JPH10186277A - Method of displaying stereo image and stereo image display device using it - Google Patents

Abstract

PROBLEM TO BE SOLVED: To permit to change over a stereo image to/from a plane image or coexistence display without loss of resolution even with a slow speed display device. SOLUTION: This stereo image display method divides a right and left parallax images into two or more stripe pixels, displays a horizontal stripe image arranged in a fixed order on a transmission type display device 5, illuminates the display device by giving a directivity to luminous flux from an illumination source of light 1 by an optical system, and separates the luminous flux having penetrated the left or the right stripe pixel to a left eye area or a right eye area. At this time, the number of scanning lines of the parallax image or the number of pixels in the vertical direction is expressed by N; the number of scanning lines of the display device is expressed by 2N; the stripe pixels are divided in each scanning lines; and one pixel vertical size PH and one pixel horizontal size PW of the display device should meet a requirement of an expression 0.40PW<=PH<=0.50PW.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional image display method and a three-dimensional image display apparatus using the same, and more particularly to a two-dimensional two-dimensional image and a three-dimensional image using a display device having a low display speed (frame frequency). The present invention relates to a display that can display a three-dimensional image without lowering the resolution and a normal high-definition two-dimensional image at the same time.

[0002]

2. Description of the Related Art Hitherto, a lenticular system or a parallax barrier system has been proposed as a stereoscopic image display apparatus without glasses. However, these methods have a problem that the lenticular lens and the parallax barrier are obstructive. Further, in these methods, two parallax images must be divided into a large number of stripe pixels, and a stripe image in which these are alternately arranged must be synthesized and displayed. Therefore, there is a problem that the resolution of the image display device is reduced to at least half of the original parallax image.

Further, in these systems, it has been difficult to switch between a normal two-dimensional image and a three-dimensional image for display or to mix and display them.

A three-dimensional image display device which solves these disadvantages is disclosed in Japanese Patent Application Laid-Open No. Hei 5-284542. This stereoscopic image display device is composed of a matrix type surface light source, a lenticular sheet, a transmittance control element comprising a polymer dispersed liquid crystal (PDLC) cell, and a transmission type display device. In this device, the transmittance control element is in a transparent state in the area displaying the three-dimensional image, and is synchronized with the lighting of the striped light source for the right eye and the left eye, so that the right and left frames are shifted to the even frame and the odd frame, respectively. The parallax image is displayed on the transmissive display device, while in the area displaying the two-dimensional image, the transmittance control element is in a scattering state, and an even number is determined according to the lighting of the striped light source for the right eye and the left eye. The same image is displayed for both frames and odd frames.

[0005]

In a lenticular type or parallax barrier type stereoscopic image display device, a normal
When displaying a two-dimensional image as it is, if it is displayed as it is, it only enters the position corresponding to the vertical stripe image of the pair of the image for the right eye and the image for the left eye, so the images entering the right eye and the left eye slightly differ There is a problem that the display becomes an image, and when a fine character or pattern is displayed, the display becomes very difficult to see.

In order to improve the above problem, if the same image is inserted in the right-eye image and the left-eye image and arranged in pairs in a vertical stripe, the same image is observed in the right and left eyes.
Although it is easier to see, the resolution drops to half that of a normal 2D image.

Further, in the stereoscopic image display devices of these systems, when the observer deviates from the optimal observation position for stereoscopic display, moire between the black matrix and the barrier separating the pixels of the liquid crystal display occurs, causing black stripes and uneven light quantity. It becomes visible and very unsightly as a normal 2D display.

Furthermore, in these conventional stereoscopic image display devices, the size of one pixel of the liquid crystal display used is substantially square, and the number of scanning lines or the number of pixels in the vertical direction of the parallax image to be displayed is N and the number of scanning lines of the liquid crystal display is N. If N is also
A stripe image for displaying a stereoscopic image must inevitably combine the left and right parallax images alternately for each pixel, and the vertical resolution of the original parallax image incident on each eye is 1 /
Had dropped to two.

In the stereoscopic image display device disclosed in Japanese Patent Application Laid-Open No. 5-284542, two parallax images of a right-eye image and a left-eye image are displayed in a time-division manner. In order to solve the above problem, it is necessary to switch images at high speed, and there is a problem that a display device capable of high-speed display is required as a twisted nematic liquid crystal cell used for a matrix type surface light source and a transmission type display device.

An object of the present invention is to switch between a three-dimensional image and a two-dimensional image without lowering the resolution, or to display them in a mixed manner, even if a display device having a low display speed (frame frequency) is used. Can be done, and
An object of the present invention is to provide a stereoscopic image display method in which moiré and light amount unevenness do not occur even if the optimal position for stereoscopic vision is shifted, and a stereoscopic image display device using the same.

The present invention is a novel stereoscopic image display method applicable to not only a stereoscopic image display device without glasses but also a stereoscopic image display device using glasses and a stereoscopic image display device using the same.

[0012]

According to the present invention, there is provided a stereoscopic image display method comprising the steps of: (1-1) converting a left parallax image corresponding to a left eye and a right parallax image corresponding to a right eye into a plurality of stripes long in the horizontal direction. A horizontal stripe image divided into pixels, arranged in a predetermined order, and synthesized is displayed on a transmissive display device, and the optical system gives directionality to a light beam from an illumination light source to illuminate the display device, thereby causing left parallax. In the stereoscopic image display method for visually recognizing a stereoscopic image by separating the light flux transmitted through the stripe pixels of the image into the left eye region and the light flux transmitted through the stripe pixels of the right parallax image into the right eye region separately, Assuming that the number of scanning lines or the number of pixels in the vertical direction between the image and the right parallax image is N, the number of scanning lines of the display device is 2N, and the stripe pixels are divided in units of scanning lines. Lee and size P _H in the vertical direction of one pixel of the device and the horizontal size P _W is wherein like satisfy the relation _{0.40P W ≦ P H ≦ 0.50P W} .

In particular, (1-1-1) the one pixel is composed of one color pixel of each of red, green and blue. (1-1-2) The optical system includes: a mask having a mask pattern including checkerboard-shaped openings and light-shielding portions from the illumination light source toward the display device; and a vertical lenticular lens having a vertical generating line of the cylindrical lens. Having. (1-1-3) The optical system has a horizontal lenticular lens in which the generating line of the cylindrical lens is horizontal between the mask and the display device. (1-1-4) When an original plane image having the number of scanning lines N is displayed as a plane image on a part or the entire surface of the display device, and the horizontal stripe image and the plane image are mixed or switched, the display is used. Image data on one scan line of the original flat image is repeatedly input and displayed for two consecutive scan lines in the flat image display area of the device. (1-1-5) The optical system includes a light directivity control element that can control a part or the entire surface between the mask and the display device to be in a light transmitting state and a light scattering state. (1-1-6) The light directivity control element is formed of a polymer dispersed liquid crystal cell. (1-1-7) displaying an original plane image having the number of scanning lines N as a plane image in a plane image display area of the display device corresponding to the area of the light directivity control element controlled to the light scattering state; When the horizontal stripe image and the plane image are mixed or switched and displayed, the same image data on one scanning line of the original plane image is repeatedly input and displayed for two consecutive scanning lines in the plane image display area. I do. (1-1-8) displaying an original plane image having the number of scanning lines N as a plane image in a plane image display area of the display device corresponding to the area of the light directivity control element controlled to the light scattering state; When a horizontal stripe image and a plane image are mixed or switched and displayed, for two consecutive scanning lines in the plane image display area, image data for one scanning line of the original plane image, and the image data The image data interpolated from the image data of the subsequent scanning line is input and displayed. (1-1-9) The horizontal stripe image displayed in the stereoscopic image display area of the display device thins out image data of stripe pixels in an area corresponding to the stereoscopic image display area in the left parallax image and the right parallax image. It is displayed without typing. (1-1-10) The left parallax image and the right parallax image are images captured by two cameras each having an image sensor. (1-1-11) An original plane image having the number of scanning lines N is displayed as a plane image on a part or the entire surface of the display device, and when the horizontal stripe image and the plane image are mixed or switched and displayed, the original plane image is displayed. The plane image is the left parallax image or the right parallax image. It is characterized by

Further, the stereoscopic image display method according to the present invention comprises:
-2) A transmissive horizontal stripe image obtained by dividing each of the left parallax image corresponding to the left eye and the right parallax image corresponding to the right eye into a plurality of horizontally elongated stripe pixels, arranging them in a predetermined order, and combining them. Illuminating the display device with a light beam from the illumination light source as linearly polarized light in a predetermined polarization axis direction, controlling the polarization of light emitted from the display device by polarization control means, In the stereoscopic image display method for visually recognizing a stereoscopic image using a light beam emitted from the display device, the number of scanning lines or the number of pixels in the vertical direction of the left parallax image and the right parallax image is N, and the number of scanning lines of the display device is 2N. , and the said stripe pixels is divided by scan line basis, the display device of the size of one pixel P _H and horizontal size P _W and is relationship 0.40P _W ≦ P _H in the vertical direction It is characterized by like satisfying 0.50P _W.

Particularly, (1-2-1) the one pixel is composed of one color pixel of each of red, green and blue. (1-2-2) The polarization control means alternately forms horizontal stripe polarizers long in the horizontal direction on the display device such that the polarization axes of transmitted light are different from one another for each scanning line of the display device. It is a polarizing plate. (1-2-3) When displaying an original plane image having the number of scanning lines N as a plane image on a part or the whole surface of the display device, and displaying the horizontal stripe image and the plane image in a mixed or switched manner, Image data on one scan line of the original flat image is repeatedly input and displayed for two consecutive scan lines in the flat image display area of the device. (1-2-4) When displaying an original plane image having the number of scanning lines N as a plane image on a part or the entire surface of the display device, and displaying the horizontal stripe image and the plane image in a mixed or switched manner, For two consecutive scanning lines in the plane image display area of the device, image data for one scanning line of the original plane image and image data interpolated from the image data and the image data of the following scanning lines are input. To display. (1-2-5) The horizontal stripe image displayed in the stereoscopic image display area of the display device thins out image data of stripe pixels in an area corresponding to the stereoscopic image display area in the left parallax image and the right parallax image. It is displayed without typing. (1-2-6) The left parallax image and the right parallax image are images captured by two cameras each including an image sensor. (1-2-7) When an original plane image having the number of scanning lines N is displayed as a plane image on a part or the whole surface of the display device, and when the horizontal stripe image and the plane image are mixed or switched, the original plane image is displayed. The plane image is the left parallax image or the right parallax image. It is characterized by

Further, the three-dimensional image display device of the present invention uses: (1-3) the three-dimensional image display method described in any one of (1-1) to (1-2-7). It is characterized by.

[0017]

FIG. 1 is a perspective view of a main part of a first embodiment of a stereoscopic image display apparatus according to the present invention. FIG. 2 shows Embodiment 1.
FIG. 1 is an explanatory diagram of the principle of stereoscopic image display in FIG.
The cross section along the horizontal plane indicated by the line A--A is shown in FIG.
FIG. 2B is a cross-sectional view along a horizontal plane indicated by B (here, a scanning line one scanning line below the scanning line indicated by the line AA).

In the figure, 1 is a backlight light source (illumination light source)
Reference numeral 2 denotes a mask on one side of which is formed a mask pattern including checkerboard-shaped openings and light-shielding portions, which is manufactured by patterning chromium or a light absorbing material on a substrate such as glass or plastic. Reference numeral 3 denotes a vertical lenticular lens, and the generatrix direction of the cylindrical lens constituting the lens is vertical. Reference numeral 4 denotes a lateral lenticular lens, and the generatrix direction of the cylindrical lens constituting the lens is horizontal. The two lenticular lenses have their generatrix directions orthogonal to each other. Reference numeral 5 denotes a transmissive display device such as a transmissive liquid crystal element, which has 2N scanning lines. Figure 1,
FIG. 2 schematically shows the state of the display image on the image display surface.

The mask 2, the vertical lenticular lens 3, the horizontal lenticular lens 4 and the like constitute one element of the optical system.

Reference numeral 6 denotes an image processing means, which divides the right parallax image R and the left parallax image L having the number of scanning lines N into a large number of stripe pixels in scanning line units, respectively, and divides them in a predetermined order as described later. One horizontal stripe image is formed by arranging vertically, and is output to the display drive circuit 7. The display drive circuit 7 drives the display device 5 according to the input horizontal stripe image signal and displays a horizontal stripe image thereon.

The stereoscopic image display method of the present embodiment will be described with reference to FIG. As shown in FIG.
The light emitted from the mask 2 having the center of the opening at a position shifted by a predetermined distance with respect to the optical axis of the vertical lenticular lens 3 and the vertical lenticular lens 3, the luminous flux transmitted through the mask 2 has directivity, right eye region of the right eye E _R of the observer arrives separated into (range arrow). At this time, since the horizontal lenticular lens 4 has no optical power in the horizontal direction, the horizontal lenticular lens 4 performs the same operation as a simple parallel plate without any operation.

At this time, the light beam incident on the right eye region is
The image is modulated by the image (here, the stripe pixel Ri of the linear right parallax image) displayed on the transmission type display device 5 provided between the vertical lenticular lens 3 and the observer, and is modulated by the linear right stripe pixel Ri. modulated light beam is incident on the right eye E _R of the observer.

A light beam along a section corresponding to a scanning line below one scanning line in FIG. 2 (A) is modulated by a linear left stripe pixel Li as shown in FIG. 2 (B). light bundle is incident to separate the left eye region, is incident on the left eye E _L of the observer.

That is, the display device 5 is illuminated by giving directivity to the light beam from the illumination light source by the optical system, and the light beam transmitted through the stripe pixels of the right parallax image is applied to the right eye region, and the stripe pixels of the left parallax image are applied to the display device 5. The transmitted luminous flux is split and made incident on the left eye region.

At this time, the opening of the mask 2 in the cross section of FIG. 2A and the opening of the mask 2 in the cross section of FIG. The mask pattern has openings and light-shielding portions formed in a checkered pattern as shown in FIG.

The display device 5 displays a horizontal stripe image in which left and right stripe pixels respectively corresponding to one horizontal row of openings are alternately arranged in the vertical direction. Therefore, the observer can see the stripe pixels corresponding to each eye with the left or right eye for each scanning line, and visually recognize the left or right parallax image with the left or right eye as a set of stripe pixels. And a stereoscopic image can be observed.

Next, the operation of the lateral lenticular lens 4 will be described. The horizontal lenticular lens 4 has an image forming function only in the vertical direction, and crosses a predetermined stripe pixel of the display device 5 (one stripe pixel is represented by one scanning line) by a light beam emitted from the opening of the mask 2. It is configured to illuminate without talk. Then, the light flux emitted from the opening of the mask 2 and spread in the vertical direction is condensed on predetermined stripe pixels of the display device 5, and the image lines (stripe pixels) corresponding to the respective openings are illuminated and transmitted. Diverges only in the vertical direction according to the NA at the time of condensing, so that an observation area where the left and right images can be uniformly separated from the predetermined eye height of the observer over the entire vertical width of the screen is obtained. Has become. With the above operation, the observer can observe a stereoscopic image displayed in a vertically wide viewing area.

With such a configuration, in the conventional parallax barrier system or lenticular system, moire fringes occur between the black matrix of the liquid crystal display and the barrier or lenticular lens. Since the directivity is given to the light 1 using the above-mentioned optical system, these moire fringes do not occur.

FIG. 3 is an explanatory diagram of the pixel arrangement of the display device 5 used in the first embodiment. One pixel of the display device 5 can perform color display by itself,
One pixel is composed of one color pixel each of red (r), green (g), and blue (b), and the vertical size (height) P _H of one pixel is changed to the horizontal size (width) P _W Is formed in approximately half of

Here, the horizontal stripe image displayed on the display device 5 will be described. FIG. 4 shows the embodiment.
FIG. 2 is an explanatory diagram of a method for forming a horizontal stripe image of FIG. Although the right parallax image R and the left parallax image L each have the number of scanning lines N, the image processing means 6 divides the image into stripe pixels in units of scanning lines (width of one pixel) in the vertical direction. In this specification, the stripe pixels divided from the right parallax image R are called right stripe pixels, and the stripe pixels divided from the left parallax image L are called left stripe pixels. Since one scanning line is scanned in the horizontal direction with a width of one pixel in the vertical direction, the stripe pixel has a vertical width of one pixel and a horizontal width of the entire screen.

Then, as shown in FIG. 3 or FIG. 4, right stripe pixels Ri and left stripe pixels Li are alternately arranged every other scanning line as shown in the right part of FIG. To form That is, a right stripe pixel R1 is arranged on the first scanning line, a left stripe pixel L1 is arranged on the second scanning line, a right stripe pixel R2 is arranged on the third scanning line, and a horizontal stripe image having 2N scanning lines is synthesized. create.

[0032] Here, when forming a line of the right stripe pixels R1 to the first scan line as shown in FIG. 3 for example, right stripe pixels R1 is formed by arranging a R ₁₁ R ₁₂ R ₁₃ ··· and the pixel,
As described above, each pixel (for example, R ₁₁ ) having the width _PW is composed of red (for example, r ₁ ), green (for example, g ₁ ), and blue (for example, b ₁ ) color pixels.

For example, if the parallax images R and L are each VGA (640 horizontal × 480 vertical pixels), the number of pixels of the display device 5 used in this embodiment is as described above.
Since the vertical size (height) P _H of one pixel is half of the horizontal size (width) P _W , it is 640 horizontal × 960 vertical pixels, and the total size of the two parallax images R and L is A horizontal stripe image can be created using the pixel information. Moreover, the aspect ratio 4: 3 of the display device 5 does not change.

The image data of the horizontal stripe image created in this way is input to the display drive circuit 7, which displays the horizontal stripe image on the display device 5 and views the stereoscopic image according to the principle described above. Can be.

Accordingly, since the horizontal stripe image of the present embodiment displays the image data of the stripe pixels obtained by dividing the right parallax image R and the left parallax image L alternately without thinning, a high-resolution stereoscopic image is displayed. Can be observed.

In the first embodiment, a case has been described in which an image created on a computer such as a CG image is used as a parallax image. However, a parallax image used in the present invention may be an image created on a computer, a compound eye camera, or the like. This is a natural image captured by a stereo camera or two cameras having an image sensor.

FIG. 5 is a perspective view of a main part of a modification of the first embodiment. In the first embodiment, each of the stripe pixels of the horizontal stripe image is illuminated without crosstalk by using two lenticular lenses having different optical functions in the horizontal direction and the vertical direction. However, the lateral lenticular lens 4 is not always necessary. In the case of this modification, since the checkered mask 2 and the vertical lenticular lens 3 are appropriately set, satisfactory stereoscopic vision can be obtained even without the horizontal lenticular lens 4.

At this time, it is desirable that the size (height) of the opening in the vertical direction of the checker-like mask pattern of the mask 2 is set slightly smaller in order to control the directivity in the vertical direction.

FIG. 6 is a perspective view of a main part of another modification of the first embodiment. This modification is a horizontal stripe-shaped second mask between the mask of the modification of FIG.
8 to control the directivity in the vertical direction.
These configurations are described in Japanese Patent Application No.
It has already been proposed in 8-40469 and Japanese Patent Application No. 8-37431.
It goes without saying that the display method of the present invention can be applied to this method.

Next, a method of displaying a two-dimensional planar image (non-stereoscopic image, that is, the term is used as a planar image) using Embodiment 1 will be described. In this case, since the original plane image is displayed as a plane image on the display device 5, the original plane image is referred to as an original plane image. And the number of scanning lines of the original plane image is
N.

When displaying a two-dimensional image, the same image data on one scanning line of the original two-dimensional image may be repeatedly input and displayed twice for two adjacent scanning lines of the display device 5.

As described above, in the three-dimensional image display apparatus of the present invention, the luminous flux modulated by the image of that portion is incident on the right eye or the left eye for each scanning line. Since the resolution in the vertical direction is doubled as shown in FIG. 4, the same plane image with the same resolution is observed with the left and right eyes, and the plane image is displayed in the same manner as a normal two-dimensional image display device. Images can be observed.

Therefore, according to the first embodiment, in some cases, a horizontal stripe image is displayed on the entire screen of the display device 5 to display a stereoscopic image, and in other cases, two adjacent scanning lines are scanned one scan of the original plane image. By displaying the line image twice and displaying the planar image, it is possible to switch between the horizontal stripe image (stereoscopic image) and the planar image.

If it is not necessary to display a stereoscopic image, a left or right parallax image may be displayed as a planar image as an original plane image.

Further, in the first embodiment, a horizontal stripe image composed of left and right parallax images is displayed on a part of the display device 5 and two adjacent scanning lines are displayed on the other part of one scanning line of the original plane image. If the image is displayed twice, the stereoscopic image and the planar image can be mixed and displayed.

At this time, if a left or right parallax image is used as the original plane image, a portion displaying a horizontal stripe image in one display image can be observed as a three-dimensional image, and a portion displayed as a two-dimensional image is a non-stereo image. Can be observed as

Next, a second embodiment will be described. In the first embodiment, the stereoscopic image is displayed over the entire display screen.
You may want to switch between two-dimensional display and three-dimensional display. Embodiment 2 of the present invention is such a stereoscopic image display device.

FIG. 7 is a perspective view of a main part of a stereoscopic image display apparatus according to a second embodiment of the present invention. In the present embodiment, a light directivity control element 9 is provided between the horizontal lenticular lens 4 and the display device 5 of the first embodiment, and is driven by a drive circuit 10.

The light directivity control element 9 is composed of, for example, a polymer dispersed liquid crystal cell (PDLC) and can be controlled by an applied electric field to a light transmitting state in which incident light is transmitted or a light scattering state in which incident light is scattered. . By controlling the light directivity control element 9 and the display image of the display device 5 by a method described later, a horizontal stripe image as a stereoscopic image and a two-dimensional plane image can be switched and displayed,
They are mixed and displayed.

FIG. 7 shows a case where a horizontal stripe image (stereoscopic image) is displayed over the entire surface of the display device 5. At this time, a display control signal for displaying a horizontal stripe image is output from a system controller (not shown) to the drive circuit 10 and the image processing means 6, and a voltage is applied from the drive circuit 10 to the entire surface of the light directivity control element 9, The light directivity control element 9 is controlled to a non-scattered light transmitting state.

At the same time, the image processing means 6
As described in 1, the horizontal stripe image is synthesized, the display device 5 is driven via the display drive circuit 7, and the horizontal stripe image in which the stripe pixels are aligned with R1L1R2L2R3L3. Display on the whole surface. Then, a stereoscopic image can be observed according to the principle described in the first embodiment.

On the other hand, when displaying a two-dimensional planar image over the entire surface of the display device 5, the voltage is not applied to the light directivity control element 9, this is controlled to a light scattering state, and the display device 5 is controlled. For two consecutive scanning lines, the same image data on one scanning line of the original plane image is repeatedly input and displayed to display a plane image.

At this time, the light from the backlight light source 1 has directivity until it enters the light directivity control element 9, but is scattered in all directions by the light directivity control element 9, and _L
Enters the light beam also the right eye E _R supposed to reach the light flux should reach back to the right eye E _R is also incident on the left eye E _L, it will be observed the same image with both eyes, normal As in the case of the two-dimensional display, all the two-dimensional images on the display device 5 can be visually recognized with both eyes.

However, the display device of the present embodiment
5 is the vertical size (height) P of one pixel size
_H is formed to half of the horizontal size (width) P _W , and the number of scanning lines is 2N, twice the number of scanning lines N of the original plane image, so a two-dimensional plane image is displayed. In this case, the same image is displayed on the display device 5 every two lines. In this way, a normal planar image can be observed.

When a planar image is displayed in the present embodiment, the left and right eyes can visually recognize the planar image as an image having 2N scanning lines, so that the definition of the planar image is higher than in the first embodiment.

The image on the kth scanning line of the original plane image is displayed on the nth scanning line of the display device 5 (where n is an odd number), and the image on the kth scanning line of the original plane image is displayed. Using the data and the image data on the (k + 1) th scanning line, the image data between the two scanning lines is obtained by interpolation, and the image data is input and displayed on the (n + 1) th scanning line of the display device 5. If you do, 2
A two-dimensional image can be displayed. The method of displaying these plane images will be described in a later embodiment.

As described above, in the present embodiment, it is possible to switch and display between a stereoscopic image display without a decrease in resolution and a two-dimensional planar image display.

The position of the light directivity control element 9 may be any position between the display device 5 and the mask 2.

Next, a third embodiment of the present invention will be described. In the second embodiment, the display can be switched between a stereoscopic image and a planar image over the entire display screen. However, in some cases the main screen part is 2
While working on a screen with high resolution by displaying a two-dimensional plane image, there is a case where it is desired to provide a window for displaying a three-dimensional image only in a partial area of the screen and proceed with the work while referring to the window. A stereoscopic image display device suitable for this purpose is desired to be able to switch a part of the screen between a two-dimensional image display (flat image display) and a three-dimensional image display (horizontal stripe image display). Embodiment 3 of the present invention is such a stereoscopic image display device.

In the third embodiment, the electrodes of the light directivity control element 9 according to the second embodiment are formed in a matrix, and a voltage is partially applied so that a predetermined area on the element is in a non-scattered light transmitting state. Thus, it is possible to partially display a horizontal stripe image (stereoscopic image). The configuration of the apparatus is the same as that of FIG.

FIG. 8 is an explanatory diagram of a method of generating a display image when a three-dimensional image is partially displayed in the third embodiment. Here, as shown in FIG.
3 A horizontal stripe image (stereoscopic image) is displayed in the stereoscopic image display area 11 surrounded by the first pixel of the scanning line to the fourth pixel of the sixth scanning line.
Is schematically illustrated. In this specification, an area for displaying a horizontal stripe image on the display device 5 is referred to as a three-dimensional image display area, and an area for displaying a two-dimensional image is referred to as a two-dimensional image display area.

The two parallax images R each having the number of scanning lines N (FIG. 8)
(A)) and L (FIG. 8 (B)) corresponding to the three-dimensional image display area 11, respectively, from the first pixel of the second scanning line to the third pixel of the third scanning line.
It is a part consisting of four pixels. The stripe pixels in this portion are alternately input for each scanning line of the display device 5, and are alternately input without thinning out the image data on the scanning lines of the parallax image as shown in the stereoscopic image display area 11 in FIG. Then, a horizontal stripe image is synthesized and displayed.

The flat image display area other than the three-dimensional image display area 11 is an area corresponding to the three-dimensional image display area 11 of the original two-dimensional image having the number of scanning lines N, as shown in FIG. Two
The image of the portion consisting of the first pixel of the scanning line to the fourth pixel of the third scanning line is deleted, for example, the image data on the first scanning line is
FIG enter the P ₁₁ P ₁₂ P ₁₃ ··· as image data of the second scan line of the first scan line and the second scan line of the display device 5
Display as shown in 8 (D).

FIG. 8D is a schematic diagram showing in detail the portion up to the seventh pixel of the display image shown in FIG.
9 (A). In this way, the horizontal stripe image is synthesized and displayed on the stereoscopic image display area 11 in the display device 5, and the image data on the same scanning line of the original plane image is displayed for every two adjacent scanning lines in the plane image display area. For example, the first scan line and the second scan line have the same data.

That is, the display device 5 of this embodiment has a vertical length (height) P of one pixel size.
_H is formed in half of the horizontal length (width) _PW , and the aspect ratio of the display pixel size is different. Therefore, the same image must be displayed every two scanning lines in the flat image display area.

At this time, as shown in FIG. 9 (B), a voltage is partially applied to a region 12 corresponding to the stereoscopic image display region 11 of the light directivity control element 9 so that a non-scattered light transmitting state is obtained. And the other regions are in a light scattering state without applying a voltage.

Thus, the directivity of the light from the illumination light source incident on the region 12 is maintained, and the light beam modulated by the left stripe pixel or the right stripe pixel enters the left or right eye and enters the three-dimensional image display region 11. A stereoscopic image can be observed.

Then, since the light from the illumination light source which is incident on the area other than the area 12 of the light directivity control element 9 is scattered here, the light passes through the right or left stripe pixel on the display device 5 and the left and right eyes equally. And the left and right eyes can observe a plane image having 2N scanning lines.

When displaying a planar image on the display device 5, the image on the kth scanning line of the original planar image is displayed on the nth scanning line of the display device 5.
(Where n is an odd number), using the image data on the k-th scanning line and the image data on the (k + 1) -th scanning line of the original plane image, obtain the image data between the two scanning lines by interpolation. Enter the image data, display device
It may be displayed by the (n + 1) th scanning line of 5.

FIG. 10 schematically shows the composite display image at this time. Here, the stereoscopic image display area 11 is omitted because it combines the horizontal stripe image in the same manner as described above, and the display of a two-dimensional planar image will be described.

As shown in FIG. 10, the display device 5
The image data of the original plane image shown in FIG.
To display the _{P 11 P 12 P 13 ··· P} 17. Next, on the second scanning line, image data P ₁₁ P ₁₂ P ₁₃ ... P ₁₇ of the first scanning line of the original plane image,
Image data of the second scanning line of the original plane image P ₂₁ P ₂₂ P ₂₃・ ・ ・ P ₂₇
Image data by performing an interpolation process _{P '11 P' 12 P '} 13 ··· P' 17 becomes scan line one line up or down by using the image data for two lines to create the new, the display device 5 Second
It is assumed that the image data is to be displayed on a scanning line.

As described above, even-numbered image data is obtained by interpolation and is displayed, whereby a higher-definition planar image can be partially displayed.

Next, a fourth embodiment will be described. Although the embodiments described so far are stereoscopic image display devices capable of observing a stereoscopic image without using glasses, the stereoscopic image display method of the present invention can also be used for a stereoscopic image display device using polarized glasses. Embodiment 4 of the present invention is such a stereoscopic image display device.

FIG. 11 is a perspective view of a principal part of a stereoscopic image display apparatus according to a fourth embodiment of the present invention. Also in this embodiment, a horizontal stripe image (stereoscopic image) and a two-dimensional planar image can be switched and displayed, or can be mixed and displayed. In FIG. 12, the third embodiment is performed on the display device 5.
3 shows a case where a stereoscopic image is displayed in the same portion 11.

As shown in FIG. 11, this embodiment is an illumination light source.
1 and transmissive display devices such as transmissive liquid crystal devices
5 and a polarizing plate (polarization control means) 13 formed thereon. The polarizing plate 13 is provided with two kinds of horizontal stripe-shaped horizontal stripe polarizing plates 14 and 15 on the display device 5 which are horizontally long so that the polarization axis of transmitted light is different for each adjacent scanning line. It is arranged alternately on the top. The observer observes the display device 5 by wearing polarizing glasses having the same polarization axis as the two types of horizontal stripe polarizing plates on the left and right eyes.

The number of scanning lines of the display device 5 is 2N, and a left parallax image and a right parallax image having the number N of scanning lines are respectively converted into left and right stripe pixels in scanning line units in a stereoscopic image display area for displaying a horizontal stripe image. A horizontal stripe image that has been divided, arranged in a predetermined order, and synthesized is displayed, and a plane image display area for displaying a plane image is one of the original plane images having the number of scanning lines N.
The image on the scanning line is
The point of repeatedly displaying on the scanning line is the same as in the previous embodiments.

The display device 5 of the present embodiment
The pixel structure and the horizontal / vertical size ratio are the same as in the previous embodiments.

The operation of the present embodiment for displaying a stereoscopic image will be described. The light emitted from the illumination light source 1 has its polarization direction aligned by a polarizing plate (not shown), and illuminates the display device 5. Then, the observer wearing the above-mentioned polarized glasses observes the stripe pixel corresponding to each eye with the left or right eye.

That is, as shown in FIG. 11, the horizontal stripe polarizing plate 14 having the same polarization axis as the analyzer 14 'of the right eye portion of the polarizing glasses is placed on the odd scanning lines of the display device 5.
On the even-numbered scanning lines, there is a horizontal stripe polarizer 15 having the same polarization axis as the analyzer 15 'of the left eye portion of the polarized glasses. Then, the polarization axes of the horizontal stripe polarizers 14 and 15 are inclined by 45 degrees from the vertical direction, respectively, so as to be orthogonal to each other.

At this time, the direction of the polarization axis of a polarizing plate (not shown) arranged on the illumination light source 1 side of the display device 5 is
It can be vertical or horizontal. Alternatively, the horizontal stripe polarizers 14 and 15 alternately formed in stripes and the stripe polarizers in a crossed Nicols state are alternately arranged, that is, the polarizers 13 alternately formed in stripes. However, a polarizing plate formed in a polarization state shifted by a half pitch from the above may be used.

When a twisted nematic liquid crystal is used as the display device 5 to be used, the latter polarizing plate is preferable because of its higher light transmittance. In this manner, by associating the analyzer (polarizing plate) of the liquid crystal display device 5 with the polarizing plate of the polarizing glasses, the stripe pixels corresponding to each eye can be separated and observed by each eye. .

Therefore, as shown in FIG.
If a right stripe pixel is arranged on an odd-numbered scanning line and a left stripe pixel is arranged on an even-numbered scanning line in 11 and a horizontal stripe image is synthesized and displayed, a stereoscopic image can be observed in this region. At this time, an image on one scanning line of the original planar image is displayed twice over two consecutive scanning lines in the planar image display area.

As described above, the present invention can be applied not only to a stereoscopic image display device without glasses but also to a stereoscopic image display device using glasses.

As described above, the three-dimensional image display device of the present invention
When displaying a stereoscopic image, the right stripe pixel Ri
Alternatively, display the left stripe pixel Li and display the backlight light source 1
Is modulated by the stripe pixels and incident on the right eye or the left eye, respectively. At this time, the resolution in the vertical direction is doubled as shown in FIG.

In displaying a two-dimensional image, the same image is displayed by two scanning lines that are partially adjacent to each other, so that the left and right eyes observe the same two-dimensional image having the same resolution. The same display as the three-dimensional image display device can be performed.

Therefore, the three-dimensional image display device of the present invention can switch between a two-dimensional image and a three-dimensional image at a high resolution and display or mix and display.

In the present invention, the vertical size P _W and the horizontal size P _H of one pixel of the display device are set.
If the range of the conditional expression 0.40P _W ≦ P _H ≦ 0.50P _W follows the purposes of this invention the.

In the above embodiment, color display is premised.
What is necessary is just to comprise with the color pixel of a color.

[0089]

As described above, according to the present invention, even when a display device having a low display speed (frame frequency) is used, a three-dimensional image and a two-dimensional image can be switched and displayed without reducing the resolution, or mixedly displayed. And a stereoscopic image display method using the same, which does not cause moiré or uneven light amount even when the optimal position for stereoscopic vision is shifted.

[Brief description of the drawings]

FIG. 1 is a perspective view of a main part of a stereoscopic image display device according to a first embodiment of the present invention.

FIG. 2 is a diagram illustrating the principle of displaying a stereoscopic image according to the first embodiment.

FIG. 3 is an explanatory diagram of a pixel arrangement of a display device 5 according to the first embodiment.

FIG. 4 is a diagram illustrating a method of forming a horizontal stripe image according to the first embodiment.

FIG. 5 is a modification of the first embodiment.

FIG. 6 shows another modification of the first embodiment.

FIG. 7 is a perspective view of a main part of a stereoscopic image display apparatus according to a second embodiment of the present invention.

FIG. 8 is an explanatory diagram of a display image generation method when a stereoscopic image is partially displayed in the third embodiment of the present invention.

FIG. 9 is an explanatory diagram of an image display state of a display device and a control state of a light directivity control element according to a third embodiment.

FIG. 10 is an explanatory diagram of an image display state when a planar image is displayed by interpolation of image data in the third embodiment.

FIG. 11 is a perspective view of a main part of a stereoscopic image display device according to a fourth embodiment of the present invention.

FIG. 12 is a diagram illustrating an image display state of the display device according to the fourth embodiment.

[Explanation of symbols]

 1 Illumination light source 2 Mask 3 Vertical lenticular lens 4 Horizontal lenticular lens 5 Display device 6 Image processing means 7 Display drive circuit 8 Second mask 9 Directivity control element 10 Drive circuit 11 Stereoscopic image display area 13 Polarizer 14 Horizontal stripe polarizer 15 Horizontal stripe polarizer

Claims (21)

[Claims] 1. A horizontal stripe image obtained by dividing each of a left parallax image corresponding to a left eye and a right parallax image corresponding to a right eye into a plurality of stripe pixels that are long in the horizontal direction and arranging and combining them in a predetermined order. Display on a transmissive display device,
The optical device gives directivity to the light beam from the illumination light source to illuminate the display device, the light beam transmitted through the stripe pixels of the left parallax image is used as the left eye area, and the light beam transmitted through the stripe pixels of the right parallax image is used as the right eye image. In a three-dimensional image display method of visually recognizing a three-dimensional image by separating and entering a region, the number of scanning lines or the number of pixels in a vertical direction of the left parallax image and the right parallax image is N, and the number of scanning lines of the display device is
2N, and the stripe pixels are divided in units of scanning lines, and the vertical size P _H and the horizontal size P _W of one pixel of the display device are expressed by a relational expression 0.40 P _W ≦ P _H ≦ 0.50 P _W A stereoscopic image display method characterized by satisfying. 2. The stereoscopic image display method according to claim 1, wherein said one pixel is constituted by one color pixel of each of red, green and blue. 3. The optical system includes a mask having a mask pattern formed of checkerboard-shaped openings and light-shielding portions from the illumination light source toward the display device, and a vertical lenticular lens having a vertical generating line of a cylindrical lens. The stereoscopic image display method according to claim 1 or 2, wherein: 4. The stereoscopic image display method according to claim 3, wherein said optical system has a horizontal lenticular lens having a horizontal generating line of a cylindrical lens between said mask and said display device. 5. An original plane image having the number of scanning lines N is displayed as a plane image on a part or the entire surface of the display device, and when the horizontal stripe image and the plane image are mixed or switched to be displayed, the display device has The method according to any one of claims 1 to 4, wherein image data on one scanning line of the original plane image is repeatedly input and displayed for two consecutive scanning lines in the plane image display area. 3D image display method. 6. The optical system according to claim 3, wherein a part or the whole of the optical system has a light directivity control element between the mask and the display device, the light directivity control element being capable of controlling a light transmitting state and a light scattering state. 4. A stereoscopic image display method. 7. The stereoscopic image display method according to claim 6, wherein said light directivity control element comprises a polymer dispersed liquid crystal cell. 8. An original plane image having the number of scanning lines N is displayed as a plane image on a plane image display area of the display device corresponding to an area of the light directivity control element controlled to a light scattering state, and the horizontal stripes are displayed. When an image and a plane image are mixed or switched and displayed, the same image data on one scanning line of the original plane image is repeatedly input and displayed for two consecutive scanning lines in the plane image display area. The stereoscopic image display method according to claim 6 or 7, wherein: 9. An original plane image having the number of scanning lines N is displayed as a plane image in a plane image display area of the display device corresponding to an area of the light directivity control element controlled to a light scattering state, and the horizontal stripes are displayed. When displaying an image and a planar image in a mixed or switched manner, for two consecutive scanning lines in the planar image display area, image data for one scanning line of the original planar image, the image data and the 8. The stereoscopic image display method according to claim 6, wherein image data interpolated from image data of a subsequent scanning line is input and displayed. 10. The horizontal stripe image displayed in the stereoscopic image display area of the display device without thinning out image data of stripe pixels in an area corresponding to the stereoscopic image display area in the left parallax image and the right parallax image. The stereoscopic image display method according to claim 1, wherein the stereoscopic image is input and displayed. 11. The stereoscopic image display method according to claim 10, wherein the left parallax image and the right parallax image are captured by two cameras having an image sensor. 12. An original plane image having a scanning line number N is displayed as a plane image on a part or the entire surface of the display device, and the horizontal stripe image and the plane image are mixed or switched to be displayed. The stereoscopic image display method according to any one of claims 1 to 11, wherein? Is the left parallax image or the right parallax image. 13. A horizontal stripe image obtained by dividing each of a left parallax image corresponding to the left eye and a right parallax image corresponding to the right eye into a plurality of stripe pixels long in the horizontal direction and arranging and combining them in a predetermined order. The display device is displayed on a transmission type display device, illuminates the display device with a light beam from an illumination light source as linearly polarized light in a predetermined polarization axis direction, and controls the polarization of light emitted from the display device by polarization control means. In a three-dimensional image display method for visually recognizing a three-dimensional image using a light beam emitted from a control unit, the number of scanning lines or the number of pixels in a vertical direction of the left parallax image and the right parallax image is set to N, and the number of scanning lines of the display device is set to N. Is
2N, and the stripe pixels are divided in units of scanning lines, and the vertical size P _H and the horizontal size P _W of one pixel of the display device are expressed by a relational expression 0.40 P _W ≦ P _H ≦ 0.50 P _W A stereoscopic image display method characterized by satisfying. 14. The stereoscopic image display method according to claim 13, wherein said one pixel is composed of one color pixel of each of red, green and blue. 15. The polarization control means comprising: a polarization device formed by alternately arranging horizontal stripe polarizers long in the horizontal direction on the display device such that the polarization axes of transmitted light are different from one another for each scanning line of the display device. The stereoscopic image display method according to claim 13, wherein the method is a plate. 16. Displaying an original plane image having the number of scanning lines N as a plane image on a part or the entire surface of the display device, and displaying or displaying the horizontal stripe image and the plane image in a mixed or switched manner. The image data according to any one of claims 13 to 15, wherein image data on one scanning line of the original plane image is repeatedly inputted and displayed for two consecutive scanning lines in the plane image display area. 3D image display method. 17. Displaying an original plane image having the number of scanning lines N as a plane image on a part or the whole surface of the display device, and displaying the horizontal stripe image and the plane image in a mixed or switched manner. For two consecutive scanning lines in the plane image display area, input and display image data for one scanning line of the original plane image, and image data interpolated from the image data and the image data of the scanning lines subsequent thereto. The stereoscopic image display method according to any one of claims 13 to 15, wherein: 18. The horizontal stripe image displayed in the stereoscopic image display area of the display device without thinning out image data of stripe pixels in an area corresponding to the stereoscopic image display area in the left parallax image and the right parallax image. 18. Input and display are performed.
The stereoscopic image display method according to any one of the above items. 19. The stereoscopic image display according to claim 13, wherein the left parallax image and the right parallax image are images obtained by two cameras provided with an imaging device. Method. 20. An original plane image having the number of scanning lines N is displayed as a plane image on a part or the entire surface of the display device, and the horizontal stripe image and the plane image are mixed or switched to be displayed. The stereoscopic image display method according to any one of claims 13 to 19, wherein is the left parallax image or the right parallax image. 21. A three-dimensional image display device using the three-dimensional image display method according to claim 1. Description: