JP2006121553A - Video display unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To display proper 2D video and 3D video while considering the fatigue of the eyes. <P>SOLUTION: A video from an output T2 of a 2D/3D converting means is turned into a video L31 shown by 1-3. The video L31 is obtained as a 3D image where images for the right eye and the left eye are arranged side by side on the basis of a T1 signal. When 2D is selected by 2D/3D manual switching, a 2-6 image is supplied to a 3D video display means, and an image L51-2 of 2-9 is displayed. When 3D is selected by the 2D/3D manual switching, the image of 2-7 is supplied to the 3D video display means, and an image L51-3 of 2-10 is displayed. The image of 2-7 is a 3D image, and a 2D/3D switching control means controls the 3D video display means to realize 3D image display. Thus, any T2 signal unsuitable for display is controlled so as not to be selected. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to video display technology, and more particularly to a stereoscopic video display device.

  In recent years, television broadcasting for portable terminals has been studied. Examples thereof include mobile broadcasting and broadcasting using one segment of terrestrial digital broadcasting. However, both of these have the disadvantage that the images are examined by QVGA and the images are coarse. The receiver is also portable and designed with a small screen size, making it difficult to get a sense of realism. Three-dimensional video is a useful method for enhancing the realism of an image and improving the visual quality of the image, and can compensate for image roughness and small defects.

  Various techniques have been disclosed for video display techniques for displaying video three-dimensionally. For example, an apparatus that has a function of converting a 2D video (hereinafter referred to as 2D video) into a 3D video (hereinafter referred to as 3D video) and performs 3D display based on a video signal obtained from broadcasting or communication means is disclosed. (For example, refer to Patent Document 1).

Also, there is a disclosure relating to a device that displays a three-dimensional broadcast transmitted from a broadcasting station as it is in three dimensions, and converts a two-dimensional broadcast into a three-dimensional display (for example, see Patent Document 2).
JP 7-226958 A JP-A-10-150608

  As described above, despite various proposals for performing three-dimensional display, it is difficult to say that 3D display devices are currently in widespread use. The following can be considered as this factor.

  1) First, in the case of a system that requires a special instrument or device such as “glasses” in order to view a stereoscopic image, the convenience of being able to watch casually at any time is impaired. In particular, it is inconvenient if a portable receiver requires a special device such as glasses.

  2) There is also a problem that there are very few providers of stereoscopic images to be displayed by the stereoscopic display system. However, if a situation in which a stereoscopic video is broadcast on television in the future is realized, it is considered useful for increasing the stereoscopic video to be displayed. Therefore, a combination of means capable of receiving broadcasts and 3D display means is preferable, but even if an apparatus capable of displaying only 3D broadcasts in 3D is provided, the opportunity to view stereoscopic images is very limited. Considering the widespread use of 2D display devices at present, it is unlikely that 3D video broadcasting will soon increase. Such a problem can be solved by adding a function of converting 2D video to 3D video on the receiver side.

  3) On the other hand, it is known that the function of eyes when observing 3D images is different from the function of normal eyes. For this reason, depending on how the 3D images are made, eye fatigue may occur. . Therefore, it is preferable to have a function of receiving a 3D video signal and displaying a 2D video in order to rest the eyes.

  A video obtained by 3D-2D conversion of a 3D video or a video obtained by 2D-3D conversion of a 2D video is not a video to be displayed originally.

  An object of the present invention is to provide a technique capable of displaying appropriate 2D video images and 3D video images while considering eye fatigue.

  In the display device capable of displaying 2D and 3D, when 2D display is performed, the 2D video signal is displayed as 2D, the 3D video signal is converted into 2D, and is displayed. When displaying, the 3D video signal is displayed as 3D, the 2D video signal is converted into 3D and displayed, and the dimensional conversion operation is controlled so that the same dimensions are not converted (double conversion). It is characterized by doing.

  The apparatus of the present invention is an apparatus capable of automatically selecting and correctly displaying 2D and 3D with respect to a received video signal, converting and displaying from 2D to 3D, and converting and displaying from 3D to 2D. is there. On the other hand, manual switching is also possible. In this case, the device incorporates a device that does not display a defective image obtained by performing 2D conversion to 2D and 3D to 3D (conversion between the same dimensions). Conversion between the same dimensions may not be performed in advance.

  It should be noted that, when the power is turned on, 2D display is performed, and if the user does not want to perform 3D display, the default setting is set so that 2D display is easier on the eyes.

  According to the video display device of the present invention, it is possible to view 3D video and to easily enjoy 3D video even when no 3D video is input. At this time, the display was optimized so as not to display inappropriate video that was converted between the same dimensions. Further, by defaulting the processing for performing 2D display when the power is turned on, it is possible to reduce eyestrain of the user.

  Hereinafter, an image display device according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a functional block diagram showing a configuration example of a video display device according to this embodiment. In the video display apparatus shown in FIG. 1, reference numeral 1 denotes broadcast receiving means, which includes an antenna 11 and a tuner 12. The received video signal is output from the tuner 12. This video signal is a 2D video if the video to be broadcast is a 2D video, and a 3D video if the video is a 3D video.

  A display example based on a video signal in the case of 3D video is shown in FIG. The left-eye image L1 is displayed on the left half of the screen in FIG. 2, and the right-eye image R1 is disposed on the right half. Various methods other than such a method have been proposed for the 3D video transmission method. For example, there is a method of transmitting in a field sequential manner.

  Returning to FIG. 1, the description will be continued. Reference numeral 2 denotes 2D-3D conversion means for converting 2D video to 3D video. The 2D-3D conversion means 2 for converting 2D video into 3D video is used to view 3D video when the broadcasted video is 2D video, and converts the broadcast to 3D in real time. An example of a method for converting a broadcast to 3D in real time will be briefly described below.

  For example, a left camera and a right camera are prepared, the left camera image is displayed as a left eye image, the right camera image is displayed as a right eye image on the display surface of the display, the left eye image is the left eye, and the right eye image is the right eye. If displayed so as to reach, the observer recognizes the depth based on the shift Xm between the left-eye image and the right-eye image, so that the depth can be expressed and stereoscopic viewing is possible. However, since using two cameras for three-dimensional imaging usually has a large burden of shooting, if a large number of existing two-dimensional images can be viewed three-dimensionally, a new three-dimensional image can be obtained. It is very convenient without having to shoot. Therefore, if two images whose display positions are shifted as described above are created from one two-dimensional image, it can be viewed as a three-dimensional image. Since the shift amount Xm changes depending on the distance of the subject, an image in which the shift amount is changed depending on the subject distance may be created (see Japanese Patent Application No. 2003-108611).

  Returning to FIG. 1, reference numeral 3 denotes 3D-2D conversion means for converting 3D video to 2D video. Although 3D video can enhance the realism of the image, it is known that the eye function when observing the 3D video is different from the normal eye function. There are concerns about the effects on health, such as large eyestrain. Also, depending on the viewer's preference, there are cases where the user wants to view the 2D video. Therefore, 3D-2D conversion means is provided so that 2D display is possible even for 3D video.

  An example of converting 3D video to 2D video is shown in FIG. Assuming a video in the format shown in FIG. 2 as a 3D video, the left-eye image L1 and the right-eye image R1 are each a 2D image. Therefore, in order to convert 3D video into 2D video, either one of the images may be taken out and displayed. Here, a case where the left-eye image L1 is extracted will be described as an example. The left-eye image L1 is taken out and enlarged to fill the angle of view as shown in the lower diagram of FIG.

  Returning to FIG. 1, reference numeral 4 denotes a stereoscopic image display means. The stereoscopic video display means 4 is a device that can switch between two-dimensional video display and three-dimensional display. As a suitable example of such a display device, there is a device described below. Since 3D video can be viewed with the naked eye without any special equipment and can be switched between 2D display and 3D display, it is suitable for application to this embodiment. This apparatus includes a display liquid crystal panel that generates a display image according to input image data, a patterned retardation plate as a parallax barrier that gives a specific viewing angle to a display image at the time of 3D display and obtains a 3D effect, And a switching liquid crystal panel that switches between 2D display and 3D display by switching the validity / invalidity of the parallax barrier effect.

  However, the above apparatus is a system using a parallax barrier, and has a drawback that a viewing range that can be viewed in three dimensions is narrow. When this method is applied to a device with a large display screen, it is necessary for the viewer to move by himself / herself to find the optimum position to adjust the viewing position, and the head is always fixed at the searched position. This is inconvenient.

  In the present embodiment, it is intended to use the above device as a display device for a portable terminal. The display unit of the portable terminal device is small, and by moving the terminal device by hand, an optimal position can be searched without moving his / her head. As a result, fatigue can be reduced and the features of the parallax barrier system that glasses are unnecessary can be utilized.

  Reference numeral 5 denotes switching means for switching between 2D display and 3D display. Hereinafter, the operation of the switching means 5 will be described. Reference numeral 51 denotes 2D3D switching control means. Reference numeral 52 denotes a video signal selector which is controlled by the 2D3D switching control means 51 and outputs either the selected 2D video or 3D video. The 2D3D switching control means 51 also switches the stereoscopic video display means 4 according to whether the selected video signal is 2D video or 3D video, and displays 2D video or 3D video according to the selected video signal. .

  Reference numeral 53 denotes a 2D3D manual / automatic switch. Select whether to perform 2D-3D switching manually or automatically. Reference numeral 54 denotes a 2D3D manual changeover switch. When the 2D3D manual / automatic changeover switch is set to manual, the switch is used to switch between 2D and 3D. Reference numeral 55 denotes a 3D detection means for discriminating between a 2D video signal and a 3D video signal.

  As an example of a 2D video signal / 3D video signal discrimination method, when creating a 3D video, a special identification signal indicating a 3D signal is superimposed on the video signal, and this identification signal is included in the video signal. Is determined to be a 3D video signal, and if this identification signal is not present in the video signal, it is determined to be a 2D video signal. As a specific method for superimposing an identification signal, for example, in the case of digital broadcasting, a video signal is sent as an MPEG2 TS (transport stream). This TS (transport stream) includes program information. It is. As program information, information indicating whether it is a 2D image or a 3D image is included and transmitted. As described above, the 3D detection unit 55 may analyze the program information included in the TS to determine whether it is 2D video or 3D video.

  Reference numeral 6 denotes video signal recording / reproducing means. The recording / reproducing means 6 includes a recording / reproducing circuit 61 and a recording medium 62. The recording / reproducing means 6 is arbitrarily provided and is not an indispensable component for receiving broadcasts. However, by providing the recording / reproducing means 6, the user can view a desired image in 2D or 3D at a desired time. It becomes possible. Further, since the content recorded by another device can be reproduced via the medium, the convenience is further increased.

  Reference numeral 71 denotes a video switching unit that switches between displaying the video of the broadcast receiving unit 1 and displaying the video of the video recording / reproducing unit 6, and broadcasting by the selector 72 based on the signal input by the video switching unit 71. Switching between output of the video of the receiving means 1 and the video of the video recording / reproducing means 6 is switched.

  Next, with reference to FIGS. 4 and 5, the overall operation when a broadcast is received will be described. Reference is also made to FIGS. 1 to 3 as appropriate. When broadcast reception is started (step S1), the output of the broadcast receiving means 1 is output to the output terminal of the selector 72. The signal at this output terminal is designated as T1 signal. Here, in step S2, the 3D detection means 55 detects whether the T1 signal is a 2D signal or a 3D signal. If the detection result of the 3D detection means 55 is a 2D signal, the process proceeds to step S3. If the detection result of the 3D detection means 55 is a 3D signal, the process proceeds to step S11. If the 2D broadcast is received, the T1 signal is a video L21 like 1-2 in FIG. 4 (that is, the same signal as the broadcast image 1-1, based on the signal at this time Assuming that the video is displayed, the video is the video shown in L21).

  The video based on the output T2 of the 2D-3D conversion unit 2 is a video L31 indicated by 1-3 in FIG. The video L31 is a 3D image in which images for the left eye and for the right eye are created and arranged based on the T1 signal. Further, the output T3 of the 3D-2D conversion means 3 is a video L22 shown in 1-4. The 3D-2D conversion operates to enlarge the left side of the 3D image as described above. However, when a 2D image is input, the left half of the input image becomes an enlarged image and does not become the entire image. Therefore, the final presentation of this image displays a meaningless image that is different from the transmitted image, which causes viewer confusion. Therefore, it is necessary not to display this image.

  The selector 52 selects and outputs one of the L21 (T1), L31 (T2), and L22 (T3) signals. In step S3, the 2D image signal is preliminarily subjected to through (T1 signal), 2D-3D conversion (T2 signal), and 3D-2D conversion (T3 signal) to prepare respective signals. Actually, it is possible to control so that unnecessary conversion is not performed in advance.

  Next, in step S4, it is determined whether 2D3D automatic switching is manual switching. First, in the case of 2D-3D automatic switching (in the case where the 2D-3D manual / automatic switch 53 is automatic), the process proceeds to step S5, and since the input broadcast image is a 2D image, 3D detection means 55 detects that the T1 signal is a 2D image and sends the result to the 2D-3D switching control means 51. Then, the 2D-3D switching control means 51 controls the selector 52 so as to select the T1 signal that is a 2D image (step S6).

  Next, in the case of 2D-3D manual switching (this is when the 2D-3D manual / automatic switch 53 is set to manual), an image is selected according to the switching of the 2D-3D manual switching SW54. When the 3D detection means 55 detects that the T1 signal is a 2D image (step S8), it is known in advance that the T1 signal is a 2D signal and the T2 signal is a 2D-3D conversion signal. Therefore, if the 2D-3D manual switching SW 54 selects 2D in step S9, the process proceeds to step S6, and T1 is selected. If 3D is selected by the 2D-3D manual switching SW 54, the process proceeds to step S10, where the T2 signal 2D-3D switching control means 51 controls the selector 52 so that is selected.

  When the signal thus selected by the selector 52 is actually displayed on the stereoscopic video display means 4, the video is as follows. In the case of 2D-3D automatic switching, the L21 image based on the T1 signal is supplied to the stereoscopic video display means 4, and the 1-8 image L41-1 is displayed (step S7). That is, since the input T1 signal 1-5 is a two-dimensional image, the 2D-3D switching control means 51 controls the stereoscopic video display means 4 to display the same two-dimensional image as the input T1 signal 1-5 (step S7).

  In the case of 2D-3D manual switching, when 2D is selected, the image L21 of 1-6 is supplied to the stereoscopic video display means 4, and the image L41-2 of 1-9 is displayed. The 1-6 image L21 is a two-dimensional image, and the 2D-3D switching control means 51 controls the selector 52 so as to select the T1 signal that is a 2D image. An image is displayed. In the case of 2D-3D manual switching, when 3D is selected, the image LR31 of 1-7 including L31 and R31 is supplied to the stereoscopic video display means 4, and the image of 1-10 is displayed. Reference numeral 1-7 denotes a three-dimensional image LR31. The 2D-3D switching control unit 51 controls the stereoscopic video display unit 4 to display a three-dimensional image, so that a three-dimensional image display L41-3 is obtained.

  At this time, it should be noted that the selector 52 does not select a T3 signal that is not suitable for display. That is, selection control is performed so that an abnormal image L22 based on the T3 signal of 1-4 is not selected and displayed.

  Next, when a 3D broadcast is received (lower column in FIG. 4), the T1 signal at the T1 terminal is the video LR11 of 2-2 in FIG. 4 (that is, the broadcast image LR11 of 2-1 itself). ). The signal at the output terminal T2 of the 2D-3D conversion means 2 becomes an image LR22 indicated by 2-3 in FIG. The image LR22 is an image in which left-eye and right-eye images are created and arranged based on the T1 signal. Since the original signal is a 3D signal, a signal obtained by 2D-3D conversion of the original signal is 3D converted based on a set of left eye image + right eye image, and thus becomes an image LR22 as shown in 2-3. Even if this is supplied to the stereoscopic video display means 4, a normal image cannot be obtained. Therefore, it is necessary to control this image not to be selected. The output T3 of the 3D-2D conversion means 3 is a 2-4 image L11 '. This is because the 3D-2D conversion operates to enlarge the left side of the 3D image as described above.

  The selector 52 selects and outputs one of the signals from T1 to T3. First, in the case of 2D-3D automatic switching (this is the case where the 2D-3D manual / automatic switch 53 becomes automatic) (step S12), since the broadcast image is a 3D image, the 3D detection means 55 uses the T1 signal as a 3D image. (Step S12), and sends the result to the 2D-3D switching control means 51. Then, the 2D-3D switching control means 51 controls the selector 52 so as to select the T1 signal that is a 3D image (step S14).

  Next, in the case of 2D-3D manual switching (when the 2D-3D manual / automatic switch 53 is set to manual) in step S12, an image is selected according to the 2D-3D manual switch 54. It is known in advance that the 3D detection means 55 detects that the image is a 3D image (step S16), the T1 signal is a 3D signal, and the T3 signal becomes a 3D-2D conversion signal. Accordingly, when the 2D-3D manual changeover switch 54 selects 2D (step S18), the T3 signal is selected, and when the 2D-3D manual changeover switch 54 selects 3D, the T1 signal is selected. Then, the 2D-3D switching control means 51 controls the selector 52.

  In this way, the video actually displayed on the stereoscopic video display means 4 from the signal selected by the selector 52 is as follows. In the case of 2D-3D automatic switching, the 2-5 signal is supplied to the stereoscopic video display means 4 and the 2-8 image L51-1 is displayed. Reference numeral 2-5 denotes a three-dimensional image, and the 2D-3D switching control means 51 controls the stereoscopic video display means 4 to display a three-dimensional image, so that a three-dimensional image is displayed (step S15).

  When 2D is selected by 2D-3D manual switching, the 2-6 image L11 'is supplied to the stereoscopic video display means 4, and the 2-9 image L51-2 is displayed. Reference numeral 2-6 denotes a two-dimensional image, and the 2D-3D switching control means 51 controls the stereoscopic video display means 4 to display a two-dimensional image, so that a two-dimensional image display is performed. When 3D is selected by 2D-3D manual switching, the image L11 of 2-7 is supplied to the stereoscopic video display means 4, and the image L51-3 of 2-10 is displayed. Reference numeral 2-7 denotes a three-dimensional image, and the 2D-3D switching control means 51 controls the stereoscopic video display means 4 to display a three-dimensional image, so that a three-dimensional image is displayed. As described above, control is performed so as to avoid selection of a T2 signal that is not suitable for display.

  As described above, in the case of 2D-3D automatic switching, 2D or 3D is automatically selected and displayed using the output signal of the 3D detection means 55. In the case of 2D-3D manual switching, 2D or 3D is manually selected. When 2D display is selected, if the received image is a 2D image, it is displayed as 2D as it is. If the received image is 3D, it is 3D-2D converted and displayed in 2D. When 3D display is selected, if the received image is 2D, 2D-3D conversion is performed and the 3D image is displayed. If the received image is 3D, it is displayed as 3D as it is. Then, the abnormal images L22 and LR22 as shown in 1-4 and 2-3 of FIG. 4 are not displayed.

  However, when viewing 3D images, eyestrain may occur, so for users who are not familiar with 3D display, when the power is turned on, it will start with 2D-3D manual switching, and it will be in 2D display. It is desirable to make the viewer aware of 3D display by switching to the 3D mode. However, since this operation tends to be complicated, a user who understands fatigue of the eyes can improve usability by providing an automatic switching mode. Although the above description has been made on the case of broadcast reception, the same operation is performed when displaying a reproduction signal from the recording / reproducing means 6.

  As described above, according to the stereoscopic video display device according to the present embodiment, the appropriate position for viewing stereoscopic video can be easily obtained by providing a small display unit that displays 3D video on the portable terminal. Can be found.

  In this signal, switching between 2D display and 3D display can be automatically performed by detecting a discrimination signal superimposed on the image. Switching between 2D display and 3D display can be performed manually or automatically. However, it is possible to reduce eye fatigue caused by viewing only the 3D display by setting the 2D display when the power is turned on. Even when manually switching between 2D display and 3D display, the discrimination signal superimposed on the image is detected and displayed, and the 3D signal is converted to 3D again and the 2D signal is again displayed. It is possible to control so that the signal converted into the 2D signal is not displayed on the screen.

  As described above, according to the stereoscopic video display device according to the present embodiment, it is possible to view a 3D broadcast image and to easily enjoy a 3D image even when there is no 3D broadcast. It also reduces eye fatigue.

  The present invention can be applied to an apparatus capable of displaying a stereoscopic image. In particular, it can be used for a device having a small display unit such as a mobile phone or a mobile terminal.

It is a functional block diagram which shows the structural example of the video display apparatus by one embodiment of this invention. It is a figure which shows an example of the image for left eyes and the image for right eyes for 3D images | videos. It is a figure which shows the example of a conversion from 3D video to 2D video. It is a figure which shows a 2D / 3D conversion display list. It is a flowchart figure which shows the flow of 2D / 3D conversion processing.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Broadcast receiving means, 2 ... 2D-3D conversion means, 3 ... 3D-2D conversion means, 4 ... Stereoscopic image display means, 5 ... Switching means, 6 ... Recording / reproducing means, 51 ... 2D-3D
52 ... selector, 71 ... video switching means, 72 ... selector.

Claims (12)

Video signal receiving means for receiving a video signal;
2D-3D video converting means for converting the video signal received by the video signal receiving means from 2D video to 3D video;
3D-2D video converting means for converting the video signal received by the video signal receiving means to 3D video into 2D video;
Detecting means for detecting whether the received video signal is a two-dimensional video or a three-dimensional video;
Video display means capable of displaying in two display modes of two-dimensional display and three-dimensional display;
An image display apparatus comprising: a switching control unit that performs control to switch between two-dimensional display and three-dimensional display in the video display unit based on a detection result by the detection unit.   The switching control means includes the output signal from the video signal receiving means, the output signal from the 2D-3D video conversion means, and the output signal from the 3D-2D video conversion means by the detection means. The video display apparatus according to claim 1, wherein a signal to be output to the video display means is selected based on a detection result.   3. The video display device according to claim 1, wherein the detection unit detects a 2D-3D discrimination signal superimposed on the video signal and sends a 2D-3D discrimination result to the switching control unit. . A switch for setting whether to automatically or manually switch between the two-dimensional display and the three-dimensional display for the switching control means;
The switching control means converts a 2D-image signal into a 2D-based signal based on a detection result of the detection means when a setting for manually switching between the two-dimensional display and the three-dimensional display is made by operating the switch. 4. The video display device according to claim 1, wherein control is performed so that a signal obtained by 3D-2D conversion of a 3D-converted signal and a 2D video signal is not displayed on the video display means. 5.   5. The video display device according to claim 1, wherein two-dimensional display is selected by the switching control unit when the power is turned on.   6. The video display device according to claim 1, wherein the video display means is a three-dimensional video display means that can be observed with the naked eye.   A portable terminal comprising the video display device according to claim 1.   8. The video display device according to claim 1, further comprising video signal recording / reproducing means for reproducing a recorded signal as the video signal.   9. The video display apparatus according to claim 1, wherein the source of the video signal is either a broadcast signal or a reproduction signal of recorded content. Receiving a video signal;
2D-3D video conversion for converting the received video signal from 2D video to 3D video;
A 3D-2D video conversion step of converting the received video signal into a two-dimensional video from a three-dimensional video;
Detecting whether the received video signal is a 2D video or a 3D video;
In this step, control is performed to switch between two-dimensional display and three-dimensional display depending on which one of the video signals converted based on the detection result in the detection step is selected, and the signal after the switching control is displayed. Step to exclude the conversion from the same dimension to the same dimension
A video display method characterized by comprising: Receiving a video signal;
Detecting whether the received video signal is a 2D video or a 3D video;
Based on the detection result in the detection step, the received video signal is through, or 2D-3D video conversion for converting 2D video to 3D video, or 3D for converting 3D video to 2D video. Determining which to select -2D video conversion;
Displaying the signal after performing the switching control in the determining step, excluding the conversion from the same dimension to the same dimension, and displaying
A video display method characterized by comprising:   The program for making a computer perform the step of Claim 10 or 11.

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