JP3234840B2 - Display device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device used for displaying multiple images such as a video conference or a highly realistic image display, for example, when displaying multiple images photographed from different places or from different directions. Depending on where you look at the displayed video,
Though, it relates to a display <br/> equipment can see an image that reproduces the photographed location or shot direction as if you were on the same space.

[0002]

2. Description of the Related Art In recent years, with the development of communication technology such as image coding technology, two-way video communication such as a TV (hereinafter referred to as TV) telephone and a TV conference system connecting remote locations with a video / audio communication network. Are rapidly spreading. In the future, ISD
A video service full of a sense of reality is expected by the enhancement of the N network and the increase of the bandwidth of the transmission network.

[0003] In the case of a TV conference, since a large number of people usually have a conversation instead of one-on-one, it is important to match the eyes of a plurality of people.

Referring to FIG. 7, a TV between two points X and Y at the present time is shown.
The case of a meeting will be described. At each of the points, one to a plurality of photographing devices and display devices are installed, and in the example, the photographing devices Xa, Xb, and Xc at the X point and the display devices Y1, Y2, and Y3 at the Y point correspond to each other. Photographing devices Ya and Y at point Y
b and Yc correspond to the display devices X1, X2 and X3 at the X point. For convenience, the photographers Xa, Xb, and Xc photograph the interlocutors XA, XB, and XC in front of them, and display the interlocutors XA, XB, and XC on the display devices Y1, Y2, and Y3 at the Y point.
Are displayed individually. Display device Y1, Y2, Y3 at point Y
YA, YB, and YC in front of the user look at the display devices Y1, Y2, and Y3, and see the display devices Y1, Y2, and Y3.
You will stare at A, XB, and XC. For example, when the interlocutor YB interacts with XB, the interlocutor YB can interact with each other while staring at each other through the display device Y2 and the display device X2. However, the interlocutor Y
When B interacts with the interlocutor XC, Y
Instead of the display device of 2, the user shakes his / her head to the right to see the interlocutor XC displayed on the display device of Y3. When the interlocutor XC faces the display device X2 as shown by the broken line, the image of the interlocutor XC photographed by the photographing device Xc is displayed horizontally on the display device Y3 as indicated by Y3 'in the figure. , And the interlocutor YB interacts with the interlocutor XC displayed in the horizontal direction without adjusting the line of sight.

[0005] As a method of compensating for the deviation of the line of sight between the interlocutors in this way and matching the lines of sight of a plurality of interlocutors, the display screen has a function that "the degree of light scattering varies depending on the incident angle of light. Screen "
Also, by projecting and displaying on the display screen from the oblique direction or the vertical direction of the rear surface of the display screen using the projection device, the interlocutors YA, YB, and YC at the front surface of the display screen each have their heads at angles γ, 0, −. Japanese Patent Application No. 5-35889 proposes a device that allows the user to talk face-to-face with a speaker at the point X by shaking the camera horizontally. As a display screen, light projected at an arbitrary angle from a projection device to an arbitrary point on the screen forms an image on the screen, and the transmitted light luminance distribution indicating the intensity of transmitted light scattering is a specific observation angle with respect to the screen. A semi-transmissive diffuser plate having a strong directivity characteristic having a peak is applied. On the other hand, like a light control plate whose manufacturing method is described in JP-A-64-77001, the light is scattered with respect to light in one incident direction, and therefore becomes opaque, and is opaque to light in another incident direction. Has been proposed which has a property of transmitting light and has a scattering directivity peak for light having a specific projection angle. The method of manufacturing this light control plate uses a light source that has a linear shape when viewed from the irradiated position (film surface),
It is produced by photocuring and is described in detail in the above publication.

[0006]

[SUMMARY OF THE INVENTION However, in the display device using the subscription <br/> over emissions scattering of light by the incident angle of light having a different function, a semi-permeable scattering plate, a screen surrounding However, there are disadvantages such as that an image other than the projection image of interest leaks and multiple images are observed as the image approaches the portion, and that the display luminance at the periphery of the screen decreases. For reference , see Japanese Patent Application Laid-Open No. 64-77001.
Only the light control plate described in Japanese Patent Application Laid-Open Publication No. H10-260, in which the light source has a linear shape when viewed from the irradiated position (film surface) when the resin composition is formed into a film and light cured. In order to use and manufacture, the scattering direction of the projection light that becomes a display image is one-dimensional. For example, if the scattering direction is excellent in the horizontal direction, the scattering direction in the vertical direction is inferior. The display shows a band-like luminance. Therefore, the light control plate alone is not enough to uniformly display a display image in all directions, and the light control plate and the semi-transmissive scattering plate are combined, or the cured sheet constituting the light control plate is partially cut. There is a drawback that the display screen configuration is complicated, such as using a screen stuck on a transparent diffusion plate.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned drawbacks of the conventional display devices and display screens, and has as its object to provide a display device used for a TV telephone, a TV conference system, etc., and a multi-image display in general. For example, it is possible to clearly separate and view multiple images from a plurality of directions, for example, by enabling gaze matching between a large number of interlocutors,
In subjecting Hisage <br/> display equipment which can improve the image quality of a displayed image.

[0008]

In order to achieve the above object, the invention of a display device according to claim 1 includes a plurality of optional devices .
Transmitted light image at exit angle in the same direction as each projection angle
Scattering angle at which the brightness of the sample shows a peak value and is half the peak value
Brightness angles off-has the property of rapidly reduced and the risk that the scattering direction and the display screen is a two-dimensional
Projection display at different projection angles from the rear side of the lean
And a plurality of projection devices for multiple of the screen
Any projection angle on the same display screen
Each projection table at a particular projection angle from Kifuku number of the projection device
Whether the displayed image is a specific emission angle corresponding to the projection angle
The angle is set so that it can be observed separately from other images .

[0009] Similarly, the invention of the display device according to the second aspect is characterized in that a convex lens is provided between the display screen and the projection device according to the first aspect.

[0010]

[0011]

In the display device according to the first aspect of the present invention,
Emission angle in the same direction as each of multiple arbitrary projection angles
Indicates the peak value of the luminance of the transmitted light image, and indicates a half value of the peak value.
The display screen having a characteristic in which the brightness of the angle deviating from the scattering angle suddenly decreases, the projection light serving as display images from a plurality of projection devices having different projection angles in a direction corresponding to the projection angle. By scattering two-dimensionally, multiple images can be separated and displayed without lowering the peripheral luminance.

According to a second aspect of the present invention, an image projected and displayed on the display screen according to the first aspect is condensed in the direction of an observer by a condensing action of a convex lens. The display brightness on the screen surface is made uniform, and the image quality of the displayed video is improved.

[0013]

[0014]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a view showing a first embodiment of the display device according to the present invention, and shows one embodiment of the invention according to the first aspect. In the present embodiment, a video in a video conference between a plurality of interlocutors will be described as a video projected and displayed on the same display screen. For the sake of simplicity, a conference between two points X and Y will be described, and a case where an image captured at point X is displayed at point Y will be described. Actually, since it is a two-way video communication, it is necessary to display the video taken at the point Y at the point X. However, in the description of the present embodiment, the point X and the point Y may be interchanged and considered in the same manner. .

The objects (XA, XB) at the point X,
A plurality of photographing devices (Xa _C , Xb _L ), (Xa _R , Xb _C ) so that each set of (XC, XD) can be photographed from different directions.
Place. Here, the suffix _C of the image capturing device captures an image in the front direction, the suffix _L indicates that the image is captured in the left direction, and the suffix _R indicates that the image is captured in the right direction. Further, a and b indicate installation locations of the photographing devices corresponding to the display device display screens Y1 and Y2.

Images of the subject photographed by the plurality of photographing devices at the point X are transmitted to the plurality of projecting devices at the point Y and displayed on the display screens Y1 and Y2. In this case, as described above, the same subject is photographed by a plurality of imaging devices, and a plurality of videos of the same subject are projected and displayed on a display device at another point. The correspondence between the captured image, the projection device, and the display screen is determined by the subject (X
A, XB) the captured projection apparatus images P _XAC, a display screen Y1 by P _XBL, subject (XC, XD) the captured projection apparatus images P _XaR, a display screen Y2 by P _XBC, respectively in correspondence Display. here,
The image projected and displayed by the projection device is “an image from an imaging device at another point having the same name as the subscript of the projection device P”.
The projection angle of the projection device P with respect to the display screen is suffix _C.
Indicates that the image is projected perpendicularly to the rear surface of the display screen, the suffix _L indicates that the image is projected from the left direction, and the suffix _R indicates that the image is projected onto the back surface of the display screen from the right direction.

[0018] The display screen shown here shows " multiple
Of the same direction as each of the arbitrary projection angles
The luminance of the overlit image shows a peak value and becomes half of the peak value.
Display screen having the characteristic that the luminance at angles outside the scattering angle suddenly drops and the scattering direction is two-dimensional "
Is used. That is, the image projected and displayed on the screen from the rear surface at a specific projection angle is observed from a specific observation angle (emission angle) corresponding to the projection angle on the screen front side to select the image displayed on the screen. Use a screen that has the property of being observable.

This embodiment exemplifies a case where two photographing devices having different directions are installed at the same installation location, and two projection devices for projecting an image on the same display screen are installed correspondingly. However, in the present invention, the number of imaging directions and the number of projection directions are not limited to two. Further, it goes without saying that the display device of the present invention is not particularly limited to a TV conference, and can be used for multi-image display in general, including high-presence image display. The display device of the present invention is capable of projecting and displaying a plurality of images on the same display screen at different projection angles, and separating the images by viewing the screen from a direction corresponding to the projection angle across the screen. It is. In the above embodiment, the case where the plurality of images projected on the same display screen are different images has been described.However, when these images are the same, the same image can be viewed even when the viewing angle for viewing the screen is different, An effect equivalent to an increase in the viewing angle of the screen can be obtained.
Therefore, the display device of the present invention does not particularly limit the type of video projected and displayed on the same display screen.

In order to explain the display screen of the display device of the present invention, when three types of images are projected on the same screen from three directions, the three types of images projected on the screen are separated according to the viewing direction. The display screen for displaying the information will be described.

A display screen having the property of being able to select and observe a plurality of images projected and displayed from different positions of the projection angle is referred to as a “screen having the same direction as each of a plurality of arbitrary projection angles ” .
The luminance of the transmitted light image shows a peak value at the emission angle, and the peak value
Brightness drops sharply at angles outside the scattering angle, which is half the value
A had the properties of the screen ", FIG. 2 (a-1)
As shown in FIG. 2, light projected from the projection device 101 to an arbitrary point on the screen 100 at an arbitrary projection angle θ
2A, an image transmitted through the measurement point 102 can be confirmed, and the transmitted light luminance distribution at this time can be changed to an arbitrary projection angle (an example of a transmitted light distribution curve 103 in FIG. 2A-1). Is a diffuser plate having a strong directivity characteristic having a peak at an emission angle with respect to θ = θ ₁ , 0, θ ₂ ). In other words,
When the luminance of the transmitted light image on the screen 100 was measured by changing the emission angle β _rl while moving the measurement point 102 left and right with the projection angle θ fixed, as shown in FIG. any incident angle _{(θ = θ 1, 0,} θ 2) indicates a large value luminance of the transmitted light image within a certain angle range centered 2δ the luminance of the transmitted light image at an angle outside this 2δ abruptly This is a diffuser plate exhibiting a transmitted light luminance characteristic that is reduced to a minimum. Here,
Emission angle β and projection angle θ that are half of the peak value of transmitted light luminance
Twice (2 | β−θ |) is referred to as a scattering angle 2δ.
As shown in FIGS. 2 (b-1) and 2 (b-2), the diffused directivity in the vertical direction when the projection angle changes in the horizontal direction hardly changes and has an appropriate transmitted light luminance distribution. In the figure, β _ud is the vertical emission angle.

Next, FIG. 3 shows a second embodiment of the display device of the present invention. This embodiment is an embodiment of the display device according to claim 2 of the present invention, in which a convex lens is provided between the display screen and the projection device, for example, near the focal length of the convex lens or at a distance longer than the focal length. It is a display device on which the plurality of projection devices are arranged. In this embodiment, a Fresnel lens 10 having a condensing function as the convex lens is arranged in front of a diffuser 11 having a strong directivity and having the above-mentioned transmitted light luminance characteristic as a display screen to display images in three directions. Show the case. When the projection images from the projection devices 12, 13, and 14 are viewed at the observation points 15, 16, and 17 via the diffusion plate 11,
By the light-condensing function of the Fresnel lens 10, it is possible to observe an image without a decrease in luminance up to the periphery of the screen. The Fresnel lens is an example of the convex lens in the present invention, and as the convex lens in the present invention, a normal convex lens or another lens having a light-collecting function can be used.

In the second embodiment, the projection device 1
Fresnel lens 10 having light condensing function with 2, 13, 14
(Hereinafter referred to as a convex lens 10) is referred to as a convex lens 1
Each of the projection devices 12, 13, and 13 has a case where the focal length is substantially equal to the focal length f of 0 and a case where the distance is longer than the focal length f.
A description will be given of how the size and position of the observation area in which the image projected from 14 can be observed change. 4 (a) and 4 (b), a diffuser 11 having a high directivity and having the above-described transmitted light luminance characteristic, which is a display screen, is a display screen for transmitting images 1, 2 and 3 from the projection devices 12, 13 and 14 respectively through the convex lens 10. (Hereinafter, referred to as a display screen 11), when projected and displayed so as to form an image, an observation region 115, an observation region 116, and an observation region 117 where these images 1, 2 and 3 can be observed are shown. FIG. 4A shows the projection devices 12, 13,
FIG. 4B shows a case where the respective installation positions are near the focal length f of the convex lens 10, and FIG.
This is a case where the installation positions of the lenses 3 and 14 are set at positions farther than the focal length f of the convex lens 10. As can be seen from these figures, the display screen 11 depends on the difference between the installation positions of the projection devices 12, 13, and 14 and the focal length f of the convex lens 10.
Since the incident angle of the projection light to the same point on the (convex lens 10) changes or the degree of refraction at the same point changes, the emission angle β _rl of the projection light (display light) after passing through the lens changes, and the image is observed brightly. The position and area that can be changed. Therefore, the projection device 1
By changing the installation position of 2, 13, 14 or changing the focal length f of the convex lens 10,
In the observation areas 115, 116, and 117 where the images 1, 2 and 3 can be seen, respectively, it is possible to observe the image at the periphery of the display screen 11 at a uniform brightness while further suppressing the decrease in the brightness of the image and at the same time. Observation areas 115, 11
6,117, or the observation areas 115, 11
6, 117 from the display screen 11 can be changed. The observation areas 115, 116, 1
Depending on the size of the projection lens 17 and the position from the display screen 11, the distance between the projection devices 12, 13, and 14 and the convex lens 10 may be set to be shorter than the focal length f of the convex lens 10. is there.

As a display screen used in the display device of the above embodiment, there is a sheet obtained by irradiating a plurality of film-shaped resin compositions having different refractive indices with light. This resin composition cured sheet is scattered for light at a specific projection angle,
Accordingly, the substrate is opaque, has a property of transmitting light of another projection angle, and has a characteristic of having a scattering directivity peak for a specific projection angle θ. The light control plate described in Japanese Patent Application Laid-Open No. 64-77001 is exemplified. This light control plate has an excellent function as a blind plate for a view in a certain angle direction, and its application is shown. However, when this light control plate is applied to a display screen of a projection image, the scattering direction of the projection light serving as the display image is one-dimensional. Inferiorly, when a projected image is displayed, the display shows a band-like luminance in the horizontal direction, and the display screen function of the present invention is insufficient. This is because, in the production method described in JP-A-64-77001, when a plurality of resin compositions having different refractive indices are formed into a film and photocured, the curing light source shape and irradiation method are as described above. This is because it is not suitable for producing the properties of the display screen.

Next, a reference example of a display screen used in the display device of the present invention will be described. This reference example is the present invention.
Viewing, showing an Example of a manufacturing method of a screen, it is intended to produce a light control plate in the manner of following the photocuring of. Assuming that the display image is projected and displayed from the projection device of the above-described display device, and from the same irradiation angle as the projection angle at the time of the projection display, the light is irradiated by the radial rays having the same incident angle. The resin composition formed into a film is cured. Here, the radial light beam is a light beam having directivity with respect to the light irradiation direction. A light source is applied to a film-shaped resin composition sheet to be photocured (hereinafter simply referred to as a sheet).
5 (a-1), (a-2),
(A-3), (b-1), (b-2), and (b-3) are cross-sectional views seen from above near the center of the sheet.

[0026] In the display screen manufacturing method of the present embodiment, first, from said projection angle and the same irradiation angle at which the projection display by the projection device, the same radial ray of the incident angle and the time of the projection, different refractive index A plurality of resin compositions are cured by irradiating light, and correspondingly to projection angles when different images are projected and displayed from the plurality of projection devices, respectively, sequentially, new films are respectively formed on the resin compositions. One sheet is manufactured by providing a resin composition in a shape and irradiating with a radial beam of light and photo-curing. Alternatively, the same resin composition is irradiated with light in the same manufacturing method as described above to be cured to produce a cured sheet, and the above-mentioned corresponding to the projection angle when different images are projected and displayed from the plurality of projection devices. It is also possible to manufacture the same number of cured sheets and to laminate these cured sheets. With such a sheet, the scattering direction of the projection light serving as the display image is two-dimensionally expanded since the angle at which the display image is projected corresponds to the irradiation angle at the time of curing, and the display image is uniformly displayed in all directions.

The cured resin composition sheet is called a light control plate. 5 (a-1), (a-
2) and (a-3) are film-like light rays that diverge obliquely with respect to the light center axis as the radial light rays move away from the light center axis 201 like light rays from a point light source 200 (point light source light rays). 5 (b-1) and (b-) when the irradiation is performed on the resin composition sheet 202 formed in (1) (the incident angle on the sheet greatly changes as the distance from the optical center axis increases).
2) and (b-3) show, as an example, the use of a Fresnel lens 203 having a light-condensing function to convert the rays of the radial rays into rays (parallel rays) parallel to the optical center axis 201 and the resin composition sheet 202. This is a case in which irradiation is performed. From these cross-sectional views, when light irradiation is performed on the sheet surface from the back left direction, the back front direction, and the back right direction, respectively, the light incident angles in the left and right directions of the sheet surface are different. On the other hand, the transmitted light luminance of the light control plate manufactured by curing the sheet with the radial light beam is such that incident light is centered around a specific projection angle θ as shown in the transmitted light luminance distribution shown in FIG. Scattered,
As the emission angle _βrl departs from the projection angle θ, it attenuates and decreases.

When a light control plate 204, which is irradiated with light from a right side of the resin composition sheet using a point light source beam from the back of the resin composition sheet and is light-cured, is used as a display screen to display a projected display image, the light FIG. 6A is a cross-sectional view of the vicinity of the center of the display screen viewed from above when the point light source projection light corresponding to the radial light source is applied. In addition, the light control plate 204 is irradiated with light from the back side of the resin composition sheet by applying a parallel light beam and cured by light. FIG. 6B is a cross-sectional view of the vicinity of the center of the display screen viewed from above when a projected display image is displayed using a display screen in which a Fresnel lens 203 having an optical function is combined. When projecting the point light source projection light onto the display screen, as the distance from the screen to the projection device becomes shorter, the tilt angle α from the observation point with respect to the incident light beam of interest on the screen becomes larger, and when the projection light is parallel, The tilt angle α is constant regardless of the distance from the screen to the projection device. The tilt angle α can be observed if it is within 1/2 of the scattering angle 2δ. In other words, it is possible to see an image on a screen in which the tilt angle is within half of the scattering angle. Alternatively, the distance from the screen to the observation point may be set so that the tilt angle is within 1/2 of the scattering angle. Therefore, the parallel light beam has a smaller tilt angle α than the point light source light beam, and the scattering angle 2δ can be reduced correspondingly.

FIGS. 6 (a) and 6 (b) show the case where the projection is performed from the rear right direction of the screen. However, when the projection display is performed from other directions, the irradiation angle at the time of curing and the projection at the time of the projection display are shown. The angles may be adjusted, and display may be performed using a Fresnel lens or the like as necessary so that the incident angles of the point light source projection light and the parallel projection light incident on the light control plate used for the screen are the same.

Up to this point, the case where the light beam irradiated on the sheet at the time of photocuring is a parallel light beam with a point light source light beam has been described. A parallel ray is a ray that converges the point source ray radially diverging as it separates from the optical center axis and makes it parallel to the optical center axis. The light may be cured by being incident on a sheet. In this case, similarly to the case of the point light source rays and the parallel rays, when the cured light control plate is applied to the display screen and projected and displayed, the projection light is also combined with the Fresnel lens and displayed by condensing. The tilt angle α can be made smaller than that of the point light source beam or the parallel beam.

As described above, the light control plate as the display screen used in the display device of the present invention is different from the conventional light control method in manufacturing. In other words, the irradiation light is controlled and cured during light curing in accordance with the projection angle at the time of projection display from the projection device and the incident angle of the projection light incident on the light control plate. In other words, when the light control plate is manufactured by curing the resin composition sheet, the light control plate is illuminated at the same irradiation angle as the projection angle at the time of projection display on the screen, and the light control at the time of projection display is performed. Irradiation is performed with radial rays having the same incident angle as the incident angle of the projection light on the plate.

The above, Oite the display equipment of the present invention, a plurality of image projected on the display screen by a plurality of projection devices having different projection angles, the same subject in different directions from different locations by a plurality of imaging devices When the captured image is applied, the image displayed on the display device is viewed from different places, that is, from different angles, so that the angle at which the subject is captured at the point where the imaging device is installed and the display device are installed. The angle at which the displayed image is viewed at the point at which the image is displayed can correspond to the sense of directly viewing the subject, that is, the feeling of being in the same place (real space).

The radial light source is disclosed in
An ultraviolet lamp is desirable, such as the light source disclosed in 4-77001. FIG. 5 (a-
Irradiation may be performed by controlling the incident angle as in 1) to (b-3).

Although the relationship between the optimum direction angles γ, γ ′ of the interlocutors YB, YA shown in FIG. 1 and the projection angle θ _P and the photographing angle θ _c almost coincide with each other, they are not necessarily completely. It is not necessary to match, and the transmitted light brightness and the brightness of FIG.
It suffices if it can be set within the margin of the scattering angle 2δ indicated by the characteristic of the emission angle.

In the description of FIG. 1, the image is directly projected from the projection device to the display screen. However, it is apparent that a reflection mirror may be provided between the projection device and the display screen for projection. is there.

In the video communication using the display device of this embodiment, a case of a conference between two points is taken up for the sake of simplicity of explanation, and it has been described that the line of sight of the parties to be discussed can be matched. Is not limited. In this embodiment, the case where two interlocutors are present in front of each display screen has been described with reference to FIG. 1, but the number of interlocutors is not particularly specified. Similarly, in FIG. 1, the number of installation locations and the number of display screens of the imaging devices at each point are described as two, but the number is not particularly limited. The number may be arbitrarily set in consideration of the number of projection devices that project and display the same display screen at different projection angles, the number of display screens, and the number of installation devices of the imaging device. At this time, unlike the case where the diffusion plate having the strong characteristic of directivity is applied to the display screen, when the light control plate is applied, the specific projection angle indicating the scattering directivity peak is set to the projection angle of the projection device. Must match. For example, when the number of display screens is set to three, images are taken from three places where the photographing device is installed, and three display devices project and display one display screen from three directions.

In the present embodiment, a plurality of images projected by a projection device having different projection angles on the same screen are used as images of a videoconversation interlocutor. For this reason, by associating the direction in which the display device is viewed with the direction in which the interlocutor is photographed from the image capturing device, it is possible to realize realistic video communication as if the interlocutor were viewed from the installation point of the imaging device.

Although the present embodiment has been described based on a video conference system between a plurality of interlocutors, the present invention
The present invention is not limited to the video conference system, and in the case of different point-to-point communication using images, when viewing images with different viewpoints through display devices at different points, the direction in which the display device is viewed is the direction in which the subject is photographed from the photographing device. In other words, video communication with a sense of realism is realized as if the subject is viewed from the installation point of the imaging device.

The display device of the present invention is not limited to two-way video communication such as a video conference as in the above embodiment, but a plurality of images are projected on the same display screen by a projection device having different projection angles. A background image as well as a display device such as a theater, a video room, an exhibition room or the like in which each of the images separated from the plurality of images can be observed in spite of the same screen depending on the position / angle at which the display screen is viewed. It can also be applied as a display device that produces

[0040]

As described above, according to the display device of the present invention, the projection in the same direction as each of a plurality of arbitrary projection angles is performed.
The luminance of the transmitted light image shows a peak value at the launch angle, and the peak value
The brightness at angles outside the scattering angle, which is half the value of
Since a plurality of images are displayed on the same display screen by a plurality of projection devices having different projection angles by using a display screen having a two-dimensional scattering direction, When the displayed image is viewed from different places and from different angles, the projected image from the projection device having the projection angle corresponding to the viewing angle can be clearly separated and viewed in spite of the same screen. Therefore, to the plurality of images, for example, by applying an image of the same subject in different directions from different locations by a plurality of remote imaging devices, from the point where the imaging device is installed, as if The displayed image can be viewed as if it were viewed directly.

In the display device according to the second aspect of the present invention,
In particular, since a convex lens for condensing light is provided between the projection device and the display screen, an image with uniform display luminance can be observed on the screen. Also, by changing the distance between the projection device and the convex lens or the focal length of the convex lens, it is possible to change the size of the area where the image can be observed with uniform display luminance and the position from the screen.

[0042]

Therefore, by using the display device of the present invention as a display device for two-way video communication such as a video conference,
The person in front of you talks with the person in front of you, staring at the image in front, and the person in front of you diagonally and in the same way as in the actual conversation, moves your neck and body toward the person, and matches your eyes with your body movements. In order to talk with each other, you can enjoy the feeling of being in front of your eyes even though you are through the video, and the feeling of talking in the same place. That is, it is possible to give a sense of dialogue on the display device in the real space (the same space).

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of an embodiment of a display device according to claim 1 of the present invention.

FIG. 2 shows (a-1), (a-2), (b-1), (b-
2) is a view for explaining the screen characteristics of the display screen used in the display device of the present invention.

FIG. 3 is a view showing an embodiment of a display device according to claim 2 of the present invention, wherein a projected image and an observation point of a display device in which a Fresnel lens is installed as a convex lens between a projection device and a display screen; Diagram explaining the relationship

FIGS. 4A and 4B show a case where the distance between the projection device and the convex lens is substantially equal to the focal length of the convex lens in the embodiment of the display device according to claim 2 of the present invention. A diagram for explaining that the size and position of an observation area in which an image projected from each projection device can be observed change when the distance is longer than the focal length.

FIG. 5 (a-1), (a-2), (a-3), (b-
1), (b-2), and (b-3) are views showing one reference example of a method of manufacturing a display screen used in the present invention , in which a resin composition sheet formed into a film as an optical screen is light-cured. For explaining the state of incidence of radial rays when manufacturing a light control plate

FIGS. 6A and 6B are explanatory diagrams when a light control plate manufactured by photocuring a resin composition sheet is used for a display screen, and is a projection image projected on a display screen from a projection device. Showing the relationship between the scattering angle 2δ of the image and the tilt angle α for observing the display image on the display screen from the observation point

FIG. 7 is a diagram showing a conventional remote communication conference (video conference) between a plurality of interlocutors based on an image between two points X and Y.

[Explanation of symbols]

Y1, Y2 ... display screen _{Xa C, Xa R, Xb C} , Xb L ... imaging apparatus _{P XaC, P XaR, P XbC} , P XbL ... projection apparatus XA, XB, XC, XD, YA, YB, YC, YD ... Interactor 10 Fresnel lens 11 Diffusion plate 12, 13, 14 Projection device 15, 16, 17 Observation point 100 Display screen 101 Projection device 102 Measurement point 103 Transmission light distribution curve 115, 116, 117 Observation area 200: Irradiated light 201: Optical center axis 202: Film-shaped resin composition sheet 203: Fresnel lens 204: Light control plate

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-4-355442 (JP, A) JP-A-50-5040 (JP, A) JP-A-5-107504 (JP, A) JP-A-4- 298710 (JP, A) JP-A-4-159529 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G03B 21/56 H04N 5/74 H04N 7/15

Claims (2)

(57) [Claims] 1. Same as each of a plurality of arbitrary projection angles
The luminance of the transmitted light image shows a peak value at the emission angle in the direction.
Brightness at angles outside the scattering angle that is half the peak value suddenly increases
A display screen having a characteristic of decreasing two-dimensionally and a scattering direction of the display screen being two-dimensionally different from a back surface of the screen.
Serial and a plurality of projection devices for projecting and displaying an image in projection angle, a plurality of arbitrary projection angle of the screen, then the projection device before Kifuku number same the display on the screen
The image projected and displayed at a specific projection angle is the projection angle
From a specific emission angle corresponding to
A display device characterized by an angle that can be perceived . 2. The display device according to claim 1, wherein a convex lens is provided between the display screen and the projection device.