JP2012078749A - Stereoscopic image display system, image controller, and stereoscopic image display method - Google Patents

Abstract

A stereoscopic image display system, an image control apparatus, and a stereoscopic image display method are provided that allow a plurality of observers to view stereoscopic images having different parallaxes.
A stereoscopic image display system according to the present invention selectively displays a right eye image and a left eye image to a viewer of a display device 34 that displays a right eye image and a left eye image in a time-division manner. And a light shielding device 32 for shielding light. The display device 34 displays the first stereoscopic image that realizes the first parallax and the second stereoscopic image that realizes the second parallax different from the first stereoscopic image by time division. The first stereoscopic image is composed of a first right eye image 112 and a first left eye image 111. The second stereoscopic image includes a second right eye image 113 and a first left eye image 111. The light shielding device 32 shields a part of the plurality of display images so that a combination of images having the first parallax or a combination of images having the second parallax is visually recognized by the observer.
[Selection] Figure 3

Description

  The present invention relates to a stereoscopic image display system, an image control apparatus, and a stereoscopic image display method.

  In the video industry field, demands for supply of 3D video shooting means and display means are increasing along with an increase in the opportunity to open 3D movies and the spread of 3D television. Accordingly, the development of technology in this field is progressing.

  For example, Patent Document 1 discloses a technique for showing a stereoscopic video to a viewer. FIG. 7 is a block diagram showing the overall configuration of the stereoscopic image display system disclosed in Patent Document 1. As shown in FIG. As shown in FIG. 7, in this system, the recording device 6 reproduces the medium on which the stereoscopic video is recorded, and outputs the right-eye video 1 and the left-eye video 2 to the display device 3 such as a television. . Cables 3A and 3B for supplying control signals are provided between the display device 3, the shutter 4, and the glasses 7A. The user views the images 5A and 5B output from the display device 3 via the shutter 4 using the glasses 7A provided with a liquid crystal shutter or a polarizing plate. Thereby, the user can see a stereoscopic image.

JP 2009-135686 A

  However, in the stereoscopic image display system disclosed in Patent Document 1, when a plurality of users view images output to a display device, there is a problem that only stereoscopic images with the same parallax can be seen. As a specific example where a problem occurs, it is conceivable that a child feels uncomfortable when a parent and child views a stereoscopic image movie having a parallax for adults. This is because there is a large difference in the amount of parallax between the eyes of children and adults.

  The stereoscopic image display system according to the present invention continuously time-divides a first stereoscopic image having a first parallax and a second stereoscopic image having a second parallax different from the first parallax. A display device for displaying and a light shielding device for selectively shielding the first stereoscopic image or the second stereoscopic image are provided. With such a configuration, the viewer can view a stereoscopic image having different parallaxes by visually recognizing a combination of images having the first parallax or a combination of images having the second parallax. it can.

  The image control apparatus according to the present invention is a time-division method in which a first stereoscopic image having a first parallax and a second stereoscopic image having a second parallax different from the first parallax are time-divisionally continuous. Means for obtaining data, and the generated time-division data, for the display device capable of continuously displaying the first stereoscopic image and the second stereoscopic image included in the time-division data, Output. With such a configuration, the viewer can view a stereoscopic image having different parallaxes by visually recognizing a combination of images having the first parallax or a combination of images having the second parallax. it can.

  The stereoscopic image display method according to the present invention continuously time-divides a first stereoscopic image having a first parallax and a second stereoscopic image having a second parallax different from the first parallax. The first stereoscopic image or the second stereoscopic image is selectively transmitted to allow the observer to recognize one of the images. With such a configuration, the viewer can view a stereoscopic image having different parallaxes by visually recognizing a combination of images having the first parallax or a combination of images having the second parallax. it can.

  According to the present invention, it is possible to provide a stereoscopic image display system, an image control apparatus, and a stereoscopic image display method that allow a plurality of observers to view stereoscopic images having different parallaxes.

1 is a configuration example of a stereoscopic image display system according to a first exemplary embodiment. 3 is a time chart for editing time-division image data according to the first embodiment; FIG. 6 is a diagram illustrating a specific example of stereoscopic image display according to the first embodiment. FIG. 4 is a time chart of image display according to the first embodiment. FIG. 10 is a diagram illustrating a specific example of stereoscopic image display according to the second embodiment. FIG. 10 is a diagram illustrating a specific example of stereoscopic image display according to the third embodiment. It is a block diagram which shows the whole structure of the stereo image display system concerning related technology.

Embodiment 1 of the Invention
The first embodiment will be described below with reference to the drawings. FIG. 1 is a diagram illustrating a configuration example of a stereoscopic image display system according to the first embodiment. The stereoscopic image display system shown in FIG. 1 includes an imaging system 10 and a display system 30. The photographing system 10 is a system that creates photographed image data and collects the image data into continuous time-division image data 20 in a time division manner. The display system 30 reproduces the time-division image data 20 as an image, and performs shutter control of 3D glasses (light-shielding device).

  The photographing system 10 includes a plurality of photographing devices 11, 12, 13 and a photographing editing device 14. In this example, the photographing device 11, the photographing device 12, and the photographing device 13 are separate photographing devices that respectively create image data. The plurality of photographing devices are photographing devices having a function of photographing a subject such as a video camera or a movie camera. Note that even if the plurality of photographing devices are not configured by a plurality of completely independent photographing devices, images are input to a single image element through optical paths such as lenses and mirrors from imaging positions separated from each other, and sequentially. The optical path may be switched to time division to generate a time division image.

  Here, each of the photographing device 11, the photographing device 12, and the photographing device 13 is arranged so as to photograph the subject from different positions. In this example, the parallax set by the image shot by the shooting apparatus 11 and the image shot by the shooting apparatus 12, and the parallax set by the image shot by the shooting apparatus 11 and the image shot by the shooting apparatus 13 are set. Is different.

  The photographing editing device 14 edits the image data created by the photographing device 11, the photographing device 12, and the photographing device 13, and creates time-division image data 20 that is time-division multiplexed data. The photographing and editing device 14 is, for example, a personal computer in which dedicated editing software is installed, or a VTR (Video Tape Recorder).

  Here, the image data editing process executed by the photographing editing device 14 will be described with reference to the time chart of FIG. In FIG. 2, image data captured by the image capturing device 11 is represented as A, image data captured by the image capture device 12 is represented as B, and image data captured by the image capture device 13 is represented as C. The image data is divided for each frame. For example, in the image data A, the data is divided into data for each frame such as A1, A2, and A3 from the left. Further, in FIG. 2, time elapses from the left to the right in the figure. That is, the data A2 is later in time series than the data A1, and the data A3 is later in time series than the data A2. The same applies to image data B and image data C.

  The photographing editing device 14 converts the image data A, the image data B, and the image data C photographed by the photographing device 11, the photographing device 12, and the photographing device 13 into one continuous image data that is time-divided. Specifically, as shown in FIG. 2, the time-division image data 20 includes image data A, image data B, A1, B1, C1, A2, B2, C2, A3, B3, C3. Image data C is image data that is time-divided and recorded alternately. At this time, one frame of the time-division image data 20 includes image data A1, B1, and C1. The next frame in the time series includes image data A2, B2, and C2, and the next frame includes image data A3, B3, and C3. The same applies to the subsequent frames. As described above, the imaging / editing device 14 edits the image data captured by the plurality of imaging devices 11, 12, and 13 so as to form one time-division image data 20 by time division.

  The display system 30 illustrated in FIG. 1 provides a stereoscopic image to a plurality of users (observers) based on the time-division image data 20. The image control device 31 generates a control signal for displaying the time-division image data 20 on the display device 34 and outputs it to the display device 34 together with the input time-division image data 20. In synchronization with the display control on the display device 34, the image control device 31 generates and outputs a control signal for allowing the user to visually recognize a stereoscopic image in the adult 3D glasses 32 and the child 3D glasses 33. The control signal for the 3D glasses 32 and 33 includes at least a synchronization signal for allowing the 3D glasses 32 and 33 to pass through only a necessary image in synchronization with the image display of the display device 34 and visually recognize the image. . Further, the synchronization signal indicates whether the image displayed on the display device 34 with respect to the 3D glasses 32 and 33 is an image for adults or an image for children, and further, whether the image is for the right eye or the left eye. Information, in other words, information indicating which image capturing device is used to capture the image may be included. The time-division image data 20, the control signal for the display device 34, and the control signal for the 3D glasses 32 and 33 may be transmitted to the display device 34 and the 3D glasses 32 and 33 by either wired or wireless. Good.

  The image control device 31 is, for example, a DVD (Digital Versatile Disc) player or a Blu-ray player that supports playback of stereoscopic images. The adult 3D glasses 32 and the children's 3D glasses 33 have the shape of glasses adapted to the average head size and parallax of each adult and child.

  The adult 3D glasses 32 and the child 3D glasses 33 are provided with a light shielding mechanism (for example, a liquid crystal shutter) in the lens portions of the left and right eyes in addition to the normal glasses frame. Further, the adult 3D glasses 32 and the child 3D glasses 33 have a receiving means (not shown) for receiving a control signal output from the image control device 31 and both eyes based on the control signal received by the receiving means. Control means (not shown) for opening and closing the liquid crystal shutter. By this control means, the control of whether light is transmitted or blocked is performed for the left and right eyes of the user. The adult 3D glasses 32 and the child 3D glasses 33 control shutter opening / closing of the right and left eyes of the 3D glasses 32 and 33 in synchronization with a control signal output from the image control device 31.

  For example, when the control signal includes only a synchronization signal common to the adult 3D glasses 32 and the child 3D glasses 33, the adult 3D glasses 32 displays an image that an adult should view based on the synchronization signal. Is recognized, and the shutter is opened at this timing. The child 3D glasses 33 recognize the timing at which an image to be visually recognized by the child is displayed based on the synchronization signal, and open the shutter at this timing. When the control signal is a control signal unique to each of the adult 3D glasses 32 and the child 3D glasses 33, the control signal is composed of a unique synchronization signal including the information. The adult 3D glasses 32 recognize the timing at which an image to be viewed by an adult is displayed based on the synchronization signal, and open the shutter at this timing. The child 3D glasses 33 recognize the timing at which an image to be visually recognized by the child is displayed based on the synchronization signal, and open the shutter at this timing. In this way, it is possible to control so that only necessary images among the images displayed on the display device 34 by the user's right eye and left eye such as adults and children reach.

  FIG. 3 illustrates a specific example of the stereoscopic image display process according to the first embodiment. In this example, the image of the object to be photographed 101 is received from each of the photographing camera lens 102 for the left eye, the photographing camera lens 103 for the right eye child, and the photographing camera lens 104 for the right eye adult, and the photographing device performs photographing. The photographing camera lens 102 for the left eye is mounted on the photographing device 11 of FIGS. 1 and 2, the photographing camera lens for the right eye 103 for the child is mounted on the photographing device 13, and the photographing camera lens for the right eye adult 104 is mounted on the photographing device 12. In shooting, the shooting camera lens left eye 102 and the shooting camera lens right eye are compared with the amount of parallax (first parallax) of images shot through the shooting camera lens left eye 102 and the shooting camera lens right eye 104 for adults. The amount of parallax (second parallax) of the image taken by the child 103 is reduced. Therefore, each lens is arranged so that the distance between the shooting camera lens left eye 102 and the shooting camera lens right eye adult 104 is longer than the distance between the shooting camera lens left eye 102 and the shooting camera lens right eye child 103. Has been.

  Three types of captured images are included in images captured through the photographing camera lens 102 for the left eye, the photographing camera lens 103 for the right eye child, and the photographing camera lens 104 for the right eye adult. That is, the photographed camera lens for the left eye 102 is for the photographed image left eye 105, the photographed camera lens for the right eye for the child 103 is photographed for the right eye for the child 106, and the photographed camera lens for the right eye adult 104 is the photographed image for the right eye adult 107. Obtainable. The captured image for the left eye 105 corresponds to the image data A in FIG. 2, the captured image for the right eye 107 for adults corresponds to the image data B, and the captured image for the right eye for children 106 corresponds to the image data C. The three types of captured images, the captured image for the left eye 105, the captured image for the right eye for adult 107, and the captured image for the right eye for child 106, are edited to be one time-division image data (not shown) by time division. Details of this editing are as described above.

  The image display means 108 reproduces image data in which the captured image for the left eye 105, the captured image for the right eye 107 for adults, and the captured image for the right eye for children 106 are edited in a time division manner. Here, the image display means 108 cyclically displays three display images corresponding to each photographed image, the display image for the left eye 111, the display image for the right eye 112, and the display image for the right eye child 113 in a time division manner. To do. The display image left eye 111 corresponds to the captured image left eye 105, the display image right eye adult 112 corresponds to the captured image right eye adult 107, and the display image right eye child 113 corresponds to the captured image right eye child 106. . The image display means 108 generates the adult 3D glasses control signal 109 and the child 3D glasses control signal 110 in synchronization with the image display, and transmits them to the adult 3D glasses 32 and the child 3D glasses 33, respectively.

  The image display means 108 is a combination of the image control device 31 and the display device 34 shown in FIG. Actually, inside the image display means 108, the image control device 31 alternately displays the display image for the left eye 111, the display image for the right eye 112 for the adult, and the display image for the right eye for the child 113 on the display device 34 alternately in time division. A control signal is output so that the Hereinafter, it is assumed that the display device 34 displays an image displayed by the image display unit 108 based on a control signal from the image control device 31 inside the image display unit 108.

  The adult 3D glasses 32 include a 3D glasses shutter left eye 114 as a left eye liquid crystal shutter and an adult 3D glasses shutter right eye 115 as a right eye liquid crystal shutter. The children's 3D glasses 33 include a 3D glasses shutter left eye 114 as a left eye liquid crystal shutter and a children's 3D glasses shutter right eye 116 as a right eye liquid crystal shutter. The adult 3D glasses 32 are worn by an adult user, and the child 3D glasses 33 are worn by a child user.

  Due to the adult 3D glasses control signal 109, the adult 3D glasses 32 causes only the 3D glasses shutter left eye 114 to open and the adult 3D glasses shutter right eye 115 to close while the display image left eye 111 is displayed. Let When the display image right-eye adult 112 is displayed, only the adult 3D glasses shutter right-eye 115 is opened, and the 3D glasses shutter left-eye 114 is closed. During the time when the display image right-eye child 113 is displayed, both the 3D glasses shutter left eye 114 and the adult 3D glasses shutter right eye 115 are closed. The display image left eye 111 is also referred to as a first left eye image, the display image right eye adult 112 is also referred to as a first right eye image, and a combination of the first left eye image and the first right eye image is a first stereoscopic image. Also called. The first stereoscopic image is a stereoscopic image that realizes the first parallax described above.

  Similarly, according to the child 3D glasses control signal 110, the child 3D glasses 33 causes the 3D glasses shutter left eye 114 to open only during the time that the display image left eye 111 is displayed, and the child 3D glasses shutter right eye is opened. Application 116 is closed. During the time that the display image right-eye child 113 is displayed, only the child's 3D glasses shutter right eye 116 is opened and the 3D glasses shutter left eye 114 is closed. When the display image right-eye adult 112 is displayed, the 3D glasses shutter left-eye 114 and the child 3D glasses shutter right-eye 116 are closed. The display image for the left eye 111 is also referred to as the first left eye image, the display image for the right eye child 113 is also referred to as the second right eye image, and a combination of the first left eye image and the second right eye image is the second stereoscopic image. Also called. This second stereoscopic image is a stereoscopic image that realizes the above-described second parallax.

  FIG. 4 is a time chart regarding stereoscopic image display according to the first embodiment. The image display means 108 converts the time-division image data 20 generated in FIG. 2 as an image and displays it. Based on the control of the adult 3D glasses control signal 109 and the children's 3D glasses control signal 110 shown in FIG. 3, the adult 3D glasses 32 and the children's 3D glasses 33 show what images adults and children see. This will be further explained. In the following description, “image A1” refers to an image in which the image data A1 is displayed as an image by the image display means 108. The same applies to “image B1” and “image C1”. The adult 3D glasses 32 fully open the left-eye shutter when it detects that a type A image is displayed, and fully opens the right-eye shutter when it detects that a type B image is displayed. Control to open. The children's 3D glasses 33 fully open the left-eye shutter when it detects that a type A image is displayed, and fully opens the right-eye shutter when it detects that a type C image is displayed. Take control. In other cases, it is assumed that the shutter is completely closed.

  First, during the time that the image A1 is displayed on the image display means 108, the 3D glasses control signal 109 for adults and the 3D glasses control signal 110 for children are currently displaying the type A image on the display device 34. This is transmitted to the adult 3D glasses 32 and the child 3D glasses 33. Based on the control signal, the adult 3D glasses 32 and the child 3D glasses 33 open the shutter of the 3D glasses shutter left eye 114. That is, both the adult 3D glasses 32 and the child 3D glasses 33 open the left-eye shutter, and both the adult and the child see the image A1 with the left eye.

  Next to the image A1, the image B1 is displayed on the image display means 108. During this period, the adult 3D glasses control signal 109 and the children's 3D glasses control signal 110 indicate that the type B image is currently displayed on the display device 34, and that the adult 3D glasses 32 and the children's 3D glasses 33 are displayed. To communicate. Based on the control signal, the adult 3D glasses 32 opens the shutter for the adult 3D glasses shutter right eye 115. The 3D glasses 33 for children keeps the shutters of the right eye and the left eye closed based on the control signal. That is, only an adult sees the image B1 with the right eye.

  Next to the image B1, the image C1 is displayed on the image display means 108. During this period, the adult 3D glasses control signal 109 and the children's 3D glasses control signal 110 indicate that the type C image is currently displayed on the display device 34, and that the adult 3D glasses 32 and the children's 3D glasses 33 are displayed. To communicate. Based on the control signal, the children's 3D glasses 33 opens the shutter for the children's 3D glasses shutter right eye 116. The adult 3D glasses 32 keeps the shutters of the right eye and the left eye closed based on the control signal. That is, only the child sees the image C1 with the right eye.

  As described above, when the image display unit 108 displays the image A1, the image B1, and the image C1 in one frame, the adult looks at the image A1 with the left eye, the image B1 with the right eye, and the child looks at the image A1 with the left eye. The image C1 will be seen. In the next frame, the images A2, B2, and C2 are displayed on the image display means 108 in a similar pattern, and adults and children see the same type of image as the previous frame. The same applies to the next frame. Thus, in parallel with the adult viewing the image A with the left eye and the image B with the right eye, the child views the image A with the left eye and the image C with the right eye. Adults see parallax images alternately with their left and right eyes, and can view stereoscopic images. Since the child sees an image with a smaller amount of parallax than the adult alternately with the left eye and the right eye, the child can see a stereoscopic image with less 3D effect than the adult.

  As described above, in the first embodiment, the first stereoscopic image captured with the parallax for adults and the second stereoscopic image captured with the parallax for children are displayed in a time division manner, and the first stereoscopic image is displayed for the adult. By displaying the second stereoscopic image to the child, the adult and the child can enjoy the stereoscopic image having no discomfort in the parallax amount. Also, depending on the setting of the image to be combined and the control of opening / closing of the shutter, it becomes possible to select and display a desired stereoscopic image to an arbitrary person.

  In the first embodiment, the image that the child and the adult see with the left eye are the same image (first left eye image), but the image that the child and the adult see with the right eye are the same image (first image). Right eye image). In this case, the adult uses the left eye 111 (first left eye image) for the display image with the left eye, and the child uses the second left eye image (the second stereoscopic image having the second parallax in combination with the first right eye image). For left eye). Thereby, an adult can view the first stereoscopic image, and the child can view the second stereoscopic image.

  Also, the time of each frame in FIGS. 2 and 4 is preferably 1/60 seconds or less in order to recognize a moving image without recognizing flicker for human eyes when reproduced.

Embodiment 2 of the Invention
Hereinafter, the stereoscopic image display system according to the second embodiment will be described. Note that descriptions of the same components and methods as those in Embodiment 1 are omitted as appropriate. In the first embodiment, a stereoscopic image with different parallax is provided to an adult and a child using an image for the left eye common to the adult and the child. However, in the second embodiment, different left-eye images are prepared for adults and children, and stereoscopic images with different parallaxes are provided to adults and children. Since the center of the parallax amount is strictly different between an adult and a child, the stereoscopic display system according to the second embodiment is suitable when it is necessary to further improve the user's comfort. Therefore, the aspect of the invention of Embodiment 2 in which images for the left eye are used differently for adults and children than the aspect of the invention of Embodiment 1 in which the images for left eyes are commonly used by adults and children. This can provide a more accurate stereoscopic image for children.

  FIG. 5 is a diagram illustrating a specific example of stereoscopic image display according to the second embodiment. The four different types of photographing devices in FIG. 5 are obtained by adding a photographing camera lens 201 for the left eye child as a left eye camera to the three kinds of photographing devices in FIG. Accordingly, a captured image left-eye child 202 and a display image left-eye child 203 are newly generated as images for the left eye of the child. The left eye of the child 3D glasses 33 is provided with a child 3D glasses shutter left eye 204 as a liquid crystal shutter instead of the same 3D glasses shutter left eye 114 as that of an adult.

  In the second embodiment, four types of photographing devices including the photographing camera lens for the left eye 102, the photographing camera lens for the right eye for children 103, the photographing camera lens for the right eye for adults 104, and the photographing camera lens for the left eye for children 201 are provided. The object 101 is photographed. At this time, compared with the amount of parallax (first parallax) of the images photographed through the photographing camera lens left eye 102 and the photographing camera lens right eye adult 104, the photographing camera lens left eye 201 and photographing camera lens right eye child Shooting is performed so that the amount of parallax (second parallax) of the image shot through 103 is reduced. In photographing, the center point of the image photographed through the photographing camera lens for the left eye for the child 201 and the photographing camera lens for the right eye for the child 103, and the photographing camera lens for the left eye 102 and the photographing camera lens for the right eye for the adult 104 are photographed. The center points of the obtained images should be the same.

  Four types of captured images are obtained from the photographing of the photographing camera lens for the left eye 102, the photographing camera lens for the right eye 103 for children, the photographing camera lens for the right eye 104 for adults, and the photographing camera lens for the left eye 201 for children. That is, the photographed image left-eye 105, the photographed image right-eye adult 107, the photographed image right-eye child 106, and the photographed image left-eye child 202. The captured image for the left eye 105, the captured image for the right eye for adult 107, the captured image for the right eye for child 106, and the captured image for the left eye for child 202 are edited so as to be time-division image data (not shown). Details of this editing are as described above. In the second embodiment, since there are four types of images to be displayed, one frame of time-division image data is divided into four.

  The image display means 108 reproduces image data that is time-divided into the captured image left-eye 105, the captured image right-eye adult 107, the captured image right-eye child 106, and the captured image left-eye child 202, and edited into one. Four types of display images corresponding to image data are displayed in a time-division manner: display image 111 for adults with left eye, display image 112 for adults with right eye, display image 203 for children with left eye, and display image 113 for children with right eye. The display method is the same as in FIG. 2 of the first embodiment.

  The image display means 108 generates the adult 3D glasses control signal 109 and the child 3D glasses control signal 110 in synchronization with the image display, and outputs them to the adult 3D glasses 32 and the child 3D glasses 33, respectively. The configuration of the adult 3D glasses 32 is the same as that of the first embodiment. However, the child 3D glasses 33 include a children's 3D glasses shutter 204 for the left eye as a left eye shutter and a children's 3D glasses shutter as a right eye shutter. A right eye 116 is provided.

  Due to the adult 3D glasses control signal 109, the adult 3D glasses 32 causes only the 3D glasses shutter left eye 114 to open and the adult 3D glasses shutter right eye 115 to open during the time that the display image left eye 111 is displayed. Close. When the display image right-eye adult 112 is displayed, only the adult 3D glasses shutter right-eye 115 is opened, and the 3D glasses shutter left-eye 114 is closed. When the display image left eye child 203 and the display image right eye child 113 are displayed, both the 3D glasses shutter left eye 114 and the adult 3D glasses shutter right eye 115 are closed. Note that the display image left-eye adult 111 is also referred to as a first left-eye image, and the display image right-eye adult 112 is also referred to as a first right-eye image. A combination of the first left-eye image and the first right-eye image is a first three-dimensional image. Also called an image. The first stereoscopic image is a stereoscopic image that realizes the first parallax described above.

  Similarly, the children's 3D glasses control signal 110 causes the children's 3D glasses 33 to open only the children's 3D glasses shutter left eye 204 when the display image left eye children's 203 is displayed. The 3D glasses shutter right eye 116 is closed. During the time when the display image right-eye children's 113 is displayed, only the child's 3D glasses shutter right eye 116 is opened, and the children's 3D glasses shutter left-eye 204 is closed. When the display image left-eye adult 111 and the display image right-eye adult 112 are displayed, the child 3D glasses shutter left eye 204 and the child 3D glasses shutter right eye 116 are closed. Note that the display image left-eye child 203 is also referred to as a second left-eye image, and the display image right-eye child 113 is also referred to as a second right-eye image, and a combination of the second left-eye image and the second right-eye image is referred to as a second stereoscopic image. Also called an image. This second stereoscopic image is a stereoscopic image that realizes the above-described second parallax.

  The time chart relating to the stereoscopic image display of the second embodiment is almost the same as that of the first embodiment, and thus the description thereof is omitted. With the above configuration, also in the aspect of the present invention according to the second embodiment, a stereoscopic image (first stereoscopic image) captured with parallax for adults and a stereoscopic image (second stereoscopic image captured with parallax for children) are used. Image) is displayed in a time-sharing manner, and adults and children can see stereoscopic images for adults, and children can enjoy stereoscopic images that are comfortable with parallax. Become. In addition, depending on the setting of the image and the shutter to be combined in a time division manner, it becomes possible to select and display only a target image to an arbitrary person. Furthermore, in the aspect of the present invention according to the second embodiment, it is possible to provide an adult and a child with a stereoscopic image for an adult and a stereoscopic image for a child that have different parallaxes and a common center point between both eyes. it can.

Embodiment 3 of the Invention
The third embodiment of the present invention will be described below. Note that description of the same components and methods as those in Embodiments 1 and 2 will be omitted as appropriate. In the first embodiment and the second embodiment, image data for adults and children are captured and displayed. However, the image data is not limited to those for adults and children, but has other parallax such as a larger amount of parallax. It is also possible to add and display image data. For example, in a video work in which a giant monster appears, a stereoscopic image viewed from the giant monster side may be displayed on the display device in a time-sharing manner as in the first and second embodiments. From the viewpoint of a huge monster whose virtual parallax is much larger than that of humans, the actual set looks like a miniature. Therefore, by displaying an image including a viewpoint from a huge monster, a new effect can be aimed at.

  FIG. 6 is a diagram illustrating a specific example of stereoscopic image display in the third embodiment. 6 are obtained by adding a photographic camera lens right-eye other 301 as a camera for other purposes such as a monster to the three types of photographing devices in FIG. Accordingly, a captured image right-eye other 302 and a display image right-eye other 303 are newly generated as other left-eye images. In addition to the 3D glasses for adults 32 and the 3D glasses for children 33, the stereoscopic image display system is provided with 3D glasses for other use 306 as 3D glasses. The left eye of the other 3D glasses 306 is provided with a 3D glasses shutter left eye 114, and the right eye is provided with an other 3D glasses shutter right eye 305 as a liquid crystal shutter.

  In the third embodiment, the four photographing devices of the photographing camera lens for the left eye 102, the photographing camera lens for the right eye for children 103, the photographing camera lens for the right eye for adult 104, and the photographing camera lens for the right eye for others 301 shoot the photographing object 101. I do. At this time, the parallax between the images taken by the shooting camera lens left eye 102 and the shooting camera lens right eye 103 for children is smaller than the parallax between images taken by the shooting camera lens left eye 102 and the shooting camera lens right eye 104 for adults. In addition, the parallax between the images taken by the photographing camera lens for the left eye 102 and the photographing camera lens right eye for the other 301 is far larger than the parallax between the images taken by the photographing camera lens for the left eye 102 and the photographing camera lens for the right eye 104. Take a picture so that it becomes larger.

  Four types of captured images are obtained from the photographing of the photographing camera lens for the left eye 102, the photographing camera lens for the right eye 103 for children, the photographing camera lens for the right eye 104 for adults, and the photographing camera lens for the right eye 301 for others. That is, the photographed image for the left eye 105, the photographed image for the right eye for the child 106, the photographed image for the right eye for the adult 107, and the photographed image for the right eye for the other 302. These four types of images are edited so as to be one time division image data (not shown) by time division. The image display means 108 reproduces image data in which the captured image for the left eye 105, the captured image for the right eye for adult 106, the captured image for the right eye for adult 107, and the captured image for the right eye for other 302 are combined in a time division manner. The corresponding four types of display images, display image left eye 111, display image right eye adult 112, display image right eye child 113, and display image right eye other 303, are displayed in a time-sharing manner. The manner of display is the same as in the first and second embodiments.

  The details of the image display means 108 sending the adult 3D glasses control signal 109 and the children's 3D glasses control signal 110 to the adult 3D glasses 32 and the children's 3D glasses 33 are the same as those in the first embodiment, and thus the description thereof is omitted. Here, the control related to the opening / closing of the shutters of both eyes, which is performed by the other 3D glasses 306 based on the other 3D glasses control signal 304 output from the image display unit 108, will be described.

  Based on the other 3D glasses control signal 304, the other 3D glasses 306 causes only the 3D glasses shutter left eye 114 to be opened while the display image left eye 111 is displayed, and the other 3D glasses shutter right eye 305. Is closed. During the time when the display image right-eye others 303 is displayed, only the other 3D glasses shutter right-eye 305 is opened, and the 3D glasses shutter left-eye 114 is closed. When the display image right-eye adult 112 and the display image right-eye child 113 are displayed, both the 3D glasses shutter left eye 114 and the other 3D glasses shutter right eye 305 are closed.

  The time chart relating to the stereoscopic image display of the third embodiment is almost the same as that of the first embodiment, and thus the description thereof is omitted. With the above configuration, in the aspect of the present invention according to the third embodiment, a stereoscopic image captured with parallax for adults, a stereoscopic image captured with parallax for children, and a stereoscopic image captured with parallax for other purposes are displayed. Displayed in time division. Specifically, with the image shown to the left eye in common, three types of right-eye images are prepared for adults, children, and others, and each image is displayed on the display device in a time-sharing manner. Accordingly, it is possible to select and display three types of stereoscopic images to an arbitrary user by shutter control of the glasses. Further, by increasing the number of photographing devices, it is possible to select and display four or more types of stereoscopic images.

  In the above description, the parallax for other purposes is larger than that of a human adult, but may be smaller than that of a human child. In that case, the parallax between the images taken by the shooting camera lens for the left eye 102 and the shooting camera lens right eye for the other 301 is compared with the parallax between the images taken by the shooting camera lens for the left eye 102 and the shooting camera lens for the right eye 103. Take a picture to make it smaller. In any case, it is sufficient to set the other parallax as the parallax different from the human parallax and perform shooting. Alternatively, shooting may be performed by setting the parallax for other purposes to be smaller than that of adults and larger than that of children.

  When displaying an image in time division, as the number of divisions increases as in the second and third embodiments, the display time of an image that is actually transmitted through 3D glasses around one frame is displayed. It will be shorter. This is dealt with by increasing the luminance of the display device 34, increasing the frequency to shorten the time of one frame, and reducing the flicker. In fact, human eyes flicker at 60 Hz or higher, considering that the fluorescent lamps blink 50 or 60 times per second and that the TV frequency has been interlaced for 60 fields for a long time. If the time of one frame is about 1/60 second or less, it is considered that the uncomfortable feeling hardly occurs. In addition, shortening the display time of one frame can be easily performed in recent years when double-speed display and triple-speed display on a television have become commonplace due to advances in technology.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention. For example, the present invention is not limited to stereoscopic display, and can be applied to normal non-stereoscopic images (images with no parallax on the left and right). In the above embodiment of the present invention, a plurality of types of images are displayed in a time-sharing manner, and different images are displayed by the user's right eye and left eye by controlling the shutter, thereby providing a stereoscopic image to the user. . That is, if the 3D glasses are controlled so as to output the same image to both eyes of the user by controlling the shutter, a non-stereoscopic image can be provided to the user. The display device may display a plurality of types of non-stereoscopic images in a time-sharing manner and provide the user with a plurality of types of non-stereoscopic images. Further, a stereoscopic image may be displayed for a certain user and a non-stereo image may be displayed for another user under the control of the image control apparatus. As an example, when the whole family goes to watch a stereoscopic movie, one person can view a non-stereoscopic ordinary image in order to get 3D sickness.

  In addition to non-stereo images, you can create multiple types of images with different effects, such as black and white or sepia, or film noise in the images, and display them in a time-sharing manner on the display device. You may make it make it.

  Although there are a plurality of types of stereoscopic images that can be displayed on the display device, it is not always necessary to provide different images to a plurality of users. Usually, it is possible to display the same image for all of a plurality of users and change the image to be displayed for each user at a specific time.

  Further, the user of the 3D glasses may select and view an arbitrary image. For example, in the first embodiment, the adult 3D glasses control signal 109 and the children's 3D glasses control signal 110 are received by the user so that both the adult 3D glasses 32 and the children's 3D glasses 33 can be transmitted. It can be considered that the control signal can be selected for adults or children. Based on the selected control signal, the 3D glasses control the opening and closing of the shutters for the right eye and the left eye as in the above embodiment. Further, the setting on the image control apparatus side instead of the 3D glasses side may be changed so that the user can select an image.

  In the above embodiment, a plurality of photographed image data is time-divided and recorded as time-division image data. However, a plurality of image data need not be time-divided at the recording stage, and may be displayed in a time-division manner as in the embodiment when displayed on the display device. In the time division display in the above embodiment, different types of images are alternately displayed in each frame. However, this may not be completely alternating. It is sufficient if different types of images are displayed in a time-sharing manner, and two types of images are displayed on the right eye and left eye, respectively, so that it can be recognized as a three-dimensional moving image by the human eye.

  In the above embodiment, image data having a plurality of parallaxes is taken in advance. However, even if the image data having a plurality of parallax differences is not captured in advance, the image data is created by the image capturing / editing device or the image control device. May be displayed. Further, the object to be imaged may be an imaginary object that does not actually exist. In other words, instead of the shooting system as shown in the embodiment, in the creation of CG or animation, a plurality of frames of the shooting target are created so as to generate parallax, and these are used as a plurality of image data to be time-shared. The image data may be recorded as one image data. Of course, any object to be imaged may be used.

  In the above embodiment, different audio data may be provided from a display device to users of different 3D glasses. Thereby, a plurality of users can view different three-dimensional images and different sounds corresponding thereto.

  In the above embodiment, the 3D glasses completely transmit or block light according to the opening / closing of the shutter. However, even when an image other than the image that the user originally sees is displayed on the display device, part of the light from the image may be transmitted. Alternatively, even in an image originally shown to the user, a part of the image may be shielded without transmitting all light.

  In the above embodiment, the control device outputs a control signal that synchronizes the timing to the 3D glasses in synchronization with a change in the image displayed on the display device, and the 3D glasses respond to the control signal according to the control signal. Suppose you want to control the opening and closing of a shutter. However, the control device may output a signal for directly controlling the opening and closing of the right eye and the left eye to the 3D glasses in synchronization with the image displayed on the display device. In that case, for example, in the first embodiment, the control signal output to the 3D glasses by the control device includes identification information indicating whether the 3D glasses are for adults or children, and the shutters of the right eye and left eye when the 3D glasses are for adults. It may be configured to include opening / closing control information and information regarding the opening / closing control information of the right-eye and left-eye shutters for children. For example, the identification information for adults or children is expressed as “1” for adults and “0” for children, and may be included in a part of the identification signal. Good. The shutter opening / closing and the like may be expressed similarly.

  Moreover, in the said embodiment, control of 3D glasses was performed by the image control means (image display and control means). However, there is no image control means, and only the 3D glasses may be provided with a stereoscopic image to the user by performing the same processing as in the present embodiment in synchronization with the display of the image data. That is, the 3D glasses may be configured to detect the type of image displayed on the display device and to control the opening and closing of the liquid crystal shutters of the right eye and the left eye accordingly.

  In the above embodiment, the 3D glasses are provided with a liquid crystal shutter. However, other shutters may be used as long as they have a shutter function that can control opening and closing. Alternatively, 3D glasses using techniques such as polarization and spectroscopy may be used. For example, when a polarization technique is used, the displayed images are different types of images, and a configuration having different polarizations is conceivable. Further, the right eye and the left eye of the 3D glasses are composed of members having a polarization function, such as different types of polarizing plates or liquid crystal filters capable of changing the polarization direction. As a result, the light of the image having the same polarization direction as each eye member of the 3D glasses is visually recognized by the user, and the light of the image having a polarization direction different from that of the eye member is not visually recognized by the user. By adjusting the polarization direction and the polarization direction of each member of the 3D glasses, a stereoscopic image having different parallax can be provided to a plurality of users. Further, if the display device has a function of shielding a part of an image displayed by time division, it does not have to be in the form of glasses.

DESCRIPTION OF SYMBOLS 10 Shooting system 11, 12, 13 Shooting apparatus 14 Shooting editing apparatus 20 Time division image data 30 Display system 31 Image control apparatus 32 3D glasses 33 for adults 3D glasses 34 for children Display apparatus 101 Shooting object 102 Shooting camera lens 103 For left eye 103 Shooting camera lens right eye for child 104 Shooting camera lens right eye for adult 105 Shooting image for left eye 106 Shooting image right eye for child 107 Shooting image right eye for adult 108 Image display / control means 109 Adult 3D glasses control signal 110 Children's 3D glasses control signal 111 Display Image For Left Eye 112 Display Image Right Eye For Adult 113 Display Image Right Eye For Child 114 3D Glasses Shutter For Left Eye 115 Adult 3D Glasses Shutter For Right Eye 116 Child 3D Glasses Shutter For Right Eye 201 Shooting Camera Lens For Left Eye Child
202 Photographed image Left eye child 203 Display image Left eye child 204 Child 3D glasses shutter Left eye 301 Photographing camera lens Right eye and others 302 Photographed image right eye and others 303 Display image right eye and others 304 Other 3D glasses control signal 305 Other 3D glasses Glasses shutter for left eye 306 Other 3D glasses

Claims (9)

A display device that continuously displays a first stereoscopic image having a first parallax and a second stereoscopic image having a second parallax different from the first parallax in a time-division manner;
A stereoscopic image display system comprising a light shielding device that selectively shields the first stereoscopic image or the second stereoscopic image. The display device further time-divides a third stereoscopic image having a third parallax different from each of the first parallax and the second parallax with the first stereoscopic image and the second stereoscopic image. Display cyclically,
The stereoscopic image display system according to claim 1, wherein the light shielding device selectively transmits any one of the first stereoscopic image, the second stereoscopic image, and the third stereoscopic image. The first stereoscopic image includes a first right-eye image and a first left-eye image that realizes a first parallax in combination with the first right-eye image.
The second stereoscopic image is a right-eye image or a left-eye image that realizes the second parallax in combination with any one of the first right-eye image and the first left-eye image, or the first right-eye image. And a second right-eye image and a second left-eye image having the second parallax independently of the first left-eye image,
The light-shielding device shields a part of the plurality of display images so that a combination of images having a first parallax or a combination of images having a second parallax is visually recognized by the observer;
The stereoscopic image display system according to claim 1. The display device
In each of the plurality of frames to be displayed, the first stereoscopic image and the second stereoscopic image are displayed in a time-sharing manner.
The three-dimensional image display system in any one of Claims 1-3.   The stereoscopic image display system according to any one of claims 1 to 4, wherein the first parallax is a parallax set for adults, and the second parallax is a parallax set for children. .   The stereoscopic image display system according to claim 2, wherein the third parallax is a parallax set to a parallax different from that of a human being. Means for acquiring time-division data continuous by time-division of a first stereoscopic image having a first parallax and a second stereoscopic image having a second parallax different from the first parallax;
An image control device that outputs the generated time-division data to a display device that can continuously display the first stereoscopic image and the second stereoscopic image included in the time-division data. For a light-shielding device that can selectively shield an image with respect to an observer of the display device, a combination of images having the first parallax or a combination of images having the second parallax is visually recognized by the observer. Output a control signal for shielding a part of a plurality of display images,
The image control apparatus according to claim 7. A first stereoscopic image having a first parallax and a second stereoscopic image having a second parallax different from the first parallax are displayed in a time-division manner continuously.
A stereoscopic image display method for selectively transmitting the first stereoscopic image or the second stereoscopic image and causing an observer to recognize any image.

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