24 is configured to select image data by giving priority to the perception of the eye located in the low 3D crosstalk region f (image data priority selection function).

  For example, as shown in FIG. 24, in the case of (A), the left eye exists in the first viewpoint area 70a, the right eye exists in the second viewpoint area 70b, and the image data includes 60c, which is the third viewpoint image, is projected onto the first viewpoint area, and 60d, which is the fourth viewpoint image, is projected onto the second viewpoint area.

  When the observer moves from this state to the state (B), the left eye is present in the high 3D crosstalk region c in which the first viewpoint region 70a and the second viewpoint region 71b are mixed, and the right eye is in the second viewpoint region. It exists in 70b which is. In this case, since the right eye perception is given priority as described above, the display controller 24 uses 60d, which is the same fourth viewpoint image as in the state (A), as the second viewpoint area, and the first viewpoint area. In addition, a configuration in which the same third viewpoint image 60c as in the state (A) is used is adopted.

Next, when the observer moves from (B) to (C), the left eye is in the second viewpoint area 71b, and the right eye is a mixture of the first viewpoint area 70a and the second viewpoint area 70b. It exists in the 3D crosstalk area c. In this case, since the perception of the left eye is given priority in the same manner as described above, the display controller 24 switches the image used for the second viewpoint region to the second viewpoint image 60b different from the state of (B). The third viewpoint image 60c is used as it is for the viewpoint area.
The second viewpoint image switching process here takes into account the movement of the observer in the minus direction of the x-axis, that is, the first viewpoint area when the observer reaches the state (D). This is a process for forming a stereoscopic viewing area with the third viewpoint image 60c maintained in (because it is not in a reverse viewing state).

As a result, when the observer moves from (C) to (D) and the left eye is in the second viewpoint area 71b and the right eye is in the first viewpoint area 70a, The same viewpoint image as in the state C) can be used as it is in both the first viewpoint area and the second viewpoint area.
That is, in the second embodiment, the image data is switched only once in the second viewpoint area while the observer moves from (A) to (D).

  The same applies to the case shown in FIG. 26, that is, when the observer moves from (A) to (B), the left eye is the first viewpoint area 70a, and the right eye is the first viewpoint area 70a and the second viewpoint. Since it exists in the high 3D crosstalk area c mixed with the area 71b, priority is given to the perception of the left eye, and the second viewpoint image 60c that is the same as the state (A) is used as the first viewpoint area. The fourth viewpoint image 60d that is the same as the state (A) is also used for the viewpoint area.

  Next, when the observer moves from (B) to (C), the left eye is in the high 3D crosstalk area c in which the first viewpoint area 70a and the second viewpoint area 71b are mixed, and the right eye is in the first viewpoint area. Since the right eye is prioritized since it exists in a certain 70a, the image used for the second viewpoint area is switched to the second viewpoint image 60b, and the third viewpoint image 60c is directly in the first viewpoint area. A switching process that takes into account the movement of the observer in the minus direction of the x axis is executed.

  As described above, in both “d> e” (the second embodiment) and “d <e” (comparative example), when the observer moves from (B) to (C), any viewpoint is used. The image data is switched in the area.

Incidentally, in the case of “d = e”, the states (B) and (C) in FIG. 26 are mixed. Accordingly, when the observer moves from the state (A) to this state, both the left and right eyes are present in the high 3D crosstalk region, and when the observer moves further from there, the state directly transitions to the state (D). .
That is, in this state of (B) + (C), since both the left and right eyes do not enter the low 3D crosstalk region, an image with a sense of incongruity is input for a moment. It is not preferable to employ a stereoscopic image display panel that adopts a configuration having the relationship “e”.

  By adopting the configuration of the second embodiment as described above, it is possible to perform the image switching process in the state of “d> e” as in the case of “d <e”, and as a result, x When the size of the viewing range of the axis is constant, more viewpoint regions can be provided, and smooth motion parallax can be presented.

(Effects of the second embodiment, etc.)
In the second embodiment, based on the existence of the low 3D crosstalk range f and the high 3D crosstalk range c, the viewpoint pitch e between adjacent viewpoint regions is set to be smaller than the binocular distance d of the observer. A stereoscopic image display panel was constructed. In other words, since significant image separation using a small viewpoint pitch can be realized here, it is possible to present smooth motion parallax even with two viewpoints.
About another structure and operation | movement, it is the same as that of 1st Embodiment mentioned above, and the effect which arises similarly are also the same. In particular, when two or more pieces of image data are used for each viewpoint area, smoother motion parallax is possible.

[Third Embodiment]
A third embodiment of the image display apparatus according to the present invention will be described with reference to FIGS. In the third embodiment, for a stereoscopic image display panel having three or more viewpoints, the number of viewpoints is N (N is a natural number of 2 or more), each viewpoint pitch is e, and the observer's binocular interval is d. The feature is that the relationship of “e × (N−2) ≦ d ≦ e × (N−1)” is established. Here, the same code | symbol shall be used about the structural member etc. equivalent to 1st Embodiment mentioned above.

  First, FIG. 27 shows a state of light separation by the four-viewpoint stereoscopic image display panel 10 as an example according to the third embodiment of the present invention.

As shown in FIG. 27, on the display surface side of the stereoscopic image display panel 10, the first viewpoint areas 50a, 51a, 52a,..., The second viewpoint areas 50b, 51b, 52b,. There is an area for outputting image data for four viewpoints including 50c, 51c, 52c,..., And fourth viewpoint areas 50d, 51d, 52d,.
The main lobe 90 includes 50a, 50b, 50c, and 50d, the side lobe 91 includes 51a, 51b, 51c, and 51d, and the side lobe 92 includes 52a, 52b, 52c, and 52d.
When the left eye of the observer is present in the side lobe 91 and the right eye is present in the main lobe 90, a reverse vision region is obtained as in the description in the first embodiment.

  The relationship of “e × (N−2) ≦ d ≦ e × (N−1)” in the case of the four viewpoints (N = 4) illustrated in FIG. 27 is “2e ≦ d ≦ 3e”. The relationship will be established.

Next, FIG. 28 shows the relationship between the position of the observer and each viewpoint area. Here, a case where the observer moves from the position 112a to the position 112d will be described.
First, when the observer is at the position 112a, the left eye of the observer is present in the first viewpoint region 50a, and the right eye of the observer is “e × (N−2) ≦ d ≦ e × described above. Due to the relationship of (N-1) ", it exists in the third viewpoint area 50c or the fourth viewpoint area 50d.
As the image data input to each viewpoint here, the image data shown in FIG. 14 referred to in the first embodiment described above is adopted.

  FIG. 29 is a table showing the correspondence between the viewpoint areas where the left and right eyes of the observer are located and the image data used for each viewpoint area when the observer sequentially moves from the position 112a to the position 112d. is there.

As shown in FIG. 29, in the state (A) where the observer is at the position 112a, the image B5 is in the first viewpoint region 50a, the image B6 is in the second viewpoint region 50b, and the third viewpoint region 50c. The image B7 is used for the fourth viewpoint area, and the image B8 is used for the fourth viewpoint area.
Therefore, a good stereoscopic image can be visually recognized in this state.

  Next, considering the case where the left eye of the observer has moved to the fourth viewpoint area 51d of the side lobe 91 (state (B) shown in FIG. 29), the right eye of the observer is the second viewpoint as described above. It exists in the area 50b or the third viewpoint area 50c. Since this corresponds to the above-described reverse viewing area, in the third embodiment, the display controller 24 switches the image used for the fourth viewpoint area 51d from B8 to B4 based on the position measurement information of the observer. The structure is adopted. By adopting such switching processing, it is possible to provide a good stereoscopic image even for an observer located at this place.

  Similarly, when the case where the left eye of the observer moves to the third viewpoint area 51c of the side lobe 91 (state (C) shown in FIG. 29) is considered, the right eye of the observer is the first viewpoint area 50a or It exists in the 2nd viewpoint area | region 50b, and corresponds to a reverse vision area | region. Therefore, the display controller 24 switches the image used for the third viewpoint area 51c from B7 to B3 based on the position measurement information of the observer. Thereby, it is possible to provide a good stereoscopic image even to an observer present at the position.

  Similarly, when the left eye of the observer moves to the second viewpoint area 51b of the side lobe 91 (state (D) shown in FIG. 29), the right eye of the observer is in the fourth viewpoint area 51d or It exists in the 1st viewpoint area | region 50a, and this area | region corresponds to the side lobe 91 or a reverse vision area | region. Even in such a case, the display controller 24 is configured to switch the image used for the second viewpoint area 51b from B6 to B2 based on the position measurement information in order to make the observer visually recognize a good stereoscopic image.

  As described above, if the configuration for performing the image switching process based on the position measurement information of the observer is adopted, even in a multi-view stereoscopic image display device with a small number of viewpoints, resolution reduction is suppressed and smooth motion parallax is obtained. be able to.

(Effects of the third embodiment)
According to the stereoscopic image display apparatus in the third embodiment, as described above, even in a multi-viewpoint stereoscopic image display apparatus with a small number of viewpoints, it is possible to suppress a decrease in resolution and present smooth motion parallax. It becomes possible.
About another structure and operation | movement, it is the same as that of what was shown in 1st Embodiment, and the effect which arises elsewhere is also the same. In particular, when two or more pieces of image data are used for each viewpoint area, smoother motion parallax is possible.

[Fourth Embodiment]
A stereoscopic image display device according to a fourth embodiment of the present invention will be described with reference to FIGS. In the first to third embodiments described above, an example in which an image is optically separated with respect to one observation direction and a parallax image is projected to an observer is shown, but in the fourth embodiment, 2 A configuration is adopted in which the image is optically separated with respect to the viewing direction and the parallax image is projected to the viewer.
Here, the same code | symbol shall be used about the structural member etc. equivalent to 1st Embodiment mentioned above.

(Overall configuration)
FIG. 30 illustrates a configuration diagram of the stereoscopic image display panel 210 according to the fourth embodiment.
The stereoscopic image display panel 210 includes a display panel 211 in which pixels (not shown) are arranged in a matrix, and a light beam separating unit 250 provided on the display surface side of the display panel 211 and associated with each pixel. ,have.

The stereoscopic image display panel 210 can display a stereoscopic image in each of two states: a first arrangement state where the x-axis direction is a horizontal direction and a second arrangement state where the y-axis direction is a horizontal direction. Further, the horizontal direction here is defined as a direction substantially parallel to a straight line connecting the left eye and the right eye of the observer, and the same applies hereinafter.
Note that specific examples of the display controller 25, the stereoscopic image display panel 210, the display panel 211, and the light beam separating unit 250 shown in FIG. This is the same as the image display panel 10, the display panel 11, and the light beam separating means 12).

  FIG. 31 illustrates an arrangement relationship between the pixels 221 provided on the display panel and the lens array elements 251 constituting the light beam separating means (lens array) 250.

As shown in FIG. 31A, a pixel 221 composed of 4 × 4 sub-pixels is composed of four primary colors of a red sub-pixel 234, a blue sub-pixel 235, a green sub-pixel 236, and a white sub-pixel 237. Has been.
Further, in the 4 × 4 sub-pixels provided in one pixel 221, the primary colors are arranged so as not to overlap in both the x-axis direction and the y-axis direction.

  Here, R1, R2, R3, R4 as red subpixels 234, B1, B2, B3, B4 as blue subpixels 235, G1, G2, G3, G4 as green subpixels 236, white By arranging W1, W2, W3, and W4 as sub-pixels 237 as shown in FIG. 31A, each primary color is configured not to overlap.

FIG. 31B shows a state in which the pixels 221 shown in FIG. 31A are arranged in a matrix, and each lens array element 251 constituting the lens array 250 is arranged at a position corresponding to each pixel 221. ing. For this reason, the stereoscopic image display panel 210 can distribute light in the directions of the four viewpoints in both the x-axis direction and the y-axis direction.
Each pixel 221 and the lens array element 251 are arranged in parallel and at the same pitch with respect to the x-axis direction and the y-axis direction.

Here, the configuration of the sub-pixel and the pixel according to the fourth embodiment shown in FIG. 31 is generally expressed using a natural number M and N (a natural number of 2 or more) that is a multiple of M. become that way.
When subpixels composed of M primary colors are used, the number of subpixels constituting each pixel is the square of N (N viewpoint × N viewpoint), and the remainder obtained by dividing N by M is zero. Further, in each pixel, adjacent sub-pixels for two light beam separation directions are not the same color. Further, in each pixel, the existence probabilities of the same color sub-pixels in the two light beam separation directions are the same between the M primary colors.
In addition, the arrangement pitch of the sub-pixels with respect to the two light beam separation directions is equal.

FIG. 31 shows an example in which one pixel is configured by 4 × 4 sub-pixels. However, the present invention is not limited to this. For example, pixels configured by 3 × 3 sub-pixels are arranged in a matrix. The display panel etc. which were done can be applied similarly.
The 4 × 4 sub-pixels have been described using primary colors of RGBW (red, green, blue, and white). However, the present invention is not limited to these. For example, instead of RGBW, (red, green, Blue / yellow) or CMYW (cyan / magenta / yellow / white) may be employed. In addition, fluorescent colors, pearl colors, and interference colors can be used as primary colors.

  In the 4 × 4 sub-pixel configuration composed of the four primary colors shown in FIG. 31A, the image data shown in FIG. 14 referred to in the first embodiment can be used.

Next, the relationship between the input image and the sub-pixel will be described with reference to FIG. 32 showing the sub-pixel configuration in the first arrangement state.
Here, the pixel 221 shown in FIG. 31 includes a sub-pixel group 241 in which sub-pixels W4, G4, B4, and R4 are arranged, a sub-pixel group 242 in which sub-pixels B3, R3, G3, and W3 are arranged, The subpixel group 243 in which G2, W2, R2, and B2 are arranged and the subpixel group 244 in which the subpixels R1, B1, W1, and G1 are arranged are caused to function.

That is, when an input image as shown in FIG. 14 is used, first, the sub-pixel group 241 has a fifth viewpoint image B5, the sub-pixel group 242 has a sixth viewpoint image B6, and the sub-pixel group 243 has a second pixel. Signals corresponding to the eighth viewpoint image B8 are input to the seven viewpoint image B7 and the sub-pixel group 244, respectively.
At this time, since all of the sub-pixel groups 241 to 244 are composed of four primary colors, it is possible to obtain an effect that there is no difference in the number of display colors between the respective viewpoint images in the pixel.

Next, the relationship between each viewpoint image and the sub-pixel will be described with reference to FIG. 33 relating to the sub-pixel configuration in the second arrangement state rotated 90 ° to the right from the first arrangement state shown in FIG.
Also in FIG. 33, as in the case of FIG. 32, the fifth viewpoint image B5 for the subpixel group 245, the sixth viewpoint image B6 for the subpixel group 246, and the seventh viewpoint image for the subpixel group 247. Signals corresponding to the eighth viewpoint image B8 are input to B7 and the sub-pixel group 248, respectively.

As described above, since the same number of parallax images (viewpoint images) are generated in each pixel in the x-axis direction and the y-axis direction, the number of sub-pixels having different color schemes is equal in each viewpoint image. Thus, an equivalent and significant stereoscopic view can be realized in any state of the first arrangement state and the second arrangement state.
Further, according to such a configuration, it is possible to make the 3D resolution in the first arrangement state and the second arrangement state the same regardless of the number of viewpoints.

  Furthermore, since the number N of viewpoints is a multiple of M colors as in the general notation described above, the occurrence of color moiré can be suppressed. Here, “color moiré” means that the unevenness of each color is perceived when the observer swings the viewing angle in the arrangement direction. When “color moiré” occurs, the display quality is greatly reduced.

  As the light beam separating means 250, either a static optical element or an active optical element can be used, but active optical elements such as a liquid crystal lens element and a liquid crystal barrier element capable of separating light beams in the x-axis and y-axis directions. A device is preferred.

  Incidentally, as shown in FIG. 34, with respect to the configuration example of the sub-pixel group shown in FIG. 32, each lens array element 251 performs light beam separation only in the x-axis direction (each direction in the zx plane) that is the light beam separation direction. By adopting a configuration in which the y-axis direction (each direction in the yz plane) that is orthogonal to this is not subjected to light beam separation, color cracking can be avoided without depending on the separation angle. The state shown in FIG. 34 corresponds to the first arrangement state described above.

  Here, the regions separated in the x-axis direction are as follows. That is, 50a, 51a (not shown), 52a is a first viewpoint region corresponding to the sub-pixel group 241, 50b, 51b (not shown), 52b is a second viewpoint region corresponding to the sub-pixel group 242, 50c, 51c and 52c (not shown) are third viewpoint regions corresponding to the sub-pixel group 243, and 50d, 51d and 52d (not shown) are fourth viewpoint regions corresponding to the sub-pixel group 244.

  In addition, the main lobe is composed of 50a, 50b, 50c, 50d, and the combination of 51a, 51b, 51c, 51d or the combination of 52a, 52b, 52c, 52d corresponds to a side lobe. Light rays 59a, 59b, 59c, 59d shown in the y-axis direction are not separated as shown.

  Similarly, in the second arrangement state in which the y-axis direction is the horizontal direction (corresponding to the configuration example of the sub-pixel group shown in FIG. 33), only the y-axis direction is separated and the x-axis direction is not separated. Each lens array element 251 is configured as follows.

  Therefore, according to the configuration of the fourth embodiment, it is possible to avoid color cracking without depending on the separation angle in any arrangement state, and color moiré becomes more apparent as the separation angle increases. The inconvenience that it becomes easy can be suppressed. That is, this configuration is an effective means for improving visibility.

  Next, as a situation when the observer moves along the x-axis direction from the state at the position 113a in FIG. 34, FIG. 35 shows the 3D crosstalk characteristics in the central portion of the display surface of the stereoscopic image display panel 210. Show.

  Details concerning the 3D crosstalk characteristics are the same as those described with reference to FIG. 23 and the like in the second embodiment. Further, 70a and 72a correspond to the first viewpoint areas 50a and 52a shown in FIG. 34, respectively, 70b corresponds to the second viewpoint area 50b shown in FIG. 34, and 70c and 71c show in FIG. It corresponds to the third viewpoint areas 50c and 51c, respectively, and 70d and 71d correspond to the fourth viewpoint areas 50d and 51d shown in FIG.

  In FIG. 35, as in the case of FIG. 23 described above, the horizontal axis represents the x-axis direction at the optimum viewing distance, and the vertical axis represents the value of 3D crosstalk. Similarly, the horizontal axis related to the 3D crosstalk characteristic may be represented as a viewing angle calculated by a tangent of the size of the x-axis with respect to the optimum viewing distance.

  Here, as shown in FIGS. 35A to 35D, when the observer sequentially moves in the negative direction of the x-axis, the viewpoint region where the left and right eyes of the observer are located, and the first viewpoint FIG. 36 shows the correspondence between the area and the image data of the fourth viewpoint area. As image data to be used, FIG. 14 in the first embodiment is employed.

As shown in FIG. 36, when the observer moves from the position 113b to the position 113c, that is, when the observer enters the reverse viewing region from the main lobe, the observer position measuring unit 45 that detects the observer position at that time. The display controller 24 replaces the image data in response to the measurement result from.
In the fourth embodiment, when the observer reaches the state (C), the process of replacing the image data of all four viewpoint regions is adopted, so that the observer further exceeds the state (D) and x Even when moving in the negative direction of the axis, it is not necessary to replace the image data until the next reverse viewing area is entered.

  When the observer moves from the position 113a to the position 113b or from the position 113c to the position 113d, as shown in FIG. 36, the image data is not replaced.

  Furthermore, each pixel arranged on the display panel is constituted by a sub-pixel group as shown in FIG. 37, and it is also possible to make an observer perceive stereoscopic vision using this.

  In FIG. 37A, the pixel 221 shown in FIG. 31 includes a sub-pixel group 241 ′ in which sub-pixels W4, B3, G4, and R3 are arranged, and a sub-pixel group in which sub-pixels G2, R1, W2, and B1 are arranged. 242 ′, a sub-pixel group 243 ′ in which the sub-pixels B4, G3, R4, and W3 are arranged, and a sub-pixel group 244 ′ in which the sub-pixels R2, W1, B2, and G1 are arranged. ), A sub-pixel group 245 ′ in which sub-pixels G2, R1, W2, and B1 are arranged, a sub-pixel group 246 ′ in which sub-pixels R2, W1, B2, and G1 are arranged, and sub-pixels W4, B3, G4, and R3 And a sub-pixel group 248 ′ in which sub-pixels B4, G3, R4, and W3 are arranged.

  That is, FIG. 37A shows the sub-pixels in the pixel 221 and the lens element 251 corresponding thereto in the first arrangement state, and FIG. 37B shows a right-angle rotation of 90 ° from the first arrangement state. Each structure in the 2nd arrangement state which made the y-axis direction the horizontal direction is shown.

FIG. 38 shows an example of image information input to each sub-pixel adopted in the fourth embodiment.
In FIG. 38, A1 to A9, B1 to B9, C1 to C9, and D1 to D9 (images arranged side by side) are images having different horizontal parallaxes, for example, vertical images such as A1, B1, C1, and D1. The images arranged here are images having different vertical parallaxes (here, images having different alphabets and the same numerals).
A major feature of the image data shown in FIG. 38 is the difference in the size of the “1” surface of the dice between the four viewpoint images (A to D) arranged vertically. Of course, between the viewpoint images numbered 1 to 9, the size of the “5” surface of the dice is different from the size of the “3” surface, as in FIG. Adopted.

  The image generation method shown in FIG. 38 is basically the same as the method described with reference to FIG. That is, each viewpoint camera corresponding to the number of image data is arranged substantially in parallel with the x-axis and the y-axis, and an image is generated by capturing a 3D object.

Here, with reference to FIG. 37A and FIG. 38, the relationship between each viewpoint image and the sub-pixel in the first arrangement state will be described.
When the input image as shown in FIG. 38 is adopted, for example, the subpixel group 241 ′ in FIG. 37A is an image B5, the subpixel group 242 ′ is an image B6, and the subpixel group 243 ′ is an image. A signal corresponding to the image C6 is input to C5 and the sub-pixel group 244 ′. That is, a signal corresponding to each image surrounded by a broken line in FIG. 38 is input to each of the sub pixel group 241 ′, the sub pixel group 242 ′, the sub pixel group 243 ′, and the sub pixel group 244 ′.
Thereby, a total of four parallax images can be displayed including two horizontal parallaxes and two vertical parallaxes. At this time, since all the sub-pixel groups 241 ′ to 244 ′ are composed of four primary colors, there is no difference in the number of display colors between the viewpoint images in the pixel.

  Next, with reference to FIG. 37B and FIG. 38, the relationship between each viewpoint image and the sub-pixel in the second arrangement state is shown. As in the case of FIG. 37A, the sub-pixel group 245 ′ has an image B5, the sub-pixel group 246 ′ has an image B6, the sub-pixel group 247 ′ has an image C5, and the sub-pixel group 248 ′ has an image C6. Are input respectively.

  According to this configuration, the 3D resolution in the first arrangement state and the second arrangement state can be made the same regardless of the number of viewpoints. That is, due to the regularity of the sub-pixel group within one pixel, the number of viewpoints in the first arrangement state and the second arrangement state is the same, thereby realizing the same stereoscopic view in each arrangement state. Is possible.

Based on the above description, the number of primary colors is M, the number of viewpoints in horizontal parallax display is N (N is a natural number of 2 or more), the number of horizontal viewpoints and the number of vertical viewpoints in horizontal / vertical parallax display is L, and the total of horizontal and vertical parallaxes These relationships are generally described below, where the number of viewpoints is J (= L × L), and the number of subpixels per direction of the subpixel group in horizontal and vertical parallax display is K.
Here, the viewpoint number N is the number of viewpoints in the case of only horizontal parallax display, and corresponds to the number of sub-pixels per direction in the pixel.

  First, K = √M when √M, which is the square root of the number of primary colors M, is an integer, and K = M when √M is not an integer. For example, when M = 1, 4, 9, √M is an integer, so K = 1, 2, 3, and when M = 2, 3, √M is not an integer, so K = 2,3. It becomes.

  Next, the number of horizontal viewpoints and the number of vertical viewpoints L per direction is represented by “L = N / K (where L is a natural number of 2 or more)”. For example, in the case of the pixel 221 shown in FIG. 31, “L = 4/2 = 2”. Thus, in the horizontal / vertical parallax display, the number of horizontal viewpoints per one direction and the number of vertical viewpoints L is a multiple of the number of sub-pixels K per direction of the sub-pixel group in the horizontal / vertical parallax display. As a result, an effect that no color moire occurs in the display image can be obtained.

Next, FIG. 39 shows a state of light beam separation in the x-axis direction and the y-axis direction in the first arrangement state shown in FIG. In FIG. 39, the x-axis direction is the horizontal direction, and the y-axis direction is the vertical direction.
Here, since the light beam separating means 250 that simultaneously separates light beams in both directions of the first direction and the second direction is employed, parallax is given in both the horizontal direction and the vertical direction.

FIG. 39 shows a configuration in which parallax is applied in both the horizontal direction and the vertical direction when the observer moves to positions 114a, 114b, 114c,... In the horizontal direction (x-axis direction). In addition, a state in the case of moving to positions 115a, 115b, 115c, 115d,... In the vertical direction (y-axis direction) is shown.
The first viewpoint area is composed of a horizontal direction 50a that is light emitted from the sub-pixel group 241 ′ and a vertical direction 55a, and the second viewpoint area is perpendicular to the horizontal direction 50b that is light emitted from the sub-pixel group 242 ′. The third viewpoint area is composed of the horizontal direction 50a and the vertical direction 55b that are emitted light from the sub-pixel group 243 ′, and the fourth viewpoint area is emitted light from the sub-pixel group 244 ′. It consists of a certain horizontal direction 50b and a vertical direction 55b.

  The main lobe in the horizontal direction is one area where the left eye of the observer is located at 50a and the right eye is located at 50b, whereas the main lobe in the vertical direction is located at the observer's eyes at 55a or 55b. Exist in two locations. Here, the area related to 55a is the main lobe 1 and the area related to 55b is the main lobe 2 and the area related to 56b is the side lobe 1 and 54a is the side lobe 2.

  FIG. 40 shows what image data (see FIG. 38) is assigned to each viewpoint area (each subpixel) when the left and right eyes of the observer are located in which viewpoint area with respect to each observer position (see FIG. 39). Group)).

  In general, when image data for four viewpoints is used for a 2 × 2 viewpoint stereoscopic image display panel, the main lobe and side lobes in the horizontal direction can only be perceived as the same image. Backsight occurs between the side lobes. Similarly, in this case, although the reverse view does not occur in the vertical direction, the main lobe 1 and the side lobe 1 or the main lobe 2 and the side lobe 2 can only perceive the same image.

On the other hand, by using the configuration in the fourth embodiment, as shown in FIG. 40, stereoscopic viewing areas A1, A2, A3..., B1, B2, B3,. .., C1, C2, C3..., D1, D2, D3... Allow viewers to perceive different images, that is, motion parallax is given in both the horizontal and vertical directions. For this reason, it is possible to contribute to the improvement of the sense of reality of the stereoscopic image quality.
Here, since binocular parallax is not involved in the vertical direction, the vertical separation angle (viewpoint pitch) may be smaller than the horizontal separation angle (viewpoint pitch). Good.

  As described above, when the active light beam separating unit 250 is used, in the fourth embodiment, for example, as shown in FIG. 34, the light beam is separated only in the x-axis direction in the first arrangement state, and the y axis As shown in FIG. 39, the configuration in which the light beam is not separated in the direction and the parallax are given to both the horizontal direction and the vertical direction, and the light beam is simultaneously applied to both the x-axis direction and the y-axis direction. It is possible to adopt a configuration in which separation is performed.

  As described above, when the configuration in which the vertical separation angle is made smaller than the horizontal separation angle, the lens power (refractive power) of the lens 253 (FIG. 39) showing a state in which the light beam is separated in the vertical direction. ) Is made smaller than the lens power of the lens 252 (FIG. 39) showing a state in which the light beam is separated in the horizontal direction.

  FIG. 41 shows an example of a terminal device 300 equipped with the stereoscopic image display device 1 according to the fourth embodiment described above. That is, the terminal device 300 includes the stereoscopic image display device 1 and a housing 310 that contains the stereoscopic image display device 1, and the stereoscopic image display device 1 serves as the light beam separating means 250 in the x-axis direction and the y-axis direction as described above. A liquid crystal lens element (not shown) capable of separating light rays in a corresponding direction is provided.

Therefore, the configuration of the terminal device 300 equipped with the stereoscopic image display device 1 according to the fourth embodiment will be described with reference to FIG.
The stereoscopic image display device 1 here is provided with a detection unit 150 that detects a displacement generated as a result of the movement of the terminal device 300 with respect to the configuration described in the first embodiment. That is, the detection unit 150 is configured to identify that the terminal device 300 is positioned horizontally or vertically for the observer.

  The detection unit 150 includes a sensor that detects a displacement that occurs as a result of the terminal device 300 moving. Here, the displacement of the terminal device 300 detected by the detection unit 150 is a change in the tilt angle or a movement amount. For example, when a sensor such as an acceleration sensor or a geomagnetic sensor is used as the detection unit 150, it is possible to calculate a change in inclination angle and a movement amount based on gravitational acceleration and geomagnetism. That is, the detection unit 150 includes an inclination angle detection unit 151 that detects a change in an inclination angle and a movement amount, and is configured to detect a positional relationship between the stereoscopic image display panel 10 and an observer.

  In addition, the detection unit 150 has a configuration in which information (displacement information) related to the inclination angle as a detection result by the inclination angle detection unit 151 is sent to the image generation processing unit 30.

  That is, the image generation processing unit 30 determines the horizontal direction and observation of the terminal device 300 according to the measurement result from the relative position calculation unit 40 and the signal (displacement information) from the detection unit 150 shown in the first embodiment. The image data corresponding to the person's position is output to the display panel drive circuit 21.

  Here, in the case of outputting 3D data, as described based on FIGS. 32 and 33 described above, the sub-pixel corresponding to each viewpoint changes in the first arrangement state and the second arrangement state. The unit 30 is configured to output image data corresponding to this change to the display panel drive circuit 21.

  Simultaneously with the output to the display panel drive circuit 21, the image generation processing unit 30 performs the arrangement state when the terminal device 300 is in the first arrangement state shown in FIG. 32 or the second arrangement state shown in FIG. In response to this, the image distribution control circuit 22 is configured to transmit a command signal for enabling the light beam separating means 250 (liquid crystal lens) in the x-axis direction and the y-axis direction.

  Further, when N viewpoints are expanded only in the horizontal direction shown in the first embodiment (hereinafter referred to as horizontal N viewpoint expansion), L viewpoints (L = When selecting (N / K) (total J viewpoint) (hereinafter referred to as horizontal and vertical J viewpoint development), the external IF 34 in the image generation processing unit 30 functions effectively. ing. For example, a configuration is adopted in which the external IF 34 receives a selection signal output from the outside in response to an instruction from an observer, and the image generation processing unit 30 generates image data based on information included in the selection signal. be able to.

Therefore, the image data generation method by the image generation processing unit 30 in the present embodiment adds a method of changing the position of the virtual camera according to the selection signal received from the outside to the generation method described in the first embodiment. It becomes the composition.
That is, when the calculator 31 sets horizontal N viewpoints, the virtual camera is set for N viewpoints only in the horizontal direction, and when the horizontal and vertical J viewpoints are expanded, the virtual camera is set to L in the horizontal direction and the vertical direction, respectively. The viewpoints (total L × L viewpoints: J viewpoints) are set, and the calculator 31 is configured to perform rendering processing and generate image data in each case.

Also, in the case of horizontal N viewpoint development, when N = 2, the relationship (e + f)>d> e described in the second embodiment can be used, and when N ≧ 3, the third embodiment. The relationship of “e × (N−2) ≦ d ≦ e × (N−1)” described in the above can be used.
Similarly to the contents described in each of the embodiments, when this relationship is satisfied, the stereoscopic image display device excellent in motion parallax while ensuring predetermined stereoscopic visibility also by the configuration according to the fourth embodiment. Can be provided.

  In the horizontal and vertical J viewpoint development shown in FIG. 37, when J = 2 (2 × 2 viewpoints), “(e + f)> d> e” described in the second embodiment is applied in the horizontal parallax direction. The relationship of “e × (J−2) ≦ d ≦ e × (J−1)” described in the third embodiment can be used when J ≧ 3. Accordingly, it is possible to provide a stereoscopic image display device that is excellent in motion parallax in the horizontal and vertical directions while ensuring predetermined stereoscopic visibility.

A smaller viewpoint pitch than the horizontal parallax direction can be used for the vertical parallax direction. As a result, it is possible to further reduce color moire and give smooth motion parallax.
Other operations are the same as those in the first embodiment.

(Description of operation)
Next, the operation contents of the stereoscopic image display device 1 and the terminal device 300 in the fourth embodiment will be briefly described based on the flowchart shown in FIG.

  The detection unit 150 that detects the displacement of the terminal device 300 outputs the displacement information that is the detection result to the image generation processing unit 30 (FIG. 43: S201).

In addition, the observer position measurement unit 45 measures the position of the observer 100 using the included camera, and outputs the measurement result to the relative position calculation unit (FIG. 43: S202).
Next, based on the measurement result acquired from the observer position measurement unit 45, the relative position calculation unit 40 performs the left eye 101 and the right eye with respect to a reference point (here, the image display center) preset on the stereoscopic image display panel 10. The relative position with respect to 102 is calculated, and the calculation result (position information) is output (FIG. 43: S203).

  Next, the image generation processing unit 30 generates and outputs 3D data and a control signal based on the displacement information from the detection unit 150 and the position information from the relative position calculation unit 40 (FIG. 43: S204).

  Subsequently, the display panel drive circuit 21 drives the display panel based on the 3D data acquired from the image generation processing unit 30, and the image distribution control circuit 22 performs the light separation unit 12 according to the control signal from the image generation processing unit 30. The operation is controlled (FIG. 43: S205).

  The above operation description has been performed in the order of the numbers given in FIG. 43 (S201 to S205) for convenience. However, the operation content of the stereoscopic image display device 1 according to the fourth embodiment is limited to the order. is not. Further, the execution contents of each step in each of steps S201 to S205 (FIG. 43) may be programmed, and this series of control programs may be realized by a computer.

(Effects of the fourth embodiment)
In the stereoscopic image display device according to the fourth embodiment, the same number of parallax images are generated in the x-axis direction and the y-axis direction in each pixel, and the number of sub-pixels having different color schemes is equal in each viewpoint image. Therefore, in the case where parallax is given in one of the horizontal and vertical directions by the active light beam separating means, or in the case where parallax is given simultaneously in two directions of the horizontal direction and the vertical direction, The 3D resolution in the first and second arrangement states can be made the same.

In addition, since each pixel in the fourth embodiment is configured such that the number of viewpoints N is a multiple of the number of primary colors M, the occurrence of color moiré can be suppressed. In addition, in the fourth embodiment, the state in which the y-axis direction is rotated horizontally by 90 ° from the first arrangement state and the horizontal direction is set as the second arrangement state is not limited to this. Even in the state in which the y-axis direction is turned to the left by 90 ° from the first arrangement state, the above-described components function effectively, so the same effects as those in the second arrangement state are obtained. be able to.
About another structure and operation | movement, it is the same as that of what was shown in 1st Embodiment, and the effect which arises elsewhere is also the same. In particular, when two or more image data are used for each viewpoint area, smoother motion parallax is possible for both horizontal parallax and vertical parallax.

[Fifth Embodiment]
In the fourth embodiment described above, the configuration example in which the image is optically separated in the two observation directions and the parallax image is projected onto the observer has been described. It can also be applied to the configuration in the third embodiment.
Therefore, in the fifth embodiment, FIGS. 44 to 45 show a stereoscopic image display apparatus in which the configuration content of optically separating images in two observation directions is applied to the configuration of the first embodiment. And explained.

  The overall configuration of the stereoscopic image display apparatus in the fifth embodiment is the same as the configuration content of the stereoscopic image display apparatus 1 shown in FIGS. 1 and 2, and therefore, in the following description, these figures are referred to for convenience. . For this reason, the same code | symbol shall be used about the structural member etc. equivalent to 1st Embodiment, and the overlapping description is abbreviate | omitted.

  The stereoscopic image display panel 10 included in the stereoscopic image display device 1 has pixels including at least sub-pixels that display an image for a first viewpoint and sub-pixels that display an image for a second viewpoint arranged in a matrix. A display panel 11 and a light beam separating unit 12 provided on the display surface side of the display panel 11 for separating a parallax image from the pixel toward each viewpoint.

  As shown in FIG. 2, the light beam separating means 12 has a configuration in which lenses 15 corresponding to the respective pixels arranged on the display panel 11 are arranged in an array, that is, of the arrangement directions of the respective pixels. It has a structure for separating light rays in one direction (light ray separation direction: x direction in FIG. 44).

  Here, the direction parallel to the straight line connecting the left eye and the right eye of the observer is defined as the horizontal direction. In the following, it is assumed that the light beam separation direction (x direction) is substantially parallel to the horizontal direction. For this reason, the light beam separation direction is also referred to as a horizontal direction. In addition, a direction perpendicular to the horizontal direction (x direction) in the display surface of the display panel 11 (in a plane parallel to the display surface) is defined as a vertical direction (y direction in FIG. 44). This vertical direction is another direction among the arrangement directions of the pixels.

  In the stereoscopic image display panel 10, a pixel 263 including a first viewpoint sub-pixel 261 and a second viewpoint sub-pixel 262, and a lens 15 constituting the light beam separating unit 12 provided at a position corresponding to the pixel 263. A plurality of combinations are arranged in a matrix, and each of them can be separated by light.

  FIG. 44 shows the vicinity of a pixel including sub-pixels for two viewpoints extracted from the configuration shown in FIG. 2, and specifically shows one of the combinations of the pixel 263 and the lens 15 described above. In addition, a state in which images corresponding to two directions corresponding to the position of the observer are presented using the light beam separating means 12 in one direction is illustrated.

  By the above combination, the first viewpoint areas 50a, 51a (not shown), 52a,... In which the emitted light from the sub-pixel group 261 spreads, and the second viewpoint areas 50b in which the emitted light from the sub-pixel group 262 spreads. The images are separated such that 51b, 52b (not shown),... Are alternately repeated along the x-axis direction.

  44 shows the case where the observer moves to the position 114a, the position 114b, the position 114c,... In the horizontal direction (x-axis direction) and the vertical direction (y-axis direction) in such an image separation space. ) Is illustrated as moving to position 115a, position 115b, position 115c, position 115d,.

  Here, the main lobe in the horizontal direction is one region where the left eye of the observer is located at 50a and the right eye is at 50b, whereas there is no lens effect in the vertical direction. There is no image separation space.

  Next, in FIG. 45, regarding each observer position (see FIG. 44), what image data (see FIG. 38) is assigned to each viewpoint area (each A correspondence relationship indicating whether or not to input to (subpixel group).

  As described above, even in a stereoscopic image display panel that separates images only in the horizontal direction of two viewpoints (a stereoscopic image display panel that does not separate images in the vertical direction), a camera-captured image corresponding to the position in the vertical direction of the observer is displayed. By switching appropriately and displaying, a significant image corresponding to the movement of the observer in the horizontal and vertical directions can be provided.

  Specifically, as shown in FIG. 45, image data A1, A2, A3... At the vertical position 115a, B1, B2, B3... At the vertical position 115b, C1, C2, C3. By applying D1, D2, D3... At the vertical position 115d, even when the observer moves in the vertical direction, the observer can perceive different images in a timely manner. As a result, motion parallax is imparted in both the horizontal and vertical directions, and it is possible to contribute to improving the sense of reality of stereoscopic image quality.

  By the way, as shown in FIG. 1, the stereoscopic image display apparatus 1 according to the fifth embodiment includes an observer position measuring unit 45 that measures the position of the observer, and observation of the stereoscopic image display panel 10 based on the measurement result. A relative position calculation unit 40 that calculates the relative position of the person, and an image generation processing unit 30 that generates a parallax image based on the relative position information calculated here.

  Here, since the relative position information calculated by the relative position calculation unit 40 includes position information in the horizontal and vertical directions of the observer, the image generation processing unit 30 determines the observer based on the relative position information. It is possible to generate an image in consideration of vertical movement of the image. In other words, the image generation processing unit 30 outputs the generated image to the display panel 11 via the display panel drive circuit 21, thereby realizing the image switching process.

The horizontal image switching angle (for example, the image switching angle between A1, A2, A3... In FIG. 38) is determined based on the horizontal camera imaging position interval, and the vertical image switching angle (for example, Similarly, the image switching angle between A1, B1, C1, D1... In FIG. 38 is also determined based on the camera imaging position interval in the vertical direction.
By making the image switching angle sufficiently smaller than the viewpoint pitch, it is possible to obtain a very smooth motion parallax. In such a case, it is particularly desirable to increase the capacity of the data storage unit 32 and the memory 33 in the display controller 24 in accordance with the image switching angle, thereby speeding up the processing capability of the computing unit 31.

  Here, the provision of motion parallax in both horizontal and vertical directions has been described based on the configuration content of the first embodiment, but as described above, the same applies depending on the configuration content in the second embodiment and the third embodiment. By this method, it is possible to realize a configuration that imparts motion parallax in both the horizontal and vertical directions.

(Effects of the fifth embodiment)
As described above, in the fifth embodiment, the light beam separating unit 12 has a structure that separates the light beam in one direction (X direction) of the arrangement direction of each pixel, and the image generation processing unit 30 includes: Generating an image corresponding to the position of the viewer in the direction (y direction) perpendicular to the one direction on the display surface of the stereoscopic image display panel 10, and outputting this to the stereoscopic image display panel 10; The structure is adopted. For this reason, it becomes possible to present a camera captured image corresponding to the position of the observer in the vertical direction to the observer.

  That is, even in a stereoscopic display panel that separates images only in the horizontal direction of two viewpoints, if the configuration according to the fifth embodiment is adopted, a camera-captured image according to the position in the vertical direction of the observer can be presented. Motion parallax is given in both the horizontal and vertical directions, which makes it possible to improve the sense of presence of the stereoscopic image.

Further, by using image data having an image switching angle sufficiently smaller than the viewpoint pitch based on the position measurement information of the observer, it is possible to suppress a decrease in resolution and smooth even in a multi-viewpoint stereoscopic image display apparatus having a small number of viewpoints. Motion parallax can be obtained.
About another structure and operation | movement, it is the same as that of each embodiment mentioned above, and the effect produced other are also the same.

  Each embodiment mentioned above is a suitable concrete example in a stereoscopic image display device, a terminal device, a stereoscopic image display method, and its program, and may have various technically desirable limits. However, the technical scope of the present invention is not limited to these embodiments unless specifically described to limit the present invention.

  The following summarizes the main points of the novel technical contents of the embodiment described above, but the present invention is not necessarily limited to this.

(Supplementary Note 1): First Embodiment (J = s × N)
A display panel in which a plurality of pixels are arranged, and a plurality of N viewpoints (N is a natural number of 2 or more) according to the arrangement direction of the pixels provided on the display surface side of the display panel. A three-dimensional image display panel comprising: a light beam separating means for separating a parallax image;
An observer position measuring unit that measures the observation position of the observer facing the display surface;
A relative position calculation unit that calculates the relative position of the observer with respect to the stereoscopic image display panel based on the measurement result;
It has a function of generating viewpoint images for J viewpoints (J> N) set in advance, and generates one or more viewpoint images corresponding to each viewpoint constituting the N viewpoints in association with the relative positions. A stereoscopic image display device comprising: an image generation processing unit that outputs the image to the stereoscopic image display panel.

(Supplementary Note 2): First Embodiment (J = s × N)
In the stereoscopic image display device according to the appendix 1,
The number of viewpoints N and the number of viewpoints J satisfy the relationship that J = s × N (coefficient s is a natural number of 2 or more) (J = s × N (coefficient s Is a natural number of 2 or more).

(Supplementary note 3): First embodiment (side lobes are substantially symmetrical; s is an odd number of 3 or more)
In the stereoscopic image display device according to Appendix 2,
The stereoscopic image display panel forms a stereoscopic viewing area including a display normal, which is a normal from the display surface, starting from the image display center as a main lobe, and a stereoscopic viewing area adjacent to the main lobe. Has a lobe forming function to form as a side lobe,
When the optimum viewing distance at which the stereoscopic viewing range is maximized is OD, and the viewpoint pitch between the viewpoint areas at this OD is e, the angle formed by the center line of the main lobe and the display normal line is atan (e / OD) or less, the coefficient s is preset to an odd number of 3 or more,
The stereoscopic image display device, wherein the image generation processing unit generates viewpoint images for the J viewpoints based on the set coefficient s.

(Supplementary note 4): First embodiment (side lobes are substantially symmetrical; s is an odd number of 3 or more)
In the stereoscopic image display device according to Appendix 2,
The stereoscopic image display panel forms a stereoscopic viewing area including a display normal, which is a normal from the display surface, starting from the image display center as a main lobe, and a stereoscopic viewing area adjacent to the main lobe. Has a lobe forming function to form as a side lobe,
The image generation processing unit has a function of calculating an angle formed by the center line of the main lobe and the display normal line based on the position information, and an optimum observation distance that maximizes the stereoscopic viewing range is OD, Assuming that the viewpoint pitch between each viewpoint area in OD is e, the coefficient s is set to an odd number of 3 or more when the calculated angle is equal to or less than “atan (e / OD)”. Stereoscopic image display device.

(Additional remark 5) 1st Embodiment (Selection of the image data according to a moving direction; N> = 3)
In the stereoscopic image display device according to any one of the supplementary notes 1 to 4,
When the number N of viewpoints is 3 or more (N ≧ 3), the image generation processing unit displays a viewpoint image for a viewpoint area in which neither of the left and right eyes of the observer is located. A stereoscopic image display device characterized by selecting based on a moving direction and outputting the selected viewpoint image toward the stereoscopic image display panel.

(Appendix 6) Embodiment 1 (Selection of image data according to moving direction; N ≧ 3)
In the stereoscopic image display device according to any one of the supplementary notes 1 to 4,
When the number N of viewpoints is 3 or more (N ≧ 3), the image generation processing unit performs the observation based on the moving direction of the observer indicated in the positional information from the relative position calculation unit over time. A stereoscopic image display apparatus having an image data switching processing function for estimating a next movement position of a person and outputting a viewpoint image corresponding to the estimated position toward the stereoscopic image display panel.

(Supplementary note 7): First embodiment (selection of image data according to moving direction and moving speed; N ≧ 4)
In the stereoscopic image display device according to any one of the supplementary notes 1 to 4,
When the number N of viewpoints is 4 or more (N ≧ 4), the image generation processing unit displays a viewpoint image for a viewpoint area in which neither of the left and right eyes of the observer is located. A stereoscopic image display device characterized in that selection is made based on a moving direction and a moving speed, and this is output toward the stereoscopic image display panel.

(Supplementary Note 8): First Embodiment (Selection of Image Data According to Movement Direction and Movement Speed; N ≧ 4)
In the stereoscopic image display device according to any one of the supplementary notes 1 to 4,
When the number N of viewpoints is 4 or more (N ≧ 4), the image generation processing unit is based on the moving direction and moving speed of the observer indicated in the positional information from the relative position calculating unit over time. A stereoscopic image display apparatus having an image data selection processing function for estimating a moving position of the observer and outputting a viewpoint image corresponding to the estimated position toward the stereoscopic image display panel.

(Supplementary Note 9): First Embodiment (Selection of Image Data According to Movement Direction and Movement Speed; N ≧ 4)
In the stereoscopic image display device according to the appendix 7 or 8,
The image generation processing unit is a first to (N-2) th to (N-2) th viewpoints where a viewpoint area where the observer is positioned before moving is set as a viewpoint area where none of the left and right eyes of the observer is positioned. A stereoscopic image display device, characterized in that the second adjacent viewpoint region is selected.

(Supplementary note 10): Second embodiment (viewpoint pitch in the case of two viewpoints)
In the stereoscopic image display device according to any one of the supplementary notes 1 to 4,
In the stereoscopic image display panel, when the number of viewpoints N is 2 (N = 2), the viewpoint pitch between the viewpoint areas at the optimal observation distance that maximizes the stereoscopic viewing range is the binocular interval of the observer. A stereoscopic image display device characterized by being configured to be smaller than (= 65 mm).

(Supplementary Note 11): Second Embodiment (Considering Crosstalk Area)
In the stereoscopic image display device according to appendix 10,
When the stereoscopic image display panel has the viewpoint pitch as e, the binocular interval as d, and the range of the viewpoint area that is equal to or smaller than a preset 3D crosstalk value as f, “(e + f)>d> e A stereoscopic image display device characterized in that it is configured to satisfy the relationship "

(Supplementary Note 12): Second Embodiment (Considering Crosstalk Area)
In the stereoscopic image display device according to any one of the supplementary notes 1 to 4,
For the stereoscopic image display panel, the viewpoint pitch between the viewpoint areas at the optimum viewing distance that maximizes the stereoscopic viewing range is e, the distance between the eyes of the observer is d, and is equal to or less than a preset 3D crosstalk value. A stereoscopic image display device configured so as to satisfy a relationship of “(e + f)>d> e” when the range of the viewpoint region is f.

(Supplementary note 13): Third embodiment (viewpoint pitch in multiple viewpoints)
In the stereoscopic image display device according to any one of appendices 1 to 9,
When the viewpoint number N is 3 or more, the viewpoint pitch between the viewpoint areas at the optimum observation distance at which the stereoscopic viewing range is maximum is e, and the binocular distance of the observer is d.
A stereoscopic image display device, wherein the stereoscopic image display panel is configured to satisfy a relationship of “e × (N−2) ≦ d ≦ e × (N−1)”.

(Supplementary Note 14): Fourth Embodiment (Vertical and Horizontal 3D)
In the one-dimensional stereoscopic image display device according to any one of appendices 1 to 13,
Each pixel has N × N (N is a natural number of 2 or more) sub-pixels that are color-coded into primary colors of M colors (M is a natural number of 1 or more), and is arranged in a matrix on the display panel. Arranged,
The light beam separating means has an optical element that distributes the emitted light from each pixel according to the parallax image in a first direction and a second direction along the arrangement of the pixels,
This optical element is arranged in a matrix in association with each pixel,
The adjacent sub-pixels in each pixel have different color schemes,
The arrangement pitch of the sub-pixels is uniform in the first and second directions,
Within each pixel, the same number of parallax images with respect to the first direction and the second direction are displayed,
A stereoscopic image display device, wherein the number of sub-pixels having different color schemes is equal in the parallax image.

(Supplementary Note 15): Fourth Embodiment (Detecting Unit)
In the stereoscopic image display device according to appendix 14,
A detector that detects a displacement of the apparatus main body including the display panel;
The stereoscopic image display device, wherein the image generation processing unit has a function of generating the viewpoint image based on the relative position and displacement information from the detection unit.

(Supplementary note 16): Fourth embodiment (horizontal and vertical two-way display)
In the stereoscopic image display device according to appendix 15,
The detection unit is in a first arrangement state in which a horizontal direction that is parallel to a straight line connecting the left eye and right eye of the observer and the first direction are parallel, or the horizontal direction and the second direction. Has a function of determining whether or not the second arrangement state is parallel,
The image generation processing unit
When the square root √M of M, which is the number of primary colors, is an integer, the quotient (L) obtained by dividing N by √M is used as the number of viewpoints in the horizontal direction and in the vertical direction orthogonal thereto. And generating an image having parallax for the number of viewpoints corresponding to each of the first and second directions,
When the square root √M of M is not an integer, the quotient (L) obtained by dividing N by M is used as the number of viewpoints in the horizontal direction and the vertical direction, and each of the first and second directions. A stereoscopic image display device that generates an image having parallax for the number of viewpoints corresponding to the number of viewpoints.

(Supplementary Note 17): Fourth Embodiment (Horizontal View Pitch> Vertical View Pitch)
In the stereoscopic image display device according to any one of appendices 14 to 16,
Either the first direction or the second direction is in a state along a horizontal direction parallel to a straight line connecting the left eye and the right eye of the observer, and the other is perpendicular to the horizontal direction. When in a state along the vertical direction,
The stereoscopic image display panel is configured so that the horizontal parallax pitch is larger than the vertical parallax pitch.

(Supplementary Note 18): Fifth Embodiment, etc. In the stereoscopic image display device according to any one of Supplementary Notes 1 to 13,
The light beam separating means has a structure for separating light beams in one direction (x direction: light beam separating direction) of the arrangement directions of the pixels,
The image generation processing unit displays an image corresponding to the position of the observer in another direction (direction perpendicular to the one direction in the display surface: y direction) in the arrangement direction of the pixels. A three-dimensional image display device, characterized in that it is generated and output toward the three-dimensional image display panel.

(Supplementary Note 19) First to Fourth Embodiments The stereoscopic image display device according to any one of Supplementary Notes 1 to 18, and
A terminal device including the three-dimensional image display device.

(Appendix 20)
A display panel in which a plurality of pixels are arranged and a parallax from each pixel toward a plurality of N viewpoints (N is a natural number of 2 or more) provided on the display surface side of the display panel according to the arrangement direction of the pixels. A stereoscopic image display panel including a light beam separating means for separating an image; an observer position measuring unit that measures the position of an observer facing the display surface; and a display controller that generates the parallax image according to the measurement result; And a stereoscopic image display device having
The observer position measurement unit measures the observation position of the observer,
The display controller calculates the relative position of the observer with respect to the stereoscopic image display panel based on the measurement result,
The display controller generates viewpoint images for J viewpoints (J> N) set in advance,
The display controller specifies a plurality of viewpoint images corresponding to the relative position from the generated viewpoint images,
A stereoscopic image display method, wherein the display controller outputs the identified plurality of viewpoint images toward the stereoscopic image display panel.

(Appendix 21)
A display panel in which a plurality of pixels are arranged and a parallax from each pixel toward a plurality of N viewpoints (N is a natural number of 2 or more) provided on the display surface side of the display panel according to the arrangement direction of the pixels. A stereoscopic image display panel including a light beam separating means for separating an image; an observer position measuring unit that measures the position of an observer facing the display surface; and a display controller that generates the parallax image according to the measurement result; And a stereoscopic image display device having
The observer position measurement unit measures the observation position of the observer,
The display controller calculates the relative position of the observer with respect to the stereoscopic image display panel based on the measurement result,
The display controller identifies a plurality of viewpoints for image emission based on the relative position from among preset J viewpoints (J> N),
A stereoscopic image display method, wherein the display controller generates viewpoint images corresponding to the plurality of identified viewpoints and outputs the generated viewpoint images toward the stereoscopic image display panel.

(Appendix 22)
A display panel in which a plurality of pixels are arranged and a parallax from each pixel toward a plurality of N viewpoints (N is a natural number of 2 or more) provided on the display surface side of the display panel according to the arrangement direction of the pixels. A stereoscopic image display panel including a light beam separating means for separating an image; an observer position measuring unit that measures the position of an observer facing the display surface; and a display controller that generates the parallax image according to the measurement result; And a stereoscopic image display device having
An observer measuring means for measuring the observation position of the observer;
An observer position calculating means for calculating a relative position of the observer with respect to the stereoscopic image display panel based on the measurement result;
After generating viewpoint images for J viewpoints (J> N) set in advance, a plurality of viewpoint images corresponding to the relative position are specified from the generated viewpoint images, and the specified viewpoints Image generation processing means for outputting an image to the stereoscopic image display panel;
A stereoscopic image display program for causing a computer provided in advance in the display controller to function.

(Appendix 23)
A display panel in which a plurality of pixels are arranged and a parallax from each pixel toward a plurality of N viewpoints (N is a natural number of 2 or more) provided on the display surface side of the display panel according to the arrangement direction of the pixels. A stereoscopic image display panel including a light beam separating means for separating an image; an observer position measuring unit that measures the position of an observer facing the display surface; and a display controller that generates the parallax image according to the measurement result; And a stereoscopic image display device having
An observer measuring means for measuring the observation position of the observer;
An observer position calculating means for calculating a relative position of the observer with respect to the stereoscopic image display panel based on the measurement result;
A plurality of viewpoints for image emission are specified from the preset J viewpoints (J> N) based on the relative positions, and viewpoint images corresponding to the specified plurality of viewpoints are generated and the viewpoint images are generated. Image generation processing means for output to a stereoscopic image display panel;
A stereoscopic image display program for causing a computer provided in advance in the display controller to function.

  The stereoscopic image display device according to the present invention can be applied to various display devices that display images.

DESCRIPTION OF SYMBOLS 1 Stereoscopic image display apparatus 10,210 Stereoscopic image display panel 11, 211 Display panel 12 Light beam separation means 15 Lens 21 Display panel drive circuit 22 Image distribution control circuit 24, 25 Display controller 30 Image generation process part 31 Calculator 32 Data storage Section 33 Memory 34 External IF
40 Relative position calculation unit 45 Observer position measurement unit 50a, 51a, 52a First viewpoint area (horizontal direction)
50b, 51b, 52b Second viewpoint area (horizontal direction)
50c, 51c, 52c Third viewpoint area (horizontal direction)
50d, 51d, 52d Fourth viewpoint area (horizontal direction)
51aa, 51ab, 51ac, 51ad First viewpoint area sub-area 54a, 55a First viewpoint area (vertical direction)
55b, 56b Second viewpoint area (vertical direction)
59a, 59b, 59c, 59d Rays 60a, 61a First viewpoint images 60b, 61b Second viewpoint images 61c Third viewpoint images 61d Fourth viewpoint images 61e Fifth viewpoint images 61f Sixth viewpoint images 64 3D Object 65a First viewpoint camera 65b Second viewpoint camera 65c Third viewpoint camera 65d Fourth viewpoint camera 65e Fifth viewpoint camera 65f Sixth viewpoint camera 66 Intersection 70a, 70b, 71b, 72a 3D crosstalk value 80, 81, 82 stereoscopic viewing area 90, 91, 92 stereoscopic viewing area 92a, 92b, 92c, 92d, 92e stereoscopic viewing area 85 reverse viewing area 100 observer 101 left eye (observer left eye)
102 Right eye (observer right eye)
110a, 110b, 110c, 110d position (observer position)
111a, 111d, 112a, 112d position (observer position)
113a, 113b, 113c, 113d position (observer position)
114a, 114b, 114c position (observer position)
115a, 115b, 115c, 115d position (observer position)
150 Detection Unit 151 Inclination Angle Detection Unit 221 Pixel (4 × 4 Subpixel)
234 sub-pixel R
235 Sub-pixel B
236 Subpixel G
237 sub-pixel W
241, 241 ′ sub-pixel group in the first arrangement state (first viewpoint region)
242, 242 ′ sub-pixel group in the first arrangement state (second viewpoint region)
243, 243 ′ sub-pixel group in the first arrangement state (third viewpoint region)
244, 244 ′ sub-pixel group in the first arrangement state (fourth viewpoint region)
245, 245 ′ Sub-pixel group in the second arrangement state (first viewpoint region)
246, 246 ′ sub-pixel group in the second arrangement state (second viewpoint region)
247, 247 ′ sub-pixel group in the second arrangement state (third viewpoint region)
248, 248 ′ sub-pixel group in the second arrangement state (fourth viewpoint region)
250 ray separation means 251 lens array element 261 first viewpoint sub-pixel 262 second viewpoint sub-pixel 263 pixel 300 terminal device 310 housing

Claims (7)

A display panel in which a plurality of pixels are arranged, and a plurality of N viewpoints (N is a natural number of 2 or more) according to the arrangement direction of the pixels provided on the display surface side of the display panel. A three-dimensional image display panel comprising: a light beam separating means for separating a parallax image;
An observer position measuring unit that measures the observation position of the observer facing the display surface;
A relative position calculation unit that calculates the relative position of the observer with respect to the stereoscopic image display panel based on the measurement result;
It has a function of generating viewpoint images for J viewpoints (J> N) set in advance, and generates one or more viewpoint images corresponding to each viewpoint constituting the N viewpoints in association with the relative positions. An image generation processing unit for outputting to the stereoscopic image display panel,
When the number N of viewpoints is 3 or more, the image generation processing unit generates a viewpoint image for a viewpoint area where none of the left and right eyes of the observer is located based on the moving direction of the observer. A stereoscopic image display device characterized by selecting and outputting the selected viewpoint image toward the stereoscopic image display panel. A display panel in which a plurality of pixels are arranged, and a plurality of N viewpoints (N is a natural number of 2 or more) according to the arrangement direction of the pixels provided on the display surface side of the display panel. A three-dimensional image display panel comprising: a light beam separating means for separating a parallax image;
An observer position measuring unit that measures the observation position of the observer facing the display surface;
A relative position calculation unit that calculates the relative position of the observer with respect to the stereoscopic image display panel based on the measurement result;
It has a function of generating viewpoint images for J viewpoints (J> N) set in advance, and generates one or more viewpoint images corresponding to each viewpoint constituting the N viewpoints in association with the relative positions. An image generation processing unit for outputting to the stereoscopic image display panel,
When the number N of viewpoints is 4 or more, the image generation processing unit converts a viewpoint image into a viewpoint area where none of the left and right eyes of the observer is located in the moving direction and moving speed of the observer. A stereoscopic image display device characterized in that it is selected based on the above and is output to the stereoscopic image display panel. The stereoscopic image display device according to claim 2,
The image generation processing unit is a first to (N-2) th to (N-2) th viewpoints where a viewpoint area where the observer is positioned before moving is set as a viewpoint area where none of the left and right eyes of the observer is positioned. A stereoscopic image display device, characterized in that the second adjacent viewpoint region is selected. A display panel in which a plurality of pixels are arranged, and a plurality of N viewpoints (N is a natural number of 2 or more) according to the arrangement direction of the pixels provided on the display surface side of the display panel. A three-dimensional image display panel comprising: a light beam separating means for separating a parallax image;
An observer position measuring unit that measures the observation position of the observer facing the display surface;
A relative position calculation unit that calculates the relative position of the observer with respect to the stereoscopic image display panel based on the measurement result;
It has a function of generating viewpoint images for J viewpoints (J> N) set in advance, and generates one or more viewpoint images corresponding to each viewpoint constituting the N viewpoints in association with the relative positions. An image generation processing unit for outputting to the stereoscopic image display panel,
Each pixel has N × N (N is a natural number of 2 or more) sub-pixels that are color-coded into primary colors of M colors (M is a natural number of 1 or more), and is arranged in a matrix on the display panel. Arranged,
The light beam separating means has an optical element that distributes the emitted light from each pixel according to the parallax image in a first direction and a second direction along the arrangement of the pixels,
This optical element is arranged in a matrix in association with each pixel,
The adjacent sub-pixels in each pixel have different color schemes,
The arrangement pitch of the sub-pixels is uniform in the first and second directions,
Within each pixel, the same number of parallax images with respect to the first direction and the second direction are displayed,
The number of sub-pixels with different color schemes is equal in the parallax image;
A detector that detects a displacement of the apparatus main body including the display panel;
The image generation processing unit has a function of generating the viewpoint image based on the relative position and displacement information from the detection unit,
The detection unit is in a first arrangement state in which a horizontal direction which is parallel to a straight line connecting the left eye and right eye of the observer and the first direction are parallel, or the horizontal direction and the second direction. And a function of determining whether or not the second arrangement state is parallel,
The image generation processing unit
When the square root √M of M, which is the number of primary colors, is an integer, the quotient (L) obtained by dividing N by √M is used as the number of viewpoints in the horizontal direction and in the vertical direction orthogonal thereto. And generating an image having parallax for the number of viewpoints corresponding to each of the first and second directions,
When the square root √M of M is not an integer, the quotient (L) obtained by dividing N by M is used as the number of viewpoints in the horizontal direction and the vertical direction, and each of the first and second directions. A stereoscopic image display device that generates an image having parallax for the number of viewpoints corresponding to the number of viewpoints. The stereoscopic image display device according to claim 4 ,
Either the first direction or the second direction is in a state along a horizontal direction parallel to a straight line connecting the left eye and the right eye of the observer, and the other is perpendicular to the horizontal direction. When in a state along the vertical direction,
The stereoscopic image display panel, the stereoscopic image display apparatus, characterized in that the horizontal parallax pitch is configured to be larger than the parallax pitch of the vertical direction. The stereoscopic image display device according to any one of claims 1 to 5 ,
A stereoscopic image display device, wherein the number of viewpoints N and the number of viewpoints J satisfy a relationship of J = s × N (coefficient s is a natural number of 2 or more). A stereoscopic image display device according to any one of claims 1 to 6 ,
A terminal device comprising: a housing containing the stereoscopic image display device.

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