JP2010049047A - Image display and image display method - Google Patents

Abstract

A video display device and a video display method capable of displaying a brighter three-dimensional image without crosstalk while avoiding complication of the configuration of the device.
An image display device includes a reflective liquid crystal panel 11R, 11G, and 11B, laser light sources 9R, 9G, and 9B, the number of lines of one frame of a left-eye video signal, and the number of lines of one frame of a right-eye video signal. A line number conversion unit 5 that reduces the number of lines, a timing generation unit 6 that generates a display timing signal and an irradiation timing signal based on the left-eye video signal and the right-eye video signal from which the number of lines has been reduced, and a display instruction unit 7 And the laser light source driving unit 8, and the reflective liquid crystal panel duplicates the video signal of each line of the video signal for the left eye and the video signal for the right eye with the reduced number of lines supplied from the display instruction unit 7. A video signal is generated by generating a video signal of a plurality of lines and simultaneously writing the duplicated video signals of the plurality of lines on the display panel.
[Selection] Figure 1

Description

  The present invention relates to a video display device and a video display method for displaying a stereoscopic video by alternately displaying a left-eye video and a right-eye video in a time division manner.

  A method of displaying a stereoscopic image by causing a left-eye image and a right-eye image to enter the corresponding eyes individually has been put into practical use. However, this method has the problem of crosstalk, in which a part of the left eye image can be seen when viewing the right eye image with the right eye, or a part of the right eye image can be seen when viewing the left eye image with the left eye. is there. To solve this problem, the light source for display panel illumination is turned off during image rewriting, and the light irradiation timing is controlled so that the light source is turned on after image rewriting is completed. There has been proposed a video display method for reducing crosstalk of video for use (see, for example, Patent Document 1).

JP 2003-202519 A (paragraphs 0084, 0096-0097, FIGS. 14 and 16)

  However, the video display method described in Patent Document 1 has a problem that the screen becomes darker than the video display method in which the light source is continuously turned on because the lighting time of the light source is shortened.

  In order to solve the problem of dark screens, there is an image display method in which a light source is provided for each line, and after rewriting one line of the image, the light source that illuminates the corresponding line is controlled to turn on. (For example, refer to Patent Document 1), there is a problem that the configuration of the apparatus becomes complicated.

  Therefore, the present invention has been made to solve the above-described problems of the prior art, and an object of the present invention is to display a brighter stereoscopic image without crosstalk while avoiding complication of the configuration of the apparatus. It is an object of the present invention to provide a video display device and a video display method capable of performing the above.

  The video display device of the present invention is a video display device that alternately displays a left-eye video and a right-eye video of a stereoscopic video in a time-sharing manner, and includes display means including a display panel for displaying the video, Illuminating means, and a left-eye video signal and a right-eye video signal being input, and a line-number conversion means for reducing the number of lines in one frame of the left-eye video signal and the number of lines in one frame of the right-eye video signal A timing generation means for generating a display timing signal and an irradiation timing signal based on the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines; and The video signal for the left eye whose number of lines has been reduced and the number of lines before being reduced at a timing synchronized with the display timing signal for each frame. Display instruction means for alternately supplying video signals for the right eye, and illumination driving means for causing the illumination means to execute the light irradiation at a timing synchronized with the irradiation timing signal for each frame, The display unit replicates the video signal of each line of the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines supplied from the display instruction unit, and outputs a plurality of lines. The video signal is generated, and the video is displayed by simultaneously writing the duplicated video signals of the plurality of lines on the display panel.

  The video display method of the present invention is a video display method for alternately displaying a left-eye video and a right-eye video of a stereoscopic video in a time-division manner, wherein the line number conversion means receives the left-eye video signal and the right-eye video signal. Reducing the number of lines in one frame of the video signal for the left eye and the number of lines in one frame of the video signal for the right eye, and timing generating means, wherein the video signal for the left eye and the lines with the reduced number of lines The display means including a step of generating a display timing signal and an irradiation timing signal based on the video signal for the right eye whose number is reduced and a display panel for displaying the video are synchronized with the display timing signal for each frame. The left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines are alternately received at the same timing. The video signal for each line of the video signal for the left eye with the reduced number of lines and the video signal for the right eye with the reduced number of lines is duplicated to generate a video signal of a plurality of lines. A step of displaying a video by simultaneously writing a video signal of a line to the display panel, and a lighting unit irradiating the display panel with light at a timing synchronized with the irradiation timing signal for each frame. And performing irradiation.

  In the present invention, since the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines are transmitted to the display means, the reception time of the video signal can be shortened. Further, in the present invention, the display means generates a video signal of a plurality of lines by duplicating the video signal of each line of the video signal for the left eye with the reduced number of lines and the video signal for the right eye with the reduced number of lines. In addition, since the video is displayed by simultaneously writing the duplicated video signals of the plurality of lines to the display panel, it is possible to shorten the writing time to the display panel. For this reason, according to the present invention, it is possible to lengthen the time for which the illumination means is lit within a range in which crosstalk between the left-eye video and the right-eye video can be prevented, and a bright video can be displayed, and the left-eye video and the right-eye video can be displayed. This has the effect of preventing crosstalk of the video. In addition, according to the present invention, since it is not necessary to provide a light source for each line, it is possible to avoid complication of the configuration.

Embodiment 1 FIG.
FIG. 1 is a block diagram schematically showing a configuration of a video display apparatus according to Embodiment 1 of the present invention (that is, an apparatus that performs the video display method according to Embodiment 1). As shown in FIG. 1, the video display device according to Embodiment 1 includes a 2D video / stereoscopic video (2D / 3D) switching unit 1, a 2D video (2D) double speed conversion unit 2, and a two-dimensional video. And a video (2D) timing generation unit 3. In addition, the video display apparatus according to Embodiment 1 includes a stereoscopic video (3D) double speed conversion unit 4, a line number conversion unit 5, a stereoscopic video (3D) timing generation unit 6, and stereoscopic video (3D) information. And a transmission unit 15. Further, the video display device according to the first embodiment includes a display instruction unit 7 and a laser light source driving unit 8.

  Also, as shown in FIG. 1, the video display apparatus according to Embodiment 1 has a red light laser light source 9R, a green light laser light source 9G, a blue light laser light source 9B, and a red light as the configuration of the optical system. Polarization beam splitter (PBS) 10R, green light polarization beam splitter (PBS) 10G, blue light polarization beam splitter (PBS) 10B, red light reflection type liquid crystal panel 11R, green light reflection type liquid crystal panel 11G, blue It has a light reflection type liquid crystal panel 11B, a cross dichroic prism 12, a projection lens 13, a screen 14, and three-dimensional (3D) glasses 16. In the first embodiment, the reflective liquid crystal panels 11R, 11G. Although a projection type image display apparatus that enlarges and projects light (image) modulated by 11B onto the screen 14 will be described, the present invention is not limited to such a form, and the liquid crystal panel is viewed directly by the viewer. A direct-view image display device may be used. In addition, the video display device according to Embodiment 1 is a device that displays either a two-dimensional video or a stereoscopic video, but the video display device according to the present invention has only a configuration for displaying a stereoscopic video. A stereoscopic video display device may be used.

  FIG. 2 is a diagram showing an internal configuration of the red light reflection type liquid crystal panel 11R in FIG. As shown in FIG. 2, the red light reflective liquid crystal panel 11R includes a display driver 21R, a source driver 22R, a gate driver 23R, and a display panel 24R. Although FIG. 2 shows the red light reflection type liquid crystal panel 11R, the green light reflection type liquid crystal panel 11G and the blue light reflection type liquid crystal panel 11B have the same configuration as the red light reflection type liquid crystal panel 11R. Yes.

  As shown in FIG. 1, the 2D / 3D switching unit 1 switches whether an input video signal is processed as a normal two-dimensional video (2D) or a stereoscopic video (3D). Switching by the 2D / 3D switching unit 1 is automatically performed according to information added to the video signal, or is performed according to input information from an operation unit (not shown) by the user. The 2D / 3D switching unit 1 outputs the input video signal to the 2D double speed conversion unit 2 when 2D video processing is selected, and the input video signal when 3D video processing is selected. Is output to the 3D double speed conversion unit 4. In the first embodiment, the 2D / 3D switching unit 1 outputs to the laser light source driving unit 8 a video mode switching signal indicating which of the two-dimensional video processing or the stereoscopic video processing is selected. However, the video mode switching signal is used, for example, when the intensity of the laser beam is switched. However, when the intensity of the laser beam is not switched, it is not necessary to output it to the laser light source driving unit 8.

If the two-dimensional image processing by the 2D / 3D switching unit 1 is selected, 2D for rate conversion section 2 converts the video signal _{S 21} which is input with a frame frequency 60Hz to 120Hz in 2D speed video signal _{S 22.} The converted 2D double-speed video signal S ₂₂ is input to the 2D timing generator 3. 2D timing generator 3 generates a liquid crystal display signal _{P 22a} for controlling the reflection type liquid crystal panel 11R, 11G, and 11B, a laser light source driving signals _{L 2} for controlling the laser light source 9R, 9G, and 9B. The generated liquid crystal display signal P _{22 a} is input to the display instruction unit 7. The display instruction unit 7 supplies the liquid crystal display signal P _22a to the reflective liquid crystal panels 11R, 11G, and 11B and transmits information indicating that the current display image is a two-dimensional image. On the other hand, the laser light source driving signal L ₂ is input to the laser light source driving unit 8. A laser light source driving unit 8, the laser light source driving signal L laser source 9R based on _2, 9G, the laser light source 9R as laser light emitted from the 9B is output by the drive timing fixed, 9G, 9B lighting and Controls turning off. Here, a laser light source is used as the light source of the illuminating means, but other light sources such as a light emitting diode (LED) may be used as long as the light source can be controlled to emit light and has high luminance.

If stereoscopic video processing is selected by the 2D / 3D switching unit 1, 3D for double speed conversion unit 4 converts the video signal _{S 31} which is input with a frame frequency 60Hz to 120Hz for 3D-speed video signal _{S 32.} The converted 3D double-speed video signal S ₃₂ is input to the line number conversion unit 5. Number converter 5 lines, the number of lines of 3D-speed video signal S ₃₂ which is input, for example, performs the line number reduction process of converting from 1080 lines to 540 lines (half). The 3D double-speed video signal S _32a with a reduced number of lines includes a vertical synchronization signal V ₃₂ and a double-speed video signal P _32a with a reduced number of lines. The 3D double-speed video signal S _32a with the reduced number of lines is input to the 3D timing generator 6. The 3D timing generation unit 6 uses a liquid crystal display signal P _32b for controlling the reflective liquid crystal panels 11R, 11G, and 11B and laser light sources 9R and 9G based on the 3D double-speed video signal S _32a in which the number of lines is reduced. , generates the 3D information signal I ₃ laser light source drive signals L ₃ for controlling _9B, and the video to be displayed is a signal indicating whether the left-eye video or right-eye video. The 3D information signal I ₃ is input to the 3D information transmission unit 15, and the liquid crystal display signal P _{32 b} and the laser light source drive signal L ₃ are displayed on the display instruction unit 7 and the laser light source drive as in the case where the two-dimensional processing is selected. Each is input to the unit 8.

  The 3D information transmission unit 15 transmits 3D information to the 3D glasses 16. The 3D glasses 16 switch the state in synchronization with the currently displayed image, and switch the light reaching the eyes. In the first embodiment, the 3D glasses 16 dynamically switch the image that reaches the eyes to one of the left and right images so that the left-eye image enters the left eye and the right-eye image enters the right eye. However, the 3D glasses 16 do not perform dynamic switching, and adopt a method that includes means for switching the polarization direction of light from the display panel according to whether the display image is a left-eye image or a right-eye image in the image display device. You can also In this case, the 3D information output from the 3D information transmission unit 15 is supplied not to the 3D glasses 16 but to a means (not shown) for switching the polarization direction provided in the liquid crystal display device.

  Next, the optical path until the laser light emitted from the laser light sources 9R, 9G, and 9B controlled by the laser light source driving unit 8 is projected onto the screen 14 will be described. The laser light source 9 </ b> R outputs red laser light under the control of the laser light source driving unit 8. The red laser light output from the laser light source 9R is reflected by the red light PBS 10R and applied to the red light reflective liquid crystal panel 11R. The red laser light applied to the red light reflective liquid crystal panel 11R returns from the red light reflective liquid crystal panel 11R to the red light PBS 10R, passes through the red light PBS 10R, and enters the red light incident surface of the cross dichroic prism 12. . The green laser light output from the laser light source 9G is reflected by the green light PBS 10G and applied to the green light reflective liquid crystal panel 11G. The green laser light applied to the green light reflective liquid crystal panel 11G returns from the green light reflective liquid crystal panel 11G to the green light PBS 10G, passes through the green light PBS 10G, and enters the incident surface for green light of the cross dichroic prism 12. . The blue laser light output from the laser light source 9B is reflected by the blue light PBS 10B and applied to the blue light reflective liquid crystal panel 11B. The blue laser light applied to the blue light reflective liquid crystal panel 11B returns from the blue light reflective liquid crystal panel 11B to the blue light PBS 10b, passes through the blue light PBS 10B, and enters the blue light incident surface of the cross dichroic prism 12. . The cross dichroic prism 12 combines the incident red light, green light, and blue light, and outputs the combined light from the emission surface toward the projection lens 13. The combined light is enlarged and projected onto the screen 14 by the projection lens 13, and an image is displayed on the screen 14.

FIG. 3 is a timing chart showing the 2D input video signal S ₂₁ and the 2D double speed video signal S ₂₂ in the 2D double speed conversion unit 2. 2D input video signal _{S 21} includes a vertical synchronizing signal _{V 21} representing the separator frame can be divided into an input video signal _{P 21.} The frequency of the vertical synchronization signal V ₂₁ of the 2D input video signal S ₂₁ is 60 Hz. Frequency of the vertical synchronizing signal _{V 22} of the 2D double-speed video signal _{S 22} is twice the 120Hz frequency of the vertical synchronizing signal _{V 21} of the 2D input video signal _{S 21.} Similar to the vertical synchronizing signal, for the double-speed video signal _{P 22} of the 2D double-speed video signal _{S 22,} which is twice the 120Hz frequency 2D input video signal _{S 21.} In this case, the frame 1a of the double-speed video signal _{P 22} is the same image as the frames of the input video signal _{P 21,} the frame 1b of the double-speed video signal _{P 22} includes a frame 1 of an input video signal _{P 21} input video signal This is an intermediate video generated from the frame 2 of S ₂₁ (for example, generated by interpolation processing). By generating an intermediate frame by doubling the frame frequency, motion blur in the reflective liquid crystal panels 11R, 11G, and 11B can be reduced.

FIG. 4 is a timing chart showing the 3D input video signal S ₃₁ and the 3D double speed video signal S ₃₂ in the 3D double speed conversion unit 4. In 3D-speed video signal _{S 32} in FIG. 4, frame 1L, frame 2L, frame 3L, ... is a left-eye video signal, frame 1R, frame 2R, frame 3R, ... is a right-eye video signal. Similarly to the 2D input video signal S ₂₁ , the 3D input video signal S ₃₁ can also be divided into a vertical synchronization signal V ₃₁ representing a frame break and an input video signal P ₃₁ . In double speed conversion processing in 3D for rate conversion section 4, a vertical synchronizing signal _{V 31} of the 3D input video signal _{S 31} of 60Hz are converted to 120Hz of the vertical synchronizing signal _{V 32,} the input video signal of the 3D input video signal _{S 31} of 60Hz P ₃₁ is converted to a 120Hz double speed video signal _{P 32.} When converting the video signal, the 3D double speed conversion unit 4 extracts the left-eye video signal portion and the right-eye video signal portion from each frame, and converts the left-eye video signal frame and the right-eye video signal into frames. Outputs alternately to generate a 120 Hz signal. As shown in FIG. 4, 3D for double speed conversion unit 4, for example, generates a frame 1L and frame 1R of 3D-speed video signal _{S 32} from the frame 1 of the 3D input video signal _{S 31,} similarly, 3D input below by generating one of the left and right frames of the 3D-speed video signal S ₃₂ from the frame of the video signal S _31, it generates a 120Hz video signal arranged right and left of the frame alternately.

FIG. 5 is an explanatory diagram illustrating the line number conversion process performed by the line number conversion unit 5 and the process performed by the 3D timing generation unit 6. The line number conversion processing, the number of lines of the video signal P ₃₂ of 3D-speed video signal S ₃₂ which is input to the line number converter 5 from the 1080 lines, into a 540 line half. In FIG. 5, line numbers 1 to 1080 given to the video signal P ₃₂ of the 3D double speed video signal S ₃₂ represent lines in the horizontal scanning direction from the first line to the 1080th line in one frame. In FIG. 5, numbers 1 a to 540 a are line numbers given to the converted video signal, and represent lines in the horizontal scanning direction from the first line to the 540th line in one frame. Since the number of lines in the video signal P _32a after the line number conversion processing is halved, a time gap is formed in the frame. This gap is prepended by the 3D timing generator 6. As a process for generating the video data of the line numbers 1a, 2a,... By the 3D timing generation unit 6, for example, the first line and the second line of the video signal before conversion are reduced in order to reduce the delay. You may use the process using the filter which produces | generates the line of the line number 1a from the line of eyes. When generating one line, if the number of lines to be referenced is increased, the processing time is increased and the time delay is increased, but the conversion process can be performed while suppressing the reduction of the video quality. The video signal converted to 540 lines per frame is input to the 3D timing generator 6. In the first embodiment, a case where the number of lines in one frame is converted to a half number of lines will be described. However, the number of lines can be reduced to another number such as a third number of lines. Also good. If the number of lines after conversion is small, there is an advantage that the laser lighting time described later can be lengthened and the image can be brightened, but the image quality is lowered instead.

FIG. 6 is a timing diagram illustrating processing performed by the 2D timing generation unit 3 according to the first embodiment. FIG. 6 shows the 2D double-speed video signal S ₂₂ , the liquid crystal display signal P _22a , and the laser light source drive signal L _{2 in the first} embodiment. Video signal _{P 22} of the 2D double-speed video signal _{S 22} which is input, the reflective liquid crystal panel 11R, 11G, to the extent that 11B can correspond, as a liquid crystal display signal _{P 22a,} as packaged in temporally previous in one frame period (That is, the transfer clock is speeded up). The reason is that the data is written to the display panel after receiving the liquid crystal display signal P _22a due to the characteristics of the reflective liquid crystal panels 11R, 11G, and 11B. This is because a long response time is required. The generated liquid crystal display signal P _{22 a} is input to the display instruction unit 7. On the other hand, the laser light source driving signals L ₂ generates a timing signal for continuously emitting a laser beam. The generated laser light source driving signal L ₂ is input to the laser light source driving unit 8.

FIG. 7 is a timing diagram illustrating processing performed by the 3D timing generation unit 6 according to the first embodiment. FIG. 7 shows the 3D double speed video signal S ₃₂ , the liquid crystal display signal P _32a , the laser light source drive signal L ₃ , and the 3D information signal I ₃ in the first embodiment. The 3D timing generator 6 uses the input video signal P _32a of the 3D double-speed video signal to _adjust the time gap between lines generated at the time of conversion in the line number converter 5 to the front of the video signal P _32a. In addition, the liquid crystal display signal P _{32b is set} to the front of the reflective liquid crystal panels 11R, 11G, and 11B (that is, processing for increasing the transfer clock). It is sent to the display instruction unit 7. (In the first embodiment, halved and then) the number of lines is reduced by being converted by the line number converter 5 since the validity period T ₀ per frame of the liquid crystal display signal P _{32 b} is, 2D This is shorter than the effective period per frame of the liquid crystal display signal P _22a generated by the timing generation unit 3 for use. This makes it possible to increase the reflection-type liquid crystal panels 11R, 11G, after the response time T ₁ has elapsed the provisions of 11B, the duration T ₂ of the up liquid crystal display signal of the next frame is enabled.

On the other hand, the laser light source drive signals L ₃ is a reflective liquid crystal panels 11R, 11G, after the response time T ₁ has elapsed the provisions of 11B (i.e., the display after the completion of the display panel) liquid crystal display signal of the next frame from the enabled a signal for the effective period T ₂ the time to. By doing so, crosstalk between the left-eye video and the right-eye video can be prevented. A laser light source 9R after the elapse of the response time T ₁ of the provision, the reason for lighting 9G, a 9B is as follows. The response times of the reflective liquid crystal panels 11R, 11G, and 11B are not always constant, and the response speed varies depending on the difference between the value before rewriting and the value after rewriting. Therefore, the laser light source 9R without waiting for the response course of time T ₁ of the predetermined prescribed, 9G, and light up the 9B, the reflective liquid crystal panels 11R, 11G, regions and response time begins rewritten 11B of previously There is a possibility that display unevenness occurs between an area that is a fast change pattern and an area other than such an area. Also, the reason for the period until the liquid crystal display signal of the next frame is enabled valid period T ₂ are as follows. Long laser source 9R than the effective period T _2, 9G, and light up the 9B, will overlap a portion of the display image of the next frame on the display image of the current frame, the crosstalk of the left-eye image and right-eye video is generated To do.

In addition, since the laser light sources 9R, 9G, and 9B are intermittently lit during the stereoscopic image processing, even if the lighting time is ensured as long as possible, the display image becomes dark compared to the two-dimensional image processing in which the laser light source is continuously lit. Therefore, the laser light source driving unit 8 may be configured to control not only the lighting timing of the laser light sources 9R, 9G, and 9B but also the outputs of the laser light sources 9R, 9G, and 9B. When the laser light sources 9R, 9G, and 9B are used, there is an advantage that intermittent lighting and fine control of the output intensity are easy, so that the brightness equivalent to that at the time of 2D video processing can be obtained at the time of stereoscopic video processing. It is possible to control to increase the output temporarily. In order to increase the output of the laser light sources 9R, 9G, and 9B, it is necessary to increase the power supply capability of the power supply device that supplies power to the laser light source. In the first embodiment, the number of lines is changed by the line number conversion unit 5. Thus, it is possible to ensure a long lighting time of the laser light sources 9R, 9G, and 9B, so that it is not necessary to significantly increase the outputs of the laser light sources 9R, 9G, and 9B. By performing such control, it is possible to minimize the reduction in brightness that becomes a problem when the laser light sources 9R, 9G, and 9B are intermittently turned on. The generated laser light source driving signal L ₃ is input to the laser light source driving unit 8.

Also, 3D timing generator 6 generates 3D information signal _{I 3.} The 3D information signal I ₃ is a signal indicating whether the currently displayed image is a left-eye image or a right-eye image. In the 3D information signal I ₃ in FIG. 7, a portion described as R means a frame of the right-eye video signal, and a portion described as L means a frame of the left-eye video signal. Since the image displayed on the display panel is projected on the screen 14 after being irradiated with the laser beam, the 3D information signal I ₃ is output in conjunction with the laser light source driving signal L ₃ . In the first embodiment, the laser light source driving signal L ₃ and the 3D information signal I ₃ are completely coincident with each other, but the switching reaction speed of the 3D glasses 16 that finally receives the 3D information signal I ₃ is also taken into consideration. Thus, a certain time difference may be provided between them, or the time difference may be variable. The 3D information signal I ₃ is input to the 3D information transmission unit 15.

  The liquid crystal display signal output from the display instruction unit 7 in FIG. 1 and the current display mode (2D / 3D) are input to the display drive unit 21R of the red light reflective liquid crystal panel 11R in FIG. 2, for example. When the current display mode is 2D, that is, two-dimensional video, the display driver 21R designates one corresponding line of the display panel 24R to the gate driver 23R, and can write to the line. To do. On the other hand, the source driver 22R is instructed to write the video data for one line. One image is written on the display panel 24R by controlling the gate driver 23R and the source driver 22R line by line according to the timing of the liquid crystal display signal and sequentially writing them.

  When the current display mode received by the display drive unit 21R from the display instruction unit 7 is a stereoscopic video, the line to be written to the display panel 24R for the gate driver 23R is twice as large as that in the case of two-dimensional display. Two lines are designated, and video data for one line is given to the source driver 22R. As a result, the same data is written in two consecutive lines on the display panel 24R. The reason for writing the same data for two lines is that the number of lines is halved in the line number conversion unit 5 in FIG. 1, and therefore it is necessary to increase the number twice when finally writing data to the display panel 24R. is there. Although the resolution is halved by halving the number of lines, the number of times of writing to the source driver 22R is halved, and the time until the writing to the display panel 24R is completed can be shortened. The other color reflective liquid crystal panels 11G and 11B operate in the same manner.

As described above, in the video display device and video display method according to the first embodiment, the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines eliminate the time gap. Since it is transmitted to the reflective liquid crystal display panels 11R, 11G, and 11B (and further shortened using a faster clock if necessary), the reception time of the video signal can be shortened. In the video display device and the video display method according to the first embodiment, the reflective liquid crystal display panels 11R, 11G, and 11B have the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines. The video signal of each line is duplicated to generate a video signal of multiple lines, and the video is displayed by simultaneously writing the duplicated video signals of the multiple lines to the display panel, thus shortening the writing time to the display panel it can. For this reason, according to the video display device and video display method of the first embodiment, the time T ₂ during which the laser light sources 9R, 9G, and 9B are lit within a range in which crosstalk between the left-eye video and the right-eye video can be prevented. This makes it possible to increase the length of the image, display a bright image, and prevent crosstalk between the left-eye image and the right-eye image. Further, according to the video display device and the video display method of the first embodiment, since it is not necessary to provide a plurality of light sources for each line, there is an effect that it is possible to avoid complication of the configuration.

Embodiment 2. FIG.
FIGS. 8A and 8B show the case where the stereoscopic video signal is an interlace signal in the video display apparatus according to Embodiment 2 of the present invention (that is, the apparatus that performs the video display method according to Embodiment 2). It is explanatory drawing of. In the description of Embodiment 1, the case where the input video signal is a non-interlace signal has been described, but the present invention can also be applied to the case where the input video signal is an interlace signal. The second embodiment is the same as the first embodiment except that the input video signal is a non-interlace signal. Therefore, FIG. 1 is also referred to in the description of the second embodiment.

  Description will be made by paying attention only to the left-eye video of the interlace signal converted to 120 Hz by the 3D double speed conversion unit 4. Considering only the left-eye video out of the 120 Hz 3D double-speed video signal, it can be regarded as a 60 Hz interlace signal. 8A and 8B show line number conversion processing in the line number conversion unit 5 when the left-eye video signal is interlaced, front-end processing in the 3D timing generation unit 6, and red light reflection type liquid crystal. A series of flows regarding a write instruction in the display drive unit 21R in the panel 11R is shown. In the case of an interlaced signal, the number of lines in each field is half of the number of lines in the frame, and therefore thinning out by the line number conversion unit 5 is not necessarily required. In the case of an interlaced signal, the process of reducing the number of lines by the line number conversion unit 5 is, for example, a process (shown in FIG. 8A) using a top field and a bottom field video signal.

  Patterns A1 and A2 shown in FIGS. 8A and 8B are display patterns between the top field and the bottom field where line flicker is inconspicuous by two-line writing. Black circles and white circles in the top field and the bottom field indicate that the corresponding lines are black or white video data, respectively. The red light reflection type liquid crystal panel 11R performs two-line writing (processing for copying lines). The green light reflection type liquid crystal panel 11G and the blue light reflection type liquid crystal panel 11B perform the same process as the red light reflection type liquid crystal panel 11R.

  As described above, according to the video display device and the video display method according to the second embodiment, the same effect as in the first embodiment can be obtained.

Embodiment 3 FIG.
FIGS. 9A and 9B show the case where the stereoscopic video signal is an interlace signal in the video display apparatus according to Embodiment 3 of the present invention (that is, the apparatus that performs the video display method according to Embodiment 3). It is explanatory drawing of. In the third embodiment, in addition to the second embodiment, measures are taken to reduce line flicker. Except for this point, the third embodiment is the same as the second embodiment.

  In the second embodiment, as shown in the pattern A2 shown in FIG. 8B, the line in which the video data changes from black to white is different from the third line in the top field and the second line in the bottom field. In some cases, line flicker may become prominent. This is because, as indicated by reference numeral 40 in FIG. 8B, the portion generated from the second line of the top field by the process of duplicating the line in the reflective liquid crystal panel and simultaneously writing the two lines on the display panel is This is because the portion generated from the second line of the black and bottom field is white, and the portion blinking black and white for each field is generated in units of two lines.

  Therefore, in the third embodiment, as shown in FIGS. 9A and 9B, when the display drive unit 21R in the red light reflection type liquid crystal panel 11R issues a write instruction, the top line of the bottom field is set. Instead of copying to 2 lines, data is written to the display panel by copying to 3 lines. Although not shown in FIGS. 9A and 9B, the last line of the bottom field is written into the display panel with one line instead of being duplicated into two lines. By such a display method, as indicated by reference numeral 42 in the pattern B2 of FIG. 9B, the black and white flashing line for each field becomes one line, and the black and white flashing line for each field. The line flicker is halved compared to the case of FIG.

  However, as indicated by reference numeral 41 in the pattern B1 in FIG. 9A, even if the line flicker has not occurred in the pattern A1 in FIG. However, in the case of FIGS. 8A and 8B in which there are places where line flicker is extremely noticeable (two-line line flicker) and places where no line flicker occurs, the difference between the lines is conspicuous. The feeling of discomfort is thought to increase. For this reason, it is considered that the conversion method shown in FIGS. 9A and 9B which allows a small line flicker as a whole is preferable.

  As described above, according to the video display device and the video display method according to the third embodiment, in addition to the same effects as in the second embodiment, the effect that the line flicker can be made inconspicuous is obtained. Can do.

Embodiment 4 FIG.
FIGS. 10A and 10B show the case where the stereoscopic video signal is an interlace signal in the video display apparatus according to Embodiment 4 of the present invention (that is, the apparatus that performs the video display method according to Embodiment 4). It is explanatory drawing of. In the fourth embodiment, measures to further reduce line flicker are taken in addition to the third embodiment. Except for this point, the fourth embodiment is the same as the third embodiment.

  10A and 10B, black circles indicate pixels with the lowest gradation level, cross-hatched circles indicate pixels with the lowest gradation level (first intermediate gradation), and unidirectional diagonal lines The hatched circle indicates a pixel whose gradation level is lower than the first gradation level and has the second highest gradation level (second intermediate gradation), and the white circle has the highest gradation level. Indicates a pixel. In the fourth embodiment, as shown in FIGS. 10A and 10B, when black pixels and white pixels are adjacent to each other in the vertical scanning direction in the top field or the bottom field, the adjacent black pixels are changed to the first black pixels. Are converted to first intermediate gradation first pixels (reference numerals 51 and 52), and adjacent white pixels are converted to second intermediate gradation second pixels (reference numerals) lower in gradation level than the first intermediate gradation. 53 and 54) is further provided with a filtering means (not shown) for performing the filtering process. This filter means (not shown) is provided in the line number conversion unit 5, for example. However, the filter unit (not shown) may be provided in the 3D timing generation unit 6 so that the filter process is performed after the front-end process is performed on the video signal with the reduced number of lines.

  By performing the filtering process, the portion that switches from white to black or from black to white in the vertical scanning direction is expressed by a halftone color (reference numerals 43 and 44 in FIG. 10A and in FIG. 10B). 45, 46), the line flicker between the top field and the bottom field can be made more inconspicuous. However, since the change from white to black or from black to white is displayed smoothly, the resolution is lowered. Therefore, the operation mode may be configured to be switchable depending on whether the line flicker is made more inconspicuous or the reduction in resolution is emphasized.

  As described above, according to the video display device and the video display method according to the fourth embodiment, in addition to the same effects as in the second and third embodiments, the effect that the line flicker can be made less noticeable. Can be obtained.

  In addition, the display method for generating intermediate grayscale pixels in the fourth embodiment is also applicable to the first and second embodiments.

1 is a block diagram schematically showing a configuration of a video display device according to Embodiment 1 of the present invention (that is, a device that performs a video display method according to Embodiment 1). FIG. FIG. 2 is a block diagram schematically showing the configuration of the reflective liquid crystal panel shown in FIG. 1. 3 is a timing diagram illustrating a 2D input video signal and a 2D double-speed video signal in Embodiment 1. FIG. 3 is a timing diagram illustrating a 3D input video signal and a 3D double-speed video signal according to Embodiment 1. FIG. 6 is an explanatory diagram illustrating a process performed by a line number conversion unit and a process performed by a 3D timing generation unit in Embodiment 1. FIG. 6 is a timing diagram illustrating processing performed by a 2D timing generation unit according to Embodiment 1. FIG. 6 is a timing diagram illustrating processing performed by the 3D timing generation unit according to Embodiment 1. FIG. (A) And (b) is the description in the case where the stereoscopic video signal is an interlace signal in the video display device according to the second embodiment of the present invention (that is, the device that performs the video display method according to the second embodiment). FIG. (A) And (b) is the description in the case where the stereoscopic video signal is an interlace signal in the video display apparatus according to the third embodiment of the present invention (that is, the apparatus that performs the video display method according to the third embodiment). FIG. (A) And (b) is the description in the case where the stereoscopic video signal is an interlace signal in the video display device according to the fourth embodiment of the present invention (that is, the device that performs the video display method according to the fourth embodiment). FIG.

Explanation of symbols

  1 2D / 3D switching section, 2 2D double speed conversion section, 3 2D timing generation section, 4 3D double speed conversion section, 5 line number conversion section, 6 3D timing generation section, 7 display instruction section, 8 laser light source drive 9R red light source, 9G green light source, 9B blue light source, 10R red light PBS, 10G green light PBS, 10B blue light PBS, 11R red light reflection liquid crystal panel, 11G green light reflection liquid crystal panel 11B Blue light reflection type liquid crystal panel, 12 Cross dichroic prism, 13 Projection lens, 14 Screen, 15 3D information transmission unit, 16 3D glasses, 21R display drive unit, 22R source driver, 23R gate driver, 24R display panel.

Claims (15)

In a video display device that alternately displays a left-eye video and a right-eye video of a stereoscopic video in a time-sharing manner,
Display means including a display panel for displaying video;
Illumination means for irradiating the display panel with light;
Line number conversion means for receiving a left-eye video signal and a right-eye video signal, and reducing the number of lines in one frame of the left-eye video signal and the number of lines in one frame of the right-eye video signal;
Timing generating means for generating a display timing signal and an irradiation timing signal based on the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines;
The display means alternately supplies the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines at a timing synchronized with the display timing signal for each frame. Display instruction means;
The illumination means has illumination drive means for executing the light irradiation at a timing synchronized with the irradiation timing signal for each frame.
The display means duplicates the video signal of each line of the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines supplied from the display instruction means. A video display device that generates video signals of lines and displays the video by simultaneously writing the duplicated video signals of a plurality of lines to the display panel.   The irradiation timing signal is a signal indicating a period from a point in time when a video signal in a certain frame is written on the display panel and a video is displayed on the display panel to immediately before the start of the next frame. Item 2. The video display device according to Item 1.   The video display apparatus according to claim 1, wherein the process of reducing the number of lines is a process of thinning out even lines or odd lines.   4. The video display device according to claim 1, wherein the display unit is a reflective liquid crystal display unit. The illumination means includes a laser light source,
5. The video display device according to claim 1, wherein the light emitted by the illuminating unit is laser light emitted from the laser light source. 6. The illumination means includes a light emitting diode,
The video display device according to any one of claims 1 to 4, wherein the light emitted by the illumination unit is light emitted from the light emitting diode. The process in which the line number conversion means reduces the number of lines in one frame is a process to halve the number of lines,
The process in which the display unit duplicates the video signal of each line to generate a video signal of a plurality of lines is a process of duplicating the video signal of one line into a video signal of two lines. 7. The video display device according to any one of 1 to 6. Each of the left-eye video signal and the right-eye video signal is an interlace signal constituting one frame from a top field and a bottom field,
8. The process of generating a plurality of video signals by duplicating the video signal of each line by the display means, wherein only the first line of the bottom field is duplicated into a three-line video signal. The video display device described.   When a black pixel and a white pixel are adjacent to each other in the vertical scanning direction in the top field or the bottom field, the adjacent black pixel is converted to a first pixel of a first intermediate gradation, and the adjacent white pixel is 9. The video display device according to claim 8, further comprising a filter unit that converts the second intermediate gradation second pixel having a gradation level lower than that of the first intermediate gradation. In a video display method for alternately displaying a left-eye video and a right-eye video in a stereoscopic manner in a time-sharing manner,
A line number converting means for receiving the left-eye video signal and the right-eye video signal, and reducing the number of lines in one frame of the left-eye video signal and the number of lines in one frame of the right-eye video signal;
A timing generation unit that generates a display timing signal and an irradiation timing signal based on the left-eye video signal in which the number of lines is reduced and the right-eye video signal in which the number of lines is reduced;
Display means including a display panel for displaying video, for each frame, at the timing synchronized with the display timing signal, the left-eye video signal with the reduced number of lines and the right-eye with the reduced number of lines By alternately receiving video signals, the video signal for each line of the left-eye video signal with the reduced number of lines and the right-eye video signal with the reduced number of lines is duplicated to generate a video signal of multiple lines And displaying the video by simultaneously writing the duplicated video signals of the plurality of lines to the display panel;
And a step of irradiating the display panel with light at a timing synchronized with the irradiation timing signal for each frame.   The irradiation timing signal is a signal indicating a period from a time point when a video signal in a certain frame is written to the display panel and a video is displayed on the display panel to immediately before the start of the next frame. Item 11. The video display method according to Item 10.   12. The video display method according to claim 10, wherein the process of reducing the number of lines is a process of thinning out even lines or odd lines. The process in which the line number conversion means reduces the number of lines in one frame is a process to halve the number of lines,
The process in which the display unit duplicates the video signal of each line to generate a video signal of a plurality of lines is a process of duplicating the video signal of one line into a video signal of two lines. 13. The video display method according to any one of 10 to 12. Each of the left-eye video signal and the right-eye video signal is an interlace signal constituting one frame from a top field and a bottom field,
14. The process of generating a plurality of video signals by duplicating the video signal of each line by the display means, wherein only the first line of the bottom field is duplicated into a three-line video signal. The video display method described.   When a black pixel and a white pixel are adjacent to each other in the vertical scanning direction in the top field or the bottom field, the adjacent black pixel is converted to a first pixel of a first intermediate gradation, and the adjacent white pixel is 15. The video display method according to claim 14, wherein conversion is performed to a second pixel of a second intermediate gradation having a gradation level lower than that of the first intermediate gradation.

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