Source: https://patents.google.com/patent/JP5465523B2/en
Timestamp: 2020-08-10 23:31:23
Document Index: 495981730

Matched Legal Cases: ['art 2', 'art, 12', 'art, 13', 'art, 14', 'art, 15', 'art, 16']

JP5465523B2 - Stereoscopic image display system - Google Patents
JP5465523B2
JP5465523B2 JP2009293192A JP2009293192A JP5465523B2 JP 5465523 B2 JP5465523 B2 JP 5465523B2 JP 2009293192 A JP2009293192 A JP 2009293192A JP 2009293192 A JP2009293192 A JP 2009293192A JP 5465523 B2 JP5465523 B2 JP 5465523B2
JP2009293192A
JP2011050029A (en
梓 竹内
2009-01-29 Priority to JP2009018098 priority Critical
2009-01-29 Priority to JP2009018098 priority
2009-07-28 Priority to JP2009175415 priority
2009-12-24 Priority to JP2009293192A priority patent/JP5465523B2/en
2011-03-10 Publication of JP2011050029A publication Critical patent/JP2011050029A/en
2014-04-09 Publication of JP5465523B2 publication Critical patent/JP5465523B2/en
239000011521 glass Substances 0.000 claims description 145
The present invention relates to a stereoscopic image display system and a projection display apparatus that allow a viewer to recognize a stereoscopic image by displaying a parallax image.
Since the human eyes are several centimeters apart, the images obtained with the right and left eyes are misaligned. The human brain recognizes the depth using this position shift as a clue. In other words, by adjusting the positional deviation amount of the image to be copied to both eyes, the brain can be made to recognize the pseudo depth. Various methods for causing the brain to recognize a planar image as a stereoscopic image using this binocular parallax have been put into practical use (for example, see Patent Document 1). Broadly classified, there are a glasses method and a naked eye method, a glasses method includes a shutter glasses method, a polarized glasses method, and an anaglyph glasses method, and a naked eye method includes a parallax barrier method and a lenticular lens method.
JP-A-10-56654
In general, in a method of displaying two types of images having a predetermined parallax by dividing them temporally or spatially, the observation position that can be recognized as a stereoscopic image is limited. That is, when viewed from a direction where binocular parallax does not occur, the stereoscopic image is not recognized. For example, when displayed on the floor and two types of images are displayed so that parallax occurs when viewed from the direction of a certain side of the display surface, it is recognized as a stereoscopic image from that direction. When viewed from the direction of another side, it is not recognized as a stereoscopic image.
The present invention has been made in view of such circumstances, and an object thereof is to provide a technique capable of recognizing a stereoscopic image from a plurality of observation directions.
A stereoscopic image display system according to an aspect of the present invention is an image display that displays a first image and a first image and a second image having a predetermined parallax in a predetermined display area by being temporally or spatially divided. A first eyeglass to be worn by the first observer who sees the first image and the second image displayed in the display area, and a second who sees the first image and the second image displayed in the display area A first observer and second glasses to be worn by a second observer facing in a direction parallel to the display surface. The first glasses have an action of showing the first image to the right eye of the first observer and showing the second image to the left eye. The second glasses have an action of showing the second image to the right eye of the second observer and showing the first image to the left eye.
Another aspect of the present invention is also a stereoscopic image display system. In this stereoscopic image display system, an image display unit that displays three or more images each having a predetermined parallax in time or space in a predetermined display area and a display area are displayed on the display area. Eyeglasses to be worn by an observer who views the image. The glasses have an effect of showing two images of three or more images specified according to the position of the viewer wearing the glasses to the viewer.
Yet another embodiment of the present invention is a projection display apparatus. The apparatus includes a projection unit that projects a plurality of images having a predetermined parallax between them on a predetermined display area in terms of time or space, and a first image and a second image displayed on the display area. A first eyeglass to be worn by the first observer who sees the image, and a second observer who sees the first image and the second image displayed in the display area, the first observer and the display surface A synchronization signal transmitting unit configured to transmit a predetermined synchronization signal to the second glasses to be worn by the second observer facing the parallel direction;
According to the present invention, a stereoscopic image can be recognized from a plurality of observation directions.
It is a figure which shows the structure of the image display system which concerns on Embodiment 1 of this invention. It is a figure which shows the 1st image and 2nd image of an object. It is a figure which shows the shutter glasses of the structure which can reverse the direction of an arm. FIG. 3A shows the glasses that the first observer should wear, and FIG. 3B shows the glasses that the second observer should wear. It is a figure which shows two glasses which each receive two types of synchronizing signals by radio | wireless. It is a figure which shows the vertical and horizontal linear polarized glasses. FIG. 5A shows glasses to be worn by the first observer, and FIG. 5B shows glasses to be worn by the second observer. It is a figure which shows diagonal linearly polarized glasses. 1 is a diagram showing an internal structure of a projection display apparatus according to Embodiment 1. FIG. FIG. 7A is an internal perspective view of the projection display apparatus viewed from the side. FIG. 7B is an internal perspective view of the projection display apparatus as viewed from above, and mainly shows an arrangement configuration of each optical component in the optical engine. 2 is a functional block diagram of the projection display apparatus according to Embodiment 1. FIG. It is a figure which shows the relationship between the image of the object displayed on a display area, and the image of the object which a 1st observer and a 2nd observer experience. FIG. 9A is a view of the space extending from the display surface of the display area as viewed from the side. FIG. 9B is a first view of the display area as viewed from above. FIG. 9C is a diagram (No. 2) of the display area as viewed from above. It is the figure which looked at the 1st image, 2nd image, and 3rd image of the object which should be displayed on a display area from the upper part of a display area. FIG. 11 is a diagram summarizing display timings of the first image, the second image, and the third image, and opening / closing timings of shutter glasses to be worn by the first to sixth observers, based on the example shown in FIG. 10. is there. It is the figure which looked at the 1st image, 2nd image, 3rd image, and 4th image of the object which should be displayed on a display area from the upper part of a display area. It is the figure which looked at the 1st image, 2nd image, 3rd image, and 4th image of the object which should be displayed on a display area from the upper part of a display area. It is a flowchart explaining the setting process of the opening / closing timing of shutter glasses. It is a figure explaining an example of how the image for direction confirmation looks. It is a modification of the process shown in FIG. It is a figure which shows the gravity center of parallax image DI1-DI4. It is a figure explaining the method of determining an observation direction when a wall surface is made into the display area. It is a flowchart explaining the determination process of the observation direction at the time of arrange | positioning a reference | standard object. It is a figure which shows the modification which has arrange | positioned reflectors 44, such as a mirror, instead of the reference | standard object. It is a flowchart explaining the determination process of the observation direction at the time of arrange | positioning a reflector. It is a figure which shows the structure of the image display system which concerns on the reference example of this invention. It is a figure of the 1st field image of the object which should be displayed on a display field, the 2nd field image, the 3rd field image, and the 4th field image.
FIG. 1 is a diagram showing a configuration of an image display system 50 according to Embodiment 1 of the present invention. The image display system 50 includes a projection display apparatus 10, a camera 20, first glasses 30a, and second glasses 30b.
The projection display apparatus 10 as an image display unit displays a first image and a first image and a second image having a predetermined parallax in a predetermined display area 40 by dividing them temporally or spatially. . The projection display apparatus 10 is a floor-mountable projector equipped with a short focus lens. The display area 40 may be a screen installed on the floor, or may be a display using the floor itself.
The first observer V1 and the second observer V2 stand in the display surface or outside the display surface and look down at the image displayed in the display area 40. The display area 40 is not limited to being formed on the floor surface, and may be formed on the ceiling surface, for example. In that case, the first observer V1 and the second observer V2 look to look up at the image displayed in the display area 40.
The image display unit is not limited to the example configured by the projection display apparatus 10 that projects an image on the display area 40, and may be configured by a liquid crystal display, a plasma display, or the like. In other words, any configuration may be used as long as the first image and the second image can be displayed on a predetermined display surface by being temporally or spatially divided.
When the shutter glasses method is employed, the projection display apparatus 10 displays the first image and the second image in a time division manner. In the example of FIG. 1, a right eye image and a left eye image are alternately displayed. When the polarized glasses method is employed, the projection display apparatus 10 displays the first image and the second image by dividing the space. In the example of FIG. 1, an image in which the pixels for the right eye image and the pixels for the left eye image are mixed is displayed.
When the polarized glasses method is adopted, the left eye image and the right eye image may be projected with different polarizations using two projection display devices, or one projection display image may be displayed. Using the device, the left-eye image and the right-eye image are displayed alternately, and a switcher that switches the polarization is arranged in front of the projection lens, and the left-eye image and the right-eye image are projected with different polarizations. Also good.
The camera 20 (for example, a CCD camera) captures an image including at least a display area 40 and a space extending vertically from the display surface, and supplies the image to the projection display apparatus 10. It is preferable that the composition of the image includes the entire movement range of the first observer V1 and the second observer V2.
The first glasses 30a are worn by the first observer V1 who sees the first image and the second image displayed in the display area 40. The second glasses 30b are the second observer V2 who sees the first image and the second image displayed in the display area 40, and are the second observer facing the first observer V1 in a direction parallel to the display surface. It is attached to the observer V2.
When the first image and the second image are displayed on the display surface formed on the floor, the first glasses 30a are worn by the first observer V1 in the first position inside or outside the display surface. . The second glasses 30b are attached to the second observer V2 positioned in a direction facing the first position with the position of the object OBJ (soccer ball in FIG. 1) displayed on the display surface interposed therebetween. For example, the first observer V1 and the second observer V2 may observe the first image and the second image from the opposite sides of the display area 40, respectively.
The first glasses 30a have a function of showing the first image to the right eye of the first observer V1 and showing the second image to the left eye. The second glasses 30b have a function of showing the second image to the right eye of the second observer V2 and showing the first image to the left eye. That is, the first glasses 30a and the second glasses 30b are reversed. When the shutter glasses method is employed, the first glasses 30a and the second glasses 30b are controlled so that the opening and closing of the right eye shutter and the left eye shutter are reversed.
[Example of object display]
FIG. 2 is a diagram illustrating the first image I1 and the second image I2 of the object OBJ. When facing and observing the object OBJ in the real world, the positional relationship between the left and right eyes of the first observer V1 and the second observer V2 is reversed. That is, the surface of the object OBJ that can be seen from the right eye of the first viewer V1 is the surface of the object OBJ that can be seen from the left eye of the second viewer V2.
In FIG. 2, the first observer V1 on the left side of the first image I1 and the second image I2 of the object OBJ sees the first image I1 with the right eye and the second image I2 with the left eye. The second observer V2 on the right side of the first image I1 and the second image I2 of the object OBJ will see the first image I1 with the left eye and the second image I2 with the right eye. Thus, when observing so that the line of sight of both eyes intersects in the middle, the object OBJ appears to pop out.
Here, in the case where the shutter glasses method is adopted, and the opening / closing operation of the shutter glasses worn by the first observer V1 and the second observer V2 is the same, the right eye image of the first observer V1 is the first. The image for the left eye of the first observer V1 is observed on the left eye of the second observer V2 on the right eye of the second observer V2. Therefore, either observer cannot correctly view stereoscopically. Therefore, control is performed so that the opening / closing operation of the shutter glasses worn by the first observer V1 and the second observer V2 is reversed. As a result, both the first observer V1 and the second observer V2 can observe a stereoscopic image.
In order to reverse the opening / closing operation of the shutter glasses worn by the first observer V1 and the second observer V2, assuming that one type of synchronization signal is used, two types of shutter glasses may be prepared, but the same A switch for reversing the opening / closing operation of the shutter glasses of a kind may be added.
Further, shutter glasses having a structure in which the direction of the arm can be reversed may be used.
FIG. 3 is a view showing shutter glasses having a structure in which the direction of the arm 31 can be reversed. FIG. 3A shows the glasses 30a to be worn by the first observer V1, and FIG. 3B shows the glasses 30b to be worn by the second observer V2.
Further, directivity may be given in the direction of the observer by two types of synchronization signals transmitted from the projection display apparatus 10 and having a different half cycle.
FIG. 4 shows two glasses that wirelessly receive each of the two types of synchronization signals. The glasses 30a to be worn by the first observer V1 and the glasses 30b to be worn by the second observer V2 are controlled in reverse.
When the polarized glasses method is adopted, two types of glasses having opposite right and left polarizations are prepared, and the first observer V1 and the second observer V2 wear these glasses.
FIG. 5 is a diagram showing vertical and horizontal linearly polarized glasses. FIG. 5A shows the glasses 30a to be worn by the first observer V1, and FIG. 5B shows the glasses 30b to be worn by the second observer V2.
Also, when adopting an anaglyph glasses system that separates images according to the wavelength band of light, the left and right filters may be reversed. Any method can be realized as long as it is a method of wearing glasses for separating images.
With vertical and horizontal linearly polarized glasses, circularly polarized glasses, and anaglyph glasses, if the structure of the direction of the arm 31 can be reversed as shown in FIG. 3, the positions of the left and right filters can be reversed. Therefore, the effects of the left and right filters can be reversed.
FIG. 6 is a diagram showing oblique linearly polarized glasses. In the glasses 30, even if the arm 31 is reversed, the functions of the left and right filters are not reversed. Therefore, the shape of the arm 31 is made so that it can be mounted from either the top or the bottom. By wearing the glasses 30 upside down, the functions of the left and right filters can be reversed.
[Configuration of Projection Display Device]
FIG. 7 is a diagram showing the internal structure of the projection display apparatus 10 according to the first embodiment. FIG. 7A is an internal perspective view of the projection display 10 viewed from the side. FIG. 7B is an internal perspective view of the projection display apparatus 10 as viewed from above, and mainly shows an arrangement configuration of each optical component in the optical engine 200.
Referring to FIG. 7, the projection display apparatus 10 includes a cabinet 100. The cabinet 100 has an image light projection port 101 formed on the front surface 100a thereof. The cabinet 100 has a convex curved surface 100d formed from the back surface 100b to the upper surface 100c, and a handle 102 is provided on the convex curved surface 100d. The handle 102 is provided with a handle portion 102a that can rotate in the XZ in-plane direction.
In the cabinet 100, an optical engine 200, a rear refractive optical system 300, a reflection mirror 400, a front refractive optical system 500, and a curved mirror 600 are arranged.
The optical engine 200 is disposed at the bottom of the cabinet 100 and generates video light modulated according to the video signal. In the optical engine 200, each optical component (a liquid crystal panel, a dichroic prism, etc.) is installed in a predetermined arrangement in the casing, and the installation surface of each optical component is substantially parallel to the bottom surface 100e of the cabinet 100. It has become.
As shown in FIG. 7B, the optical engine 200 includes a light source 201, a light guide optical system 202, three transmissive liquid crystal panels 203, 204, and 205, and a dichroic prism 206.
White light emitted from the light source 201 is converted into light in the red wavelength band (hereinafter referred to as “R light”), light in the green wavelength band (hereinafter referred to as “G light”), and blue wavelength by the light guide optical system 202. The light is separated into band light (hereinafter referred to as “B light”) and applied to the liquid crystal panels 203, 204, and 205. The R light, G light, and B light modulated by the liquid crystal panels 203, 204, and 205 are color-combined by the dichroic prism 206 and emitted as video light. Polarizers (not shown) are provided on the incident side and the emission side of the liquid crystal panels 203, 204, and 205.
In addition to the transmissive liquid crystal panels 203, 204, and 205, a reflective liquid crystal panel or a MEMS device can be used as the light modulation element disposed in the optical engine 200. Further, when a liquid crystal panel is used, a single-plate type optical system using a color wheel can be used instead of the three-plate type as described above.
A rear refractive optical system 300 is attached to the image light exit of the optical engine 200. The image light generated by the optical engine 200 is incident on the rear refractive optical system 300. The rear refractive optical system 300 includes a plurality of lenses, and the optical axis L1 of these lenses is parallel to the bottom surface 100e (X axis) of the cabinet 100. As shown in FIG. 7A, the liquid crystal panels 203, 204, 205 and the dichroic prism 206 are arranged shifted from the optical axis L1 of the rear refractive optical system 300 in the Z-axis direction (the curved mirror 600 side). .
A reflection mirror 400 is arranged in front of the rear refractive optical system 300. The reflection mirror 400 is arranged in a state orthogonal to the XZ plane and inclined by 45 degrees with respect to the bottom surface 100e (XY plane) of the cabinet 100.
A front refractive optical system 500 is disposed above the reflection mirror 400. The front refractive optical system 500 includes a plurality of lenses, and the optical axis L2 of these lenses is parallel to the Z axis and parallel to the image light exit surface of the dichroic prism 206. In addition, the optical axis L2 of the front refractive optical system 500 is perpendicular to the optical axis L1 of the rear refractive optical system 300 and the bottom surface 100e of the cabinet 100. Crosses the optical axis L1. That is, the front refractive optical system 500 forms one refractive optical system in cooperation with the rear refractive optical system 300, and is reflected by the reflection mirror 400 interposed between the two refractive optical systems 300 and 500. The optical axis of the lens group is converted from a direction perpendicular to the exit surface of the dichroic prism 206 to a direction parallel thereto.
The image light that has entered the rear refractive optical system 300 passes through the rear refractive optical system 300, the reflection mirror 400, and the front refractive optical system 500, and then enters the curved mirror 600 disposed above the front refractive optical system 500. .
The curved mirror 600 has a concave reflecting surface. As shown in FIG. 7A, the curved mirror 600 has an effective reflection region on the optical engine 200 side with respect to the optical axis L2 of the front refractive optical system 500. The curved mirror 600 can be aspherical, free curved, or spherical.
The image light incident on the curved mirror 600 is reflected by the curved mirror 600 and enlarged and projected on the projection surface through the projection port 101. At this time, the image light is expanded after being converged most in the vicinity of the projection port 101.
[Functions of the projection display device]
FIG. 8 is a functional block diagram of the projection display apparatus 10 according to the first embodiment. The projection display apparatus 10 includes an image signal holding unit 11, an image analysis unit 12, an image processing unit 13, a projection unit 14, a synchronization signal generation unit 15, and a synchronization signal transmission unit 16. These configurations can be realized by an arbitrary processor, memory, or other LSI in terms of hardware, and can be realized by a program loaded in the memory in terms of software, but here by their cooperation. Draw functional blocks. Accordingly, those skilled in the art will understand that these functional blocks can be realized in various forms by hardware only, software only, or a combination thereof.
The image signal holding unit 11 holds an image signal supplied from the outside. The image analysis unit 12 analyzes an image photographed by the camera 20. Here, the movement of the observer in the image is analyzed. For example, the movement of the observer can be analyzed by calculating the difference between the photographed image and the actually projected image.
The image processing unit 13 processes the image signal held in the image signal holding unit 11 according to the analysis result of the image analysis unit 12. For example, in a soccer game application as shown in FIG. 1, a stadium and a soccer ball are displayed in the projected image. Here, when the observer performs an action of kicking the ball on the display screen, the image analysis unit 12 detects an object different from the projected image in the vicinity of the soccer ball in the image taken by the camera 20. The image processing unit 13 receives the detection result and generates an image in which the soccer ball moves in the moving direction of the object. More specifically, an image in which the position of the soccer ball in the current projected image is corrected is generated.
The moving speed of the soccer ball is basically proportional to the moving speed of the object, but the speed setting can be freely changed. For example, the observer enters the age before starting the game. When the first observer V1 is older than the second observer V2, the first observer V1 kicks the speed toward the second observer V2, and the second observer V2 kicks the first observer V1. Slower than heading speed. In this way, even if there is a difference in ability in the real world, it can be enjoyed equally in a virtual game. As for the age, for example, by estimating the actual height of the observer from the observer in the image taken by the camera 20, the taller person may be determined as the older person.
Further, by performing the stereoscopic display, it is possible to add a vertical movement to the soccer ball. Various special effects can be produced, such as a ball that sinks in the ground, a ball that floats while moving, or a ball that floats and moves suddenly.
The projection unit 14 projects light according to the image generated by the image processing unit 13 onto the display area 40. The synchronization signal generation unit 15 generates a signal synchronized with the projection timing of each frame image by the projection unit 14. The synchronization signal transmission unit 16 transmits the synchronization signal generated by the synchronization signal generation unit 15 to the glasses 30 by infrared communication or other short-range wireless communication. Note that the synchronization signal generation unit 15 and the synchronization signal transmission unit 16 are configured to be provided when the shutter glasses method is adopted, and are not necessary when the polarization glasses method is adopted. In addition, when a plurality of types of shutter glasses as shown in FIG. 3 are used, one type of synchronization signal may be transmitted, but when a single type of shutter glasses is used as shown in FIG. A synchronization signal needs to be transmitted.
[Adaptation of objects]
Next, an object OBJ suitable for display will be considered. Usually, an image that is correctly viewed from the first observer V1 is an image of a surface observed from the first observer V1. Therefore, the second observer V2 cannot see the image of the surface to be observed, and is observed with the front and rear and the top and bottom reversed. As described above, there are many cases where an object with clear front and rear and top and bottom cannot be stereoscopically viewed. On the other hand, an object OBJ that is symmetrical vertically and horizontally like a soccer ball does not feel uncomfortable when viewed from the first observer V1 or the second observer V2. For example, rugby balls and jewelry are also suitable for the object OBJ. If it is a regular polyhedron, it is still more preferable. However, it is desirable that the ball should not be shaded to express the vertical relationship.
FIG. 9 is a diagram illustrating the relationship between the images DI1 and DI2 of the object OBJ displayed in the display area 40 and the images OI1 and OI2 of the object OBJ that the first observer V1 and the second observer V2 experience. FIG. 9A is a view of a space extending from the display surface of the display area 40 as viewed from the side. In the display area 40, images DI1 and DI2 of two types of objects OBJ having a predetermined parallax are alternately displayed.
Since the first observer V1 and the second observer V2 do not see the images DI1 and DI2 of the object OBJ from directly above the display area 40, the positions of the stereoscopic images to be experienced are closer to themselves. That is, from the viewpoint V1 of the first observer V1, the image OI1 of the object OBJ is sensed at a position closer to the self (first observer V1) position than the positions of the displayed images DI1 and DI2. Similarly, from the viewpoint V2 of the second observer V2, the image OI2 of the object OBJ is experienced at a position closer to the position of the self (second observer V2) than the positions of the displayed images DI1 and DI2. From this viewpoint, it can be said that it is desirable not to display the shadow of the object OBJ on the ground (the surface of the display area 40) or the like. This is because the position of the object OBJ that each of the plurality of observers experiences is different.
FIG. 9B is a first view of the display area 40 as viewed from above. Since the first observer V1 and the second observer V2 do not see the images DI1 and DI2 of the object OBJ from directly above the display area 40, the first observer V1 and the second observer V2 are contracted back and forth from the images DI1 and DI2 of the object OBJ. The Therefore, the images DI1 and DI2 of the object OBJ are extended in the direction of the opposing line between the first observer V1 and the second observer V2 and displayed on the display area 40. Thereby, the image OI1 of the object OBJ experienced from the right eye viewpoint RV1 and the left eye viewpoint LV1 of the first observer V1 becomes a circle. Similarly, the image OI2 of the object OBJ experienced from the right eye viewpoint RV2 and the left eye viewpoint LV2 of the second observer V2 becomes a circle.
FIG. 9C is a diagram (part 2) of the display area 40 viewed from above. In this example, the images DI1 and DI2 of the object OBJ displayed in the display area 40 are circles. In this case, the first observer V1 and the second observer V2 experience the object OBJ contracted in the facing line direction. Of course, if this distortion is small enough to be acceptable, the images DI1 and DI2 of the circular object OBJ may be displayed. In FIG. 2, for the sake of easy understanding, the first image I1 and the second image I2 are displayed so as not to overlap. However, in actuality, depending on the pop-out amount to be given to the object OBJ. 9B and 9C, the images DI1 and DI2 of the object OBJ may be displayed overlapping each other.
As described above, according to the first embodiment, an observer facing in a direction parallel to the display surface wears glasses that act in the opposite direction, so that a stereoscopic image can be obtained from the directions of both observers. Can be recognized.
Next, an image display system 50 according to Embodiment 2 of the present invention will be described. In the second embodiment, it is assumed that there are three or more observers.
FIG. 10 is a view of the first image DI1, the second image DI2, and the third image DI3 of the object OBJ to be displayed in the display area 40 as viewed from above the display area 40. The first image DI1, the second image DI2, and the third image DI3 of the object OBJ each have a predetermined parallax and are displayed in a time division manner. Here, six observers observe these images. The first observer V1 and the second observer V2 see a pair of the first image DI1 and the second image DI2. The third observer V3 and the fourth observer V4 see a pair of the first image DI1 and the third image DI3. The fifth observer V5 and the sixth observer V6 see a pair of the second image DI2 and the third image DI3.
FIG. 11 shows the display timings of the first image DI1, the second image DI2, and the third image DI3 and the shutters to be worn by the first observer V1 to the sixth observer V6 based on the example shown in FIG. It is the figure which put together the opening and closing timing of glasses. Assuming that each of the first image DI1, the second image DI2, and the third image DI3 is displayed at 60 Hz, one unit of the frame image is displayed at 180 Hz.
In the first phase of the unit, the first image DI1 is controlled to be displayed, and the second image DI2 and the third image DI3 are controlled to be non-displayed. The shutter of the right eye of the first observer V1, the shutter of the left eye of the second observer V2, the shutter of the left eye of the third observer V3, and the shutter of the right eye of the fourth observer V4 are opened. The shutter is controlled to close.
In the second phase, the second image DI2 is controlled to be displayed, and the first image DI1 and the third image DI3 are controlled to be non-displayed. The shutter of the left eye of the first viewer V1, the shutter of the right eye of the second viewer V2, the shutter of the left eye of the fifth viewer V5, and the shutter of the right eye of the sixth viewer V6 are opened. The shutter is controlled to close.
In the third phase, the third image DI3 is controlled to be displayed, and the first image DI1 and the second image DI2 are controlled to be non-displayed. The shutter of the right eye of the third observer V3, the shutter of the left eye of the fourth observer V4, the shutter of the right eye of the fifth observer V5, and the shutter of the left eye of the sixth observer V6 are opened. The shutter is controlled to close.
FIG. 12 is a view of the first image DI1, the second image DI2, the third image DI3, and the fourth image DI4 of the object OBJ to be displayed in the display area 40 as viewed from above the display area 40. The first image DI1, the second image DI2, the third image DI3, and the fourth image DI4 of the object OBJ each have a predetermined parallax and are displayed in a time division manner. Here, eight observers observe these images.
The first observer V1 looks at the pair of the third image DI3 and the fourth image DI4. The second observer V2 looks at the pair of the first image DI1 and the second image DI2. The third observer V3 looks at the pair of the second image DI2 and the fourth image DI4. The fourth observer V4 looks at the pair of the first image DI1 and the third image DI3. The fifth observer V5 and the sixth observer V6 see a pair of the second image DI2 and the third image DI3. The seventh observer V7 and the eighth observer V8 see the pair of the first image DI1 and the fourth image DI4.
Note that the first observer V1 may see the pair of the first image DI1 and the second image DI2, but as described with reference to FIG. 9, the position of the bodily sensation image is closer to its own position than the display position. It is preferable to look at a pair of images that are farther away from the self. The same applies to the second observer V2 to the fourth observer V4.
Note that by further increasing the number of images DI of the object OBJ displayed in one unit, a stereoscopic image can be observed from more than one direction.
As described above, according to Embodiment 2, a stereoscopic image is recognized from three or more directions by dividing and displaying three or more images each having a parallax in time or space. Can do.
[Judgment method 1 of observation direction]
In the above, when there are three or more observers, the display timing of the images DI1 to DI4 in the object OBJ and the opening / closing timing of the shutter glasses worn by the observer are appropriately adjusted to observe three or more observers. Stated that a person can recognize a stereoscopic image from multiple directions. At this time, a pair of images to be viewed by each observer with the left eye and the right eye is determined in advance.
However, as the number of observers increases, it becomes difficult to understand which image pair in the object should be set so that each person sees the opening / closing timing of the shutter glasses. Furthermore, when the observer moves and changes the direction of viewing the object, there is a problem that the stereoscopic image cannot be recognized at the opening / closing timing of the shutter glasses set in accordance with the original viewing direction.
Therefore, hereinafter, an image display system that automatically sets the opening / closing timing of the shutter glasses when the projection display apparatus projects a display area on the floor will be described.
FIG. 13 is a view of the first image DI1, the second image DI2, the third image DI3, and the fourth image DI4 of the object OBJ to be displayed in the display area 40 as viewed from above the display area 40 in the image display system. It is. The first image DI1, the second image DI2, the third image DI3, and the fourth image DI4 of the object OBJ each have a predetermined parallax and are displayed in a time division manner.
The image display system includes the projection display apparatus 10 shown in FIG. 7 and shutter glasses that can open and close the shutter with the left eye and the right eye, respectively. The object OBJ is projected by the projection display apparatus 10 onto the floor surface where the observer is present. The object OBJ is observed from eight directions V1 to V8 shown in the drawing. FIG. 13 shows a direction confirmation image K in addition to the object OBJ, which will be described later.
The shutter glasses worn by each observer include a small camera such as a CCD (Charge Coupled Device) camera, a control unit including hardware such as a CPU, ROM, and RAM, a program cooperating therewith, and the like. A receiving unit that receives a synchronization signal from the type video display device 10.
FIG. 14 is a flowchart illustrating a process for setting shutter glasses opening / closing timing.
First, in a situation where an observer is present around the object display area 40, the projection display apparatus projects a direction confirmation image K in addition to the object OBJ (S10). This direction confirmation image K can have an arbitrary shape that is different from each other when viewed from the eight observation directions V1 to V8. In FIG. 13, an arrow shape is shown as the direction confirmation image K. The direction confirmation image K is displayed at the same timing as the display timing of the parallax images DI1 to DI3.
The small camera attached to the shutter glasses worn by each observer captures an area including the direction confirmation image (S12). The control unit of the camera detects the direction confirmation image K from the photographed area using a technique such as pattern matching that determines which of the patterns in the direction recorded in advance matches most (S14). ) Based on the direction of the direction confirmation image, the direction of the observer who is looking at the display area is determined from V1 to V8 (S16).
FIG. 15 is a diagram illustrating an example of how the direction confirmation image looks. (A) shows the appearance of the direction confirmation image K when the object OBJ is observed from the direction of V8, and (b) shows the appearance of the direction confirmation image K when the object OBJ is observed from the direction of V3. Indicates. Thus, by detecting the direction confirmation image, it is possible to determine from which direction of the V1 to V8 each observer is observing the object OBJ.
Returning to FIG. 14, the control unit of each shutter glasses selects an image to be observed with the right eye and the left eye of the glasses from the first image DI1 to the fourth image DI4 according to the determined observation direction ( S18). That is, the selection is made so that the viewers in each observation direction can see the pair of images arranged in the most horizontal direction. At this time, if there are a plurality of pair candidates, the one farther than the observer is selected. Specifically, when the observation direction is V8, the image to be viewed with the right eye is the first image DI1, and the image to be viewed with the left eye is the fourth image DI4. When the observation direction is V3, the image to be viewed with the right eye is the fourth image DI4, and the image to be viewed with the left eye is the second image DI2.
The control unit of the shutter glasses sets the opening / closing timing of the left eye shutter and the right eye shutter so that the image selected in S16 is observed by the left and right eyes (S20). As shown in FIG. 11, this setting is set for each shutter glasses together with the display timing of the first image DI1 to the fourth image DI4 in each phase. That is, the opening / closing timing is set so that the right eye shutter of the glasses is opened when an image to be viewed with the right eye is displayed in a certain phase, and the right eye shutter is closed when other images are displayed. . Similarly, for the left-eye shutter, the opening and closing timing is set so that the left-eye shutter is opened when an image to be viewed with the left eye is displayed, and the left-eye shutter is closed when other images are displayed. To do.
By controlling as described above, for each shutter glasses worn by each viewer around the display area 40, an image to be viewed is determined so that each viewer can recognize a stereoscopic image, and the shutter is accordingly adjusted. The opening / closing timing of the glasses can be set. Therefore, it is not necessary to prepare shutter glasses whose opening / closing timing is set according to the orientation of the viewer with respect to the display area 40. Furthermore, even if the observer moves around the display area 40 and changes its orientation, the 3D image can be recognized according to the direction as long as the display sequence of the direction confirmation image exists.
Note that the display time of the direction confirmation image is preferably close to the shortest time that can be captured by a small camera of shutter glasses. Accordingly, there is no possibility that each observer will pay attention to an image other than the object OBJ, and the display sequence of the direction confirmation image may be executed at any time during the display of the object.
Alternatively, it may be configured so that the observer cannot see the direction confirmation image by closing the shutters of both eyes of the shutter glasses while the direction confirmation image is displayed. In this case, the projection type video apparatus sends a signal to the transmission / reception unit of each shutter glasses immediately before or during the display of the direction confirmation image, and the shutter glasses control device performs a predetermined operation from the time the signal is received. During this period or during reception of the signal, the shutter is operated to close. By doing so, the observer is not confused by the direction confirmation image, and the stereoscopic image can be recognized as soon as the shutter is opened.
Since the orientation of the observer with respect to the object is important for correctly recognizing a stereoscopic image, the display position of the direction confirmation image is preferably in the vicinity of the object as shown in FIG. Displaying the direction confirmation image in the center of the object in this manner is more preferable because there is almost no deviation between the orientation of the observer with respect to the object and the orientation of the direction confirmation image.
FIG. 16 is a modification of the process shown in FIG.
First, in a situation where the observer is present around the object display area 40, the projection display apparatus displays the object OBJ in the display area 40, and the small camera attached to the shutter glasses worn by the observer is the object. A region including is photographed (S30). The control unit of the camera detects the parallax images DI1 to DI4 by pattern matching with the parallax images in the object recorded in advance (S32). Subsequently, the control unit calculates the center of gravity of the parallax images DI1 to DI4 (S34). FIG. 17 shows the centers of gravity of the parallax images DI1 to DI4 with black circles. Instead of the center of gravity, the center point of the width and height of each image may be simply calculated. As a result, four centroids are obtained.
The control unit selects the two most horizontally arranged points out of the four centroids, and selects an image including the centroids of the two points as an image to be seen by the left and right eyes of each observer (S36). At this time, when there are a plurality of pairs of two points arranged horizontally, it is preferable to select a pair located farther than the observer. For example, when the observer is in the direction of V4, there are a pair of DI1 and DI3 and a pair of DI2 and DI4 as a pair of horizontal centers of gravity, but the former is selected as being located farther away. The control unit of the shutter glasses sets the opening / closing timing of the left eye shutter and the right eye shutter so that the image selected in S16 can be observed by the left and right eyes (S38).
As described above, in this modified example, instead of displaying the direction confirmation image together with the object, the observer's direction can be determined using the graphical characteristics of the object itself. Therefore, there is no need to provide a display sequence for the direction confirmation image, and it is possible to execute direction determination at any time on the shutter glasses side while the object is displayed in the display area 40. Further, the observer is not aware of the direction confirmation image.
13 to 17, the case where the object OBJ includes four parallax images has been described. However, the present invention can be similarly applied to the case where the number of parallax images is three and five or more.
[Observation direction determination method 2]
So far, the method for determining the observation direction when the display area is set on the floor has been described. On the other hand, when the display area is set on the wall surface, which of the plurality of parallax images of the object displayed on the wall surface should be observed for each observer to recognize the stereoscopic image is the observation on the wall surface. It depends on the direction of the person. Therefore, a method different from the case of the floor surface is required.
FIG. 18 is a diagram for explaining a method of determining the observation direction when the wall surface is the display area 40. The projection display apparatus projects an object onto the display area 40 on the wall surface. At this time, a reference object having a different color, shape, or pattern is arranged around the display area 40, for example, at the top, according to the direction of the observer with respect to the object displayed on the wall surface. In the example of FIG. 18, a cylindrical reference object 42 is arranged on the upper portion of the display area 40, and five vertical lines 42 a are drawn on the outer surface. The vertical line 42a is a line of different colors, for example, yellow, green, red, blue, and orange from left to right. By appropriately setting the degree of curvature of the reference object 42 and the arrangement of the vertical lines, the appearance of the reference object 42 differs depending on the observation direction, so that the observation direction can be determined.
The reference object 42 may not be cylindrical as long as it has an outward or inward curved surface. Further, as long as the appearance differs depending on the observation direction, wirings having different shapes and patterns may be arranged instead of the vertical lines having different colors.
FIG. 19 is a flowchart illustrating a process for determining an observation direction when a reference object is arranged.
First, in a situation where the observer is present around the object display area 40, the projection display apparatus displays the object OBJ on the display area 40 on the wall surface, and is a small size attached to the shutter glasses worn by the observer. The camera captures an area including the reference object 42 (S50). The control unit of the camera detects the reference object 42 from within the region by matching with a pattern such as a color and pattern of the reference object surface recorded in advance, and determines the observation direction of the observer based on the arrangement of the color and pattern (S52).
Based on the observation direction determined in S52, the control unit of the shutter glasses selects an image to be viewed with the left eye and the right eye of the observer from the plurality of parallax images included in the object (S54). Then, the control unit of the shutter glasses sets the opening / closing timings of the left-eye shutter and the right-eye shutter in accordance with the object display timing so that the selected image is observed by the left and right eyes (S56).
FIG. 20 shows a modification in which a reflector 44 such as a mirror is arranged instead of the reference object 42. The reflector 44 is installed in the vicinity of the display area 40, preferably in the upper part, in a state inclined by a predetermined angle with respect to the direction of the observer. This angle is preferably determined according to the distance between the wall surface projecting the display area and the observer.
With the reflector 44 disposed, the projection display apparatus projects a direction confirmation image on the display area 40 before displaying the object. The direction confirmation image 44a is five vertical lines as in the example of FIG. 18, and is arranged from left to right, for example, in the order of yellow, green, red, blue, and orange. Note that the number of vertical lines to be displayed as the confirmation image is preferably determined according to the angular spread of the observer with respect to the object projected on the display area. By appropriately setting the installation angle of the reflector and the arrangement of the vertical lines, the viewing direction of the direction confirmation image 44a reflected on the reflector 44 is different depending on the observation direction, so that the observation direction can be determined.
As in the example of FIG. 19, as long as the appearance differs depending on the observation direction, an arbitrary figure having a different color, shape, pattern, or the like may be projected as the direction confirmation image 44a instead of the vertical line having a different color. it can. Further, the reflector 44 may be a curved mirror other than the plane as long as the direction confirmation image can be reflected toward the observer.
FIG. 21 is a flowchart for explaining a process for determining an observation direction when a reflector is arranged.
First, in a situation where the observer is present around the object display area 40, the projection display apparatus executes a sequence for projecting the direction confirmation image onto the wall display area 40 before displaying the object OBJ. (S60). The small camera attached to the shutter glasses worn by the observer captures an area including the direction confirmation image (S62). The control unit of the camera detects the reflector 44 from within the area by matching with a pattern such as a color or pattern of the reference object surface recorded in advance (S64), and the color in the image reflected on the reflector 44 Based on the pattern, the observation direction of the observer is determined (S66). For example, in the example of FIG. 20, in shutter glasses worn by an observer located on the right side in the drawing, a yellow line that is projected to the left end of the display area 40 and reflected by the reflector 44 is photographed (in the drawing). The direction of the observer can be determined.
The control unit of the shutter glasses selects an image to be viewed with the left eye and the right eye of the observer from the plurality of parallax images included in the object based on the observation direction determined in S66 (S68). Then, the control unit of the shutter glasses sets the open / close timing of the left eye shutter and the right eye shutter in accordance with the display timing of the object so that the selected image is observed by the left and right eyes (S70).
Similar to the example of FIG. 13, the display time of the direction confirmation image is preferably close to the shortest time that can be captured by a small camera of shutter glasses. Further, during the display of the direction confirmation image, it may be configured so that the observer cannot see the direction confirmation image by closing the shutters of both eyes of the shutter glasses. In this case, the projection type video apparatus sends a signal to the transmission / reception unit of each shutter glasses immediately before or during the display of the direction confirmation image, and the shutter glasses control device performs a predetermined operation from the time the signal is received. During this period or during reception of the signal, the shutter is operated to close. By doing so, the observer is not confused by the direction confirmation image, and the stereoscopic image can be recognized as soon as the shutter is opened.
Next, an image display system 50 according to a reference example will be described. In this reference example, the display timing of a plurality of area images and the opening / closing timing of shutter glasses to be worn by the observer are controlled. As a result, it is possible to provide a stereoscopic image that does not cause a sense of incongruity even if the object OBJ is not symmetrical vertically and horizontally.
FIG. 22 is a diagram illustrating a configuration of an image display system 50 according to the reference example. The image display system 50 includes a projection display apparatus 10, a camera 20, a microscope 21, first glasses 30a, second glasses 30b, third glasses 30c, and fourth glasses 30d.
The projection display apparatus 10 as an image display unit displays, in a predetermined display area 40, an image (RI1) of the first area R1, an image (RI2) of the second area R2, and an image (RI2) of the third area R3. RI3) and the image (RI4) of the fourth region R4 are respectively displayed. The first area image RI1, the second area image RI2, the third area image RI3, and the fourth area image RI4 of the object OBJ to be displayed in the display area 40 each have a predetermined parallax and are displayed in a time-sharing manner. The
The camera 20 (for example, a CCD camera) captures an image of 360 ° around the projection display apparatus 10 and supplies it to the projection display apparatus 10. From the image from the camera 20, the projection-type image display apparatus 10 includes the first glasses 30 a, the second glasses 30 b, the third glasses 30 c, and the fourth glasses 30 d, respectively, in the areas R 1, R 2, R 3, It is determined which region of R4 corresponds to which region.
The microscope 21 captures the object placed on the preparation as a plurality of images with parallax and supplies the images to the projection display apparatus 10. The image captured by the microscope 21 may be supplied to the projection display apparatus 10 via a personal computer (not shown).
The first glasses 30a are worn by the first observer V1 who views the first region image RI1 displayed in the first region of the display region 40. Similarly, the second glasses 30b, the third glasses 30c, and the fourth glasses 30d are the second region image RI2, the third region image RI3, and the third region image RI3 displayed in the second region, the third region, and the fourth region of the display region 40, respectively. The second viewer V2, the third viewer V3, and the fourth viewer V4 who view the fourth region image RI4 are mounted.
FIG. 23 is a diagram of the first region image RI1, the second region image RI2, the third region image RI3, and the fourth region image RI4 of the object OBJ to be displayed in the display region 40.
The first observer V1 looks at the right eye image RI1R and the left eye image RI1L of the first region image RI1. The second observer V2 views the right eye image RI2R and the left eye image RI2L of the second region image RI2. The third observer V3 views the right eye image RI3R and the left eye image RI3L of the third region image RI3. The fourth observer V4 views the right eye image RI4R and the left eye image RI4L of the fourth region image RI4.
In other words, the first glasses 30a have a shutter so that the right eye of the first region image RI1R is displayed on the right eye of the first observer V1 and the left eye image RI1L of the first region image RI1 is displayed on the left eye. Is controlled to open and close. Similarly, the opening / closing of the shutter is controlled so that the second glasses 30b, the third glasses 30c, and the fourth glasses 30d also show the right eye image and the left eye image to the right eye and the left eye of each observer. The
Assuming that the right eye image and the left eye image of each region image are displayed at 60 Hz, one unit of the frame image is displayed at 120 Hz.
In this reference example, the microscope 21 is used for explanation. However, as a means for capturing an image for creating a stereoscopic image, a normal camera (however, a device capable of capturing a plurality of images having parallax) may be used. Moreover, the structure which takes in an image from the database of the existing stereo image may be sufficient.
In this reference example, the display area 40 has been described on the assumption that it is projected on a normal screen or floor, but an interactive board such as a touch panel may be used as the screen. In this case, the part touching the screen may be set to be displayed at the center of the screen, or the part surrounded by a circle may be set to be enlarged and displayed.
As described above, it may be set so that not only images captured with a microscope or the like but also images of animals captured from a database such as an electronic pictorial book are displayed. In this case, a description about the animal may be displayed in text beside the displayed stereoscopic image. In this case, it is considered that it is easier for the observer to read the text part as a two-dimensional image, that is, an image having no parallax.
In addition, by making the camera 20 recognize a card on which food or the like is drawn, the displayed animal may be set to display a gesture for eating food. If the projection display apparatus 10 is used, it is difficult for shadows such as a hand to appear in the displayed stereoscopic image, so that even if the card is inserted, the stereoscopic image can be displayed without being lost.
You may set so that images, such as a dinosaur, may be displayed from the card in which the IC chip is incorporated. In this case, an image display system is composed of a projection display apparatus, a camera, a plurality of glasses and a card reader. In the case of such contents, the presence of air (wind), water, and a scent toward the observer is provided in addition to the three-dimensional image. Further, when the camera 20 detects that the observer's hand is approaching, the stereoscopic image may be set to cause an action.
In this reference example, the camera 20 indicates which region of each region R1, R2, R3, and R4 each eyeglass 30 corresponds to, specifically, which region is substantially in front of the viewer. Although used for discrimination, the utilization method of the camera 20 is not limited to this. It is also possible to create an indoor video by integrating 360 ° video output divided and output from the camera 20.
The present invention has been described based on some embodiments. It is understood by those skilled in the art that these embodiments are exemplifications, and that various modifications can be made to combinations of the respective constituent elements and processing processes, and such modifications are also within the scope of the present invention. By the way.
According to the consideration according to the second embodiment, the glasses 30 to be worn by the observer depend on the position of the observer wearing the three or more images having a predetermined parallax between them. It is understood that it is only necessary to show the two images specified by the observer. More specifically, it is understood that it is only necessary to show two images having parallax in the direction perpendicular to the observer's line-of-sight direction among the three or more images.
When shutter glasses capable of variably controlling the opening / closing operation timing are employed, the image analysis unit 12 specifies the position of the observer from the image captured by the camera 20. A glasses control unit (not shown) generates a control signal for setting the opening / closing timing of the glasses 30 in the glasses 30 according to the position of the observer, and the synchronization signal transmission unit 16 sends the control signal to the glasses 30. Send. This control can be performed with one or more observers. If this control is performed in real time, even if the observer moves and the direction of viewing the object changes, it is possible to show the observer a combination of images in which a stereoscopic image can always be observed.
V1 1st observer, V2 2nd observer, 10 Projection type image display device, 11 Image signal holding part, 12 Image analysis part, 13 Image processing part, 14 Projection part, 15 Synchronization signal generation part, 16 Synchronization signal transmission part , 20 camera, 21 microscope, 30 glasses (30a: first glasses, 30b: second glasses, 30c: third glasses, 30d: fourth glasses), OBJ object, 40 display area, 50 image display system.
An image display unit for displaying three or more images having a predetermined parallax between them in a predetermined display area in time or space;
Glasses to be worn by an observer who sees an image displayed in the display area,
The glasses include a camera that captures an image displayed in the display area, and a control unit that determines two images to be shown to the observer among the three or more images.
When a direction confirmation image having a shape that looks different depending on the line of sight of the observer is displayed in the display area by the image display unit, the direction confirmation image is captured by the camera,
Determining the viewing direction of the observer according to the orientation of the direction confirmation image;
Select two images with parallax in the direction perpendicular to the line-of-sight direction,
Standing body image display system that is characterized in that operate to show the two images selected in the viewer.
When the three or more images having a predetermined parallax are displayed in the display area by the image display unit, the three or more images are captured by the camera,
Calculating the position of each of the three or more images,
Select the two most horizontal images of the images,
Glasses to be worn by an observer who sees an image displayed in the display area;
A reference object that is arranged in the vicinity of the display area and has a different appearance depending on the viewing direction of the observer ,
The reference object is photographed by the camera,
Detect the reference object from the imaged area,
Determining the viewing direction of the observer based on the appearance of the detected reference object;
A reflector disposed near the display area and reflecting an image in the display area toward an observer ;
When a direction confirmation image having a different appearance depending on the line of sight of the observer is displayed on the display area by the image display unit, the area including the reflector is photographed by the camera,
Detecting the reflector from the captured image,
Based on the direction confirmation image reflected on the reflector, determine the viewing direction of the observer,
The image display unit, three-dimensional image display system according to any one of claims 1 to 4, which is a projection display apparatus for projecting an image onto a predetermined projection plane.
JP2009293192A 2009-01-29 2009-12-24 Stereoscopic image display system Expired - Fee Related JP5465523B2 (en)
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JP2009293192A JP5465523B2 (en) 2009-01-29 2009-12-24 Stereoscopic image display system
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JP2011050029A JP2011050029A (en) 2011-03-10
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JP2009293192A Expired - Fee Related JP5465523B2 (en) 2009-01-29 2009-12-24 Stereoscopic image display system
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