JP2011053707A - Stereoscopic video display device and stereoscopic video display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stereoscopic video display device and a stereoscopic video display method, wherein, in alternately displaying two kinds of videos for a stereoscopic view through the use of a technology to control the light emission amount of each of a plurality of light sources constituting a backlight in accordance with partial contrast of a display video in the same screen, the light emission amount of each of the light sources is appropriately controlled so that the display video may not become dark, thereby having improved video quality. <P>SOLUTION: The stereoscopic video display device includes a display panel, an illumination means, an acquisition means and a control means. The illumination means is configured to irradiate the display panel with illumination light from the rear side of the display panel by means of the plurality of light sources arrayed according to the surface of the display panel for alternately displaying the first and second videos. The acquisition means is configured to, in each of a plurality of areas obtained by dividing the display panel surface in accordance with the plurality of light sources, acquire the greater luminance value, that is, the maximum luminance value during the first video display period or the maximum luminance value during the second video display period. The control means is configured to control the light emission amount of the light source in each area on the basis of the luminance value of each of the areas acquired by the acquisition means. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  Embodiments of the present invention relate to an improvement in a stereoscopic video display apparatus and a stereoscopic video display method for displaying a stereoscopic video image by irradiating illumination light from a backlight onto a liquid crystal display panel, for example.

  As is well known, conventionally, development of a technique for allowing a user to recognize a stereoscopic image using a flat image display screen has been advanced. This technology prepares two types of images having parallax corresponding to the distance between both eyes of a human and makes a right eye image visible to the user's right eye and a left eye image to be viewed by the user's left eye. Is to do.

  Specifically, the right-eye video and the left-eye video are alternately displayed on the same video display screen, and when the right-eye video is displayed on the stereoscopic glasses worn by the user, the left-eye shutter is opened. There is a technique for allowing a user to recognize a stereoscopic image by controlling to close the right eye shutter when the left eye image is closed.

  On the other hand, in recent years, video display devices using a liquid crystal display panel for displaying video have been rapidly spread. This type of image display device displays an image by transmitting illumination light from a backlight whose light source is, for example, a cold cathode tube such as a fluorescent tube or a discharge lamp, from the back side of the liquid crystal display panel. Yes.

  At present, the backlight is composed of a plurality of light sources, and the amount of light emitted from each light source is controlled in accordance with the partial brightness of the display image in the same screen, so that the dark portion in the same screen becomes darker. A so-called local dimming technique has been developed in which bright portions are brightened to increase contrast.

  For this reason, as a matter of course, it has been considered to display a stereoscopic video using a video display device to which local dimming technology is applied. By the way, such a local dimming technique is still in the development stage, and there is still a lot of room for improvement in various points when used for displaying images for stereoscopic viewing.

  For example, the right-eye video and the left-eye video that are alternately displayed for stereoscopic viewing have parallax with each other, and therefore the same subject exists when comparing small areas at the same position on the screen There are cases where it does not exist. In this case, assuming that the luminance of the subject is high, a high-luminance video and a low-luminance video are alternately displayed in the small area.

  Here, the light emission amounts of a plurality of light sources constituting the backlight will be considered. In other words, the light source that illuminates the small area with the illumination light is controlled so that the light emission amount is increased (brighter) when displaying the image in which the subject is present, and the light amount is decreased (darker) when the image without the subject is displayed. ) To be controlled.

  However, the amount of light emitted from the plurality of light sources constituting the backlight is recognized by the user that the light emission status of each light source sequentially changes in accordance with the movement of the display image when displaying a normal moving image. In order to prevent this, it is controlled so as to change gradually in the time axis direction.

  For this reason, the light source that illuminates the small area with the illumination light emits light with a light emission amount approximately halfway between the light emission amount when displaying an image in which the subject is present and the light emission amount when displaying an image without the subject. As a result, the display image is dark and the user feels that the display image is dark.

JP 2007-279395 A JP 2008-268396 A

  Using a technique for controlling the light emission amounts of a plurality of light sources that constitute the backlight according to the partial brightness of the display image within the same screen, two types of images having parallax are displayed alternately and displayed in three dimensions. An object of the present invention is to provide a stereoscopic video display device and a stereoscopic video display method capable of improving the image quality by appropriately controlling the light emission amount of each light source so that the display video does not become dark when viewing. And

  According to the embodiment, the stereoscopic video display apparatus includes a display panel, illumination means, acquisition means, and control means. The display panel displays the first and second images alternately. The illumination means has a plurality of light sources arranged corresponding to the display panel surface, and irradiates the display panel with illumination light from the back side. The obtaining unit displays the maximum luminance value and the second image when the first image is displayed for each of a plurality of areas obtained by dividing the display panel surface in correspondence with the plurality of light sources constituting the illumination unit. The larger one of the maximum luminance values is acquired. The control unit controls the light emission amount of the light source corresponding to each area based on the luminance value in each of the plurality of areas acquired by the acquisition unit.

The block block diagram shown in order to demonstrate the signal processing system of the stereoscopic vision video display in embodiment. The figure shown in order to demonstrate operation | movement of the serialization process part which comprises the stereoscopic vision video display in the same embodiment. The timing diagram shown in order to demonstrate the relationship between the video for right eyes and left eyes displayed on the stereoscopic video display in the same embodiment, and the shutter control of the glasses for stereoscopic vision. The top view shown in order to demonstrate an example of the liquid crystal display panel which comprises the stereoscopic vision video display in the embodiment. The top view shown in order to demonstrate an example of the backlight which comprises the stereoscopic vision video display apparatus in the embodiment. The side view shown in order to demonstrate the relationship between the liquid crystal display panel and backlight which comprise the stereoscopic vision video display in the embodiment. The block block diagram shown in order to demonstrate an example of the backlight control part which comprises the stereoscopic vision video display in the embodiment. The block block diagram shown in order to demonstrate an example of all the area maximum value memory | storage parts and control value memory | storage part which comprise the backlight control part in the embodiment. The block block diagram shown in order to demonstrate an example of LPF which comprises the backlight control part in the embodiment. The characteristic view shown in order to demonstrate the filtering process of the time-axis direction of LPF in the embodiment. The figure shown in order to demonstrate the image | video for right eyes and the lighting state of a backlight which are displayed with the stereoscopic vision video display in the embodiment. The figure shown in order to demonstrate the image | video for left eyes displayed with the stereoscopic vision video display in the same embodiment, and the lighting state of a backlight. The figure shown in order to demonstrate the image | video produced | generated with the stereoscopic vision video display in the same embodiment, and the lighting state of a backlight. The block block diagram shown in order to demonstrate the modification of the stereoscopic vision video display in the embodiment. The timing diagram shown in order to demonstrate an example of the operation | movement which the modification of the stereoscopic vision video display in the embodiment performs. The timing diagram shown in order to demonstrate the other example of the operation | movement which the modification of the stereoscopic vision video display in the same embodiment performs.

  Hereinafter, embodiments will be described in detail with reference to the drawings. FIG. 1 shows a signal processing system of a stereoscopic video display 11 described in this embodiment. The stereoscopic video display 11 includes two input terminals 12 and 13.

  Among these, as shown in FIG. 2A, a right-eye video signal for forming a right-eye video having a frame period of 1/60 seconds is input to one input terminal 12. Further, as shown in FIG. 2B, the other input terminal 13 receives a left-eye video signal for forming a left-eye video having a frame period of 1/60 seconds.

  The right-eye video signal and the left-eye video signal can be acquired by receiving, for example, a broadcaster broadcast as a stereoscopic video signal. Further, it can be acquired from a content provider via a network or the like, or can be reproduced from a recording medium such as an optical disk.

  The right-eye and left-eye video signals supplied to these input terminals 12 and 13 are supplied to the serialization processing unit 14. The serialization processing unit 14 converts the right-eye and left-eye video signals supplied to the input terminals 12 and 13 in units of one frame so that the frame period is 1/120 seconds as shown in FIG. Are alternately arranged and output. The video signal output from the serialization processing unit 14 is supplied to the liquid crystal display panel control unit 15 and the backlight control unit 16, respectively.

  Among these, the liquid crystal display panel control unit 15 writes video signals corresponding to one frame output from the serialization processing unit 14 to a plurality of pixels constituting the liquid crystal display panel 17 in the subsequent stage. The display image for one frame is formed on the liquid crystal display panel 17.

  Further, the backlight control unit 16 controls a backlight 19 in the subsequent stage that causes the liquid crystal display panel 17 to irradiate illumination light from the back side to display an image. That is, the backlight control unit 16 corresponds to the partial luminance of the display image for one frame formed on the liquid crystal display panel 17 based on the video signal output from the serialization processing unit 14. A light emission amount control value for controlling the light emission amounts (brightness) of a plurality of light sources constituting the backlight 19 is calculated.

  The light emission amount control value calculated by the backlight control unit 16 is supplied to the backlight driving unit 18. The backlight drive unit 18 controls the light emission amounts of a plurality of light sources constituting the backlight 19 based on the light emission amount control value supplied from the backlight control unit 16, and applies the local dimming technique to the backlight drive unit 18, respectively. The displayed video is displayed.

  The liquid crystal display panel control unit 15 is supplied with the light emission amount control value calculated by the backlight control unit 16. Then, the liquid crystal display panel control unit 15 performs a correction process on the video signal output from the serialization processing unit 14 based on the light emission amount control value calculated by the backlight control unit 16, and the liquid crystal display panel 17 is output.

  Further, the serialization processing unit 14 outputs a signal indicating the timing of alternately outputting the right-eye and left-eye video signals in units of one frame to the spectacles control unit 20. The eyeglass control unit 20 generates a right eye shutter control signal and a left eye shutter control signal for the stereoscopic eyeglasses 21 worn by the user based on the timing signal supplied from the serialization processing unit 14. is doing.

  That is, the glasses control unit 20 closes the left-eye shutter of the stereoscopic glasses 21 when the right-eye video is displayed, and closes the right-eye shutter of the stereoscopic glasses 21 when the left-eye video is displayed. Thus, the user is made to recognize the stereoscopic video.

  FIG. 3 shows the relationship between the right-eye and left-eye images displayed on the liquid crystal display panel 17 and the right-eye and left-eye shutter control of the stereoscopic glasses 21. That is, the right-eye video signals R1, R2,... Having a frame period of 1/60 seconds as shown in FIG. 3A are supplied to the input terminal 12, and the input terminal 13 is supplied with FIG. Assume that left-eye video signals L1, L2,... Having a frame period of 1/60 seconds are supplied.

  Then, as shown in FIG. 3C, the serialization processing unit 14 alternately outputs the right-eye video signal and the left-eye video signal with a frame period of 1/120 seconds, and based on this, the liquid crystal The right-eye video and the left-eye video are alternately displayed on the display panel 17.

  Then, as shown in FIG. 3D, the spectacles controller 20 opens the right eye shutter of the stereoscopic glasses 21 at the H (high) level at the timing when the right eye image is displayed. At the timing when the left-eye video is displayed, the right-eye shutter control signal for closing the right-eye shutter of the stereoscopic glasses 21 is output at the L (low) level.

  Further, as shown in FIG. 3E, the eyeglass control unit 20 becomes H level at the timing when the left-eye video is displayed, and the left-eye shutter of the stereoscopic glasses 21 is opened, and the right-eye video is displayed. The left-eye shutter control signal for closing the left-eye shutter of the stereoscopic glasses 21 is output at the L level at the timing when is displayed.

  Here, FIG. 4 shows an example of the liquid crystal display panel 17. That is, the liquid crystal display panel 17 is configured by arranging a plurality of pixels 22 each of which is a liquid crystal cell in a matrix in the horizontal direction and the vertical direction. In this case, the panel surface of the liquid crystal display panel 17 is divided into a plurality (j × k) areas 23 of j pieces in the horizontal direction and k pieces in the vertical direction. Each area 23 includes a plurality (n × m) of pixels 22 each including n in the horizontal direction and m in the vertical direction.

  FIG. 5 shows an example of the backlight 19. That is, the backlight 19 has a plurality of (j × k) light sources 24 arranged in a matrix form with j pieces in the horizontal direction and k pieces in the vertical direction corresponding to each area 23 of the liquid crystal display panel 17. It is configured to be. Each of these light sources 24 is composed of, for example, an LED (light emitting diode).

  More specifically, as shown in FIG. 6, the backlight 19 has j light sources 24 composed of a white LED array or the like arranged in the horizontal direction and k light sources arranged in the vertical direction, and each light source 24 is reflected by the reflection plate 25. The diffusion plate 26 is disposed on the light irradiation surface so that uniform light irradiation can be performed in units of areas 23. The backlight 19 is placed on the back side of the liquid crystal display panel 17, and the liquid crystal display panel 17 is irradiated with light from the back side to display an image.

  FIG. 7 shows an example of the backlight control unit 16. The backlight control unit 16 includes input terminals 27, 28, and 29 to which R (red), G (green), and B (blue) video signals output from the serialization processing unit 14 are supplied. . The R, G, B signals supplied to the input terminals 27 to 29 are supplied to the luminance conversion unit 30 and converted into the luminance signal Y.

  The luminance signal Y output from the luminance conversion unit 30 is supplied to the n pixel maximum value detection unit 31. The n pixel maximum value detection unit 31 detects the maximum luminance value for every n pixels, that is, for each area 23, from a plurality of (n × j) pixels constituting one horizontal line. And output to one input terminal of the comparison unit 32.

  The n pixel maximum value detection unit 31 detects the maximum luminance value for each of j areas for one horizontal line, and then detects the plurality of (n × j) pixels constituting the next horizontal line. The operation of detecting the maximum luminance value is repeated every n pixels from the inside, that is, for each area 23.

  Further, the luminance value stored in the j area maximum value storage unit 33 is supplied to the other input terminal of the comparison unit 32. The j area maximum value storage unit 33 has a luminance maximum value storage area corresponding to j areas 23 arranged in the horizontal direction. The comparison unit 32 then supplies the maximum luminance value of the predetermined area 23 supplied from the n pixel maximum value detection unit 31 and the maximum luminance value storage area of the j area maximum value storage unit 33 corresponding to the predetermined area 23. The larger value is selected and stored in the same luminance maximum value storage area of the j area maximum value storage unit 33.

  In this case, the luminance value stored in the j area maximum value storage unit 33 to be compared with the maximum luminance value detected from the first horizontal line in each area 23 by the n pixel maximum value detection unit 31 is set to 0, and thereafter The comparison result obtained by the comparison unit 32 in the same area 23 is stored in the luminance maximum value storage area of the corresponding area 23 of the j area maximum value storage unit 33.

  Thereby, when the detection process of the maximum value of luminance is completed for each of j areas for the m horizontal lines by the n pixel maximum value detection unit 31, during the detection process, the comparison unit 32 The maximum luminance value in each of the j areas 23 in the horizontal direction is output.

  In this way, the maximum luminance value in each of the j areas 23 in the horizontal direction output from the comparison unit 32 is written in the all area maximum value storage unit 34.

  By repeating the above operation k times in the vertical direction, the maximum luminance value in all the j × k areas 23 of the liquid crystal display panel 17 is obtained and written in the all area maximum value storage unit 34.

  The maximum brightness value in all areas 23 written in the all area maximum value storage unit 34 is subjected to filtering in the time axis direction by an LPF (low pass filter) 35, and then the backlight 19 is turned on. It is written in the control value storage unit 36 as a light emission amount control value for controlling the light emission amounts of a plurality of (j × k) light sources 24 constituting the same.

  Thereafter, the light emission amount control value of each light source 24 written in the control value storage unit 36 is supplied to the backlight driving unit 18 via the output terminal 37.

  The LPF 35 performs a filtering process on the maximum luminance value supplied from the all area maximum value storage unit 34 based on the past light emission amount control value written in the control value storage unit 36. .

  FIG. 8 shows an example of the all area maximum value storage unit 34 and the control value storage unit 36. That is, in the all area maximum value storage unit 34, the maximum luminance value of each area 23 output from the comparison unit 32 is supplied to the input terminal 34a. The maximum luminance value supplied to the input terminal 34a is supplied to the writing / reading control unit 34b, and a plurality of j (j in the horizontal direction and k in the vertical direction prepared for each area 23 (j Is stored for each area 23 in the (× k) maximum value storage units 34c.

  In this case, each maximum value storage unit 34c stores the maximum value of the right-eye maximum value storage area 34c1 for storing the luminance value of each area 23 for the right-eye image and the maximum value of the luminance value of each area 23 for the left-eye image. And a left-eye maximum value storage area 34c2.

  Therefore, the right-eye maximum value storage area 34c1 and the left-eye maximum value storage area 34c2 of each maximum value storage section 34c include the right-eye video signal for one frame that is alternately output from the serialization processing section 14. The maximum luminance value of each area 23 in the left-eye video signal is stored together.

  Then, the writing / reading control unit 34b has a larger one of the maximum luminance values stored in the right-eye maximum value storage region 34c1 and the left-eye maximum value storage region 34c2 of each maximum value storage unit 34c. A value is selected and output to the LPF 35 via the output terminal 34d.

  The LPF 35 is arranged in the time axis direction based on the past light emission amount control value written in the control value storage unit 36 with respect to the maximum luminance value for each area 23 output from the all area maximum value storage unit 34. Filtering processing is performed and the result is output to the control value storage unit 36.

  In this case, in the control value storage unit 36, the maximum luminance value of each area 23 output from the LPF 35 is supplied to the input terminal 36a. The maximum luminance value after filtering supplied to the input terminal 36a is supplied to the writing / reading control unit 36b, and is j in the horizontal direction and k in the vertical direction prepared for each area 23. A plurality of (j × k) light emission amount control value storage units 36 c are stored as light emission amount control values for each area 23.

  The writing / reading control unit 36b outputs the light emission amount control value stored in each light emission amount control value storage unit 36c to the backlight drive unit 37 via the output terminal 36d and also outputs it to the LPF 35. is doing. In this case, the backlight drive unit 37 controls the light emission amount of the light source 24 corresponding to each area 23 based on the light emission amount control value read from each light emission amount control value storage unit 36c.

  That is, in the backlight control unit 16 illustrated in FIG. 7, for each of a plurality (j × k) areas 23 obtained by dividing the panel surface of the liquid crystal display panel 17, the maximum luminance value in the right-eye image and the left-eye image are displayed. The maximum value of luminance is acquired. Thereafter, for each area 23, a larger value is selected from the maximum luminance values corresponding to the right eye and the left eye, and the selected luminance value is used to control the light emission amount of the light source 24 corresponding to each area 23. The emission amount control value is

  Here, prior to explaining the reason why the backlight control unit 16 performs the above-described operation, an example of the LPF 35 will be described with reference to FIG. That is, in the LPF 35, the maximum luminance value for each area 23 output from the all area maximum value storage unit 34 is supplied to the input terminal 35a. The maximum luminance value supplied to the input terminal 35a is supplied to the multiplication processing unit 35b, multiplied by the coefficient K1 held in the coefficient K1 holding unit 35c, and then applied to one input terminal of the addition processing unit 35d. Supplied.

  In the LPF 35, the light emission amount control value for the light source 24 for each area 23 stored in the control value storage unit 36 is supplied to the input terminal 35e. The light emission amount control value supplied to the input terminal 35e is supplied to the multiplication processing unit 35f, multiplied by the coefficient K2 held in the coefficient K2 holding unit 35g, and then applied to the other input terminal of the addition processing unit 35d. Supplied.

  The addition processing unit 35d adds the luminance value output from the multiplication processing unit 35b and the light emission amount control value output from the multiplication processing unit 35f for the same area 23, and uses the addition result as a new light emission amount. The control value is output to the control value storage unit 36 via the output terminal 35h. Therefore, the control value storage unit 36 writes and holds the new light emission amount control value supplied from the LPF 35 in the light emission amount control value storage unit 36c of the corresponding area 23.

  The operation of the LPF 35 described above will be described with a specific example for one predetermined area 23. When the coefficient K1 is 0.4 and the coefficient K2 is 0.6, when the value supplied to the input terminal 35a changes from 0 to 1, the input value is multiplied by 0.4. At this time, if the light emission amount control value supplied from the corresponding light emission amount control value storage unit 36c of the control value storage unit 36 to the input terminal 35e is 0, the output of the addition processing unit 35d is 0.4. The value is stored as a new light emission amount control value in the corresponding light emission amount control value storage unit 36c of the control value storage unit 36.

  In the next same area 23, 1 which is a value supplied to the input terminal 35a is multiplied by 0.4 by the multiplication processing unit 35b. At this time, the light emission amount control value supplied from the corresponding light emission amount control value storage unit 36c of the control value storage unit 36 to the input terminal 35e is 0.4 stored previously. Therefore, 0.4 output from the multiplication processing unit 35b and 0.24 obtained by multiplying 0.4 supplied to the input terminal 35e by 0.6 by the multiplication processing unit 35f are added by the addition processing unit 35d. As a result, 0.64 is obtained. Then, 0.64 is stored in the corresponding light emission amount control value storage unit 36c of the control value storage unit 36 as a new light emission amount control value.

  By repeating such an operation, as shown by a solid line A in FIG. 10A, when the value supplied to the input terminal 35a changes from 0 to 1, the value output from the LPF 35 is as shown in FIG. As shown by the dotted line B in (a), the characteristic gradually rises, that is, the filtering process is performed in the time axis direction.

  Similarly, when the value supplied to the input terminal 35a changes from 1 to 0, the output value of the LPF 35 has a characteristic of gradually falling.

  Here, FIG. 11A shows a right-eye image displayed on the liquid crystal display panel 17, and FIG. 11B shows light emission of each light source 24 constituting the backlight 19 corresponding to the right-eye image. Indicates the state. 12A shows a left-eye image displayed on the liquid crystal display panel 17, and FIG. 12B shows a light emission state of each light source 24 constituting the backlight 19 corresponding to the left-eye image. Is shown.

  That is, in both the right-eye video and the left-eye video, in the high-luminance (bright) part (the part shown in white in the figure), the corresponding light emission amount of the light source 24 is large (bright) and the luminance is low ( The local dimming technique is adopted so that the light emission amount of the corresponding light source 24 becomes small (dark) in the dark part (the part shown in black in the drawing).

  Here, as described above, the right-eye video and the left-eye video in the stereoscopic video have a parallax corresponding to the interval between the human eyes. That is, as can be seen by comparing the right-eye video shown in FIG. 11 (a) with the left-eye video shown in FIG. 12 (a), the far-away subject (the house in the figure) has a right-eye video and a left-eye video. Although there is no difference in position, a nearby subject (white circle in the figure) appears to the left in the right-eye image and appears to the right in the left-eye image.

  For this reason, when attention is paid to the predetermined area 23a in the right-eye video shown in FIG. 11A, a subject having a high luminance indicated by a white circle in the right-eye video exists in the predetermined area 23a. In the left-eye video, it can be seen that there is no subject with high brightness indicated by a white circle. In terms of the backlight 19, this is controlled so that the light emission amount of the light source 24 at a position corresponding to the predetermined area 23 a is large (bright) when the right-eye video is displayed, and predetermined when the left-eye video is displayed. That is, the light emission amount of the light source 24 at the position corresponding to the area 23a is controlled to be small (dark).

  Since the right-eye video and the left-eye video are alternately displayed in the stereoscopic video, the light emission amount of the light source 24 at the position corresponding to the predetermined area 23a and the light emission are increased. The amount is controlled alternately so that the amount becomes small.

  Therefore, as the right-eye video signal and the left-eye video signal are alternately output from the serialization processing unit 14, the maximum luminance value acquired from the right-eye video for the predetermined area 23a described above. And the maximum luminance value obtained from the left-eye video image are simply supplied to the LPF 35 alternately.

  Then, as indicated by a solid line A in FIG. 10C, the luminance value supplied to the input terminal 35a of the LPF 35 is greatly different between the display time of the right-eye image and the display time of the left-eye image. Become. Then, as described above, the LPF 35 performs a filtering process on the input value in the time axis direction so that the output value is gradually changed in the time axis direction with respect to the input value.

  For this reason, the output value of the LPF 35 is suppressed to a value that is approximately half of the input value as indicated by the dotted line B in FIG. 10C, and the output value of the LPF 35 is stored in the predetermined area 23a. The light emission amount control value controls the light emission amount of the light source 24 at the corresponding position. Thereby, the light emission amount of the light source 24 is not sufficiently increased, and the display image in the predetermined area 23a is felt to be dark by the user.

  Therefore, as in the backlight control unit 16 described above, for a plurality (j × k) areas 23 obtained by dividing the panel surface of the liquid crystal display panel 17, the maximum luminance value in the right-eye image and the left-eye image are respectively obtained. The larger one of the maximum luminance values is selected, and the selected luminance value is output to the LPF 35.

  As shown in FIG. 13 (a), this means that the luminance in each area 23 from the right-eye video shown in FIG. 11 (a) and the left-eye video shown in FIG. 12 (a). It is that the video which took out the higher one was generated. FIG. 13B shows a state in which the light emission amount of each light source 24 constituting the backlight 19 is controlled corresponding to the image shown in FIG.

  In this way, by supplying the larger value of the maximum luminance value in the right-eye video and the maximum luminance value in the left-eye video to the LPF 35, the right-eye video signal of the predetermined area 23a described above is supplied. Even when the maximum luminance value and the maximum luminance value of the video signal for the left eye are greatly different alternately as shown by the dotted line A in FIG. 10B, the luminance value input to the LPF 35 is as shown in FIG. As shown by the solid line B, the larger luminance value is obtained.

  As a result, the output value of the LPF 35 does not drop below the input value even when the filtering process is performed in the time axis direction, as indicated by the dotted line C in FIG. It is possible to sufficiently increase the light emission amount of the light source 24 at the position corresponding to, and to prevent the display image in the predetermined area 23a from being felt dark by the user.

  FIG. 14 shows a modification of the stereoscopic video display 11 described in this embodiment. In FIG. 14, the same parts as those in FIG. 1 are denoted by the same reference numerals, and the right-eye video signal and the left-eye video signal output alternately from the serialization processing unit 14 are supplied to the double frame processing unit 38. is doing. The double frame processing unit 38 functions to output the right-eye video signal and the left-eye video signal that are alternately input twice at a double speed.

  That is, the right-eye video signals R1, R2,... Having a frame period of 1/60 seconds as shown in FIG. 15A are supplied to the input terminal 12, and the input terminal 13 is supplied with FIG. Assume that left-eye video signals L1, L2,... Having a frame period of 1/60 seconds are supplied.

  Then, as shown in FIG. 15C, the serialization processing unit 14 alternately outputs the right-eye video signal and the left-eye video signal with a frame period of 1/120 seconds. As shown in FIG. 15D, the right-eye video signal and the left-eye video signal are alternately output twice each with a frame period of 1/240 seconds.

  In each of FIGS. 15E, 15F, and 15G, the vertical axis indicates the height direction of the screen. Then, as shown in FIG. 15E, the right-eye video signal and the left-eye video signal that are alternately output twice from the double frame processing unit 38 at a frame period of 1/240 seconds are displayed on the liquid crystal display panel 17. Are sequentially written to each frame.

  In this case, the writing of the video signal for one frame to the liquid crystal display panel 17 is sequentially performed from the top to the bottom of the screen by one horizontal line. Therefore, writing to the bottom horizontal line is performed at a time close to the writing start timing for the next frame. Since the liquid crystal is a fold type device, it holds the same signal until the next writing.

  The backlight 19 is turned off for each frame as shown in FIG. In this case, the plurality of light sources 24 constituting the backlight 19 are controlled to be turned on and off for each area 23 in synchronization with the writing of the video signal to the liquid crystal display panel 17.

  Then, the backlight 19 controlled as shown in FIG. 15 (f) illuminates the liquid crystal display panel 17 in which the video signal is written as shown in FIG. 15 (e), and the display shown in FIG. 15 (g). The user visually recognizes the video, that is, the video in which the black screen for one frame is inserted between the right-eye video and the left-eye video alternately displayed with the stereoscopic glasses 21.

  In this case, as shown in FIG. 15 (h), the eyeglass control unit 20 becomes L level at the timing when the black screen and the video for the right eye that follows are displayed, and for the right eye of the stereoscopic glasses 21. The shutter is opened, and at the timing when the black screen and the subsequent left-eye video are displayed, the level becomes H level, and a right-eye shutter control signal for closing the right-eye shutter of the stereoscopic glasses 21 is output.

  Further, as shown in FIG. 15 (i), the eyeglass control unit 20 becomes L level at the timing when the black screen and the subsequent left-eye video are displayed, and opens the left-eye shutter of the stereoscopic glasses 21. Then, at the timing when the black screen and subsequent right-eye video are displayed, the level becomes H level, and the left-eye shutter control signal for closing the left-eye shutter of the stereoscopic glasses 21 is output.

  When the operation described with reference to FIG. 15 is performed, the luminance stored in the maximum value storage area 34c1 for the right eye and the maximum value storage area 34c2 for the left eye of each maximum value storage section 34c constituting the all area maximum value storage section 34. The maximum value of is updated every two frames.

  FIG. 16 shows another operation example of the modification example of the stereoscopic video display 11 shown in FIG. That is, the right-eye video signals R1, R2,... With a frame period of 1/60 seconds as shown in FIG. 16A are supplied to the input terminal 12, and the input terminal 13 is supplied with FIG. Assume that left-eye video signals L1, L2,... Having a frame period of 1/60 seconds are supplied.

  Then, as shown in FIG. 16C, the serialization processing unit 14 alternately outputs the right-eye video signal and the left-eye video signal with a frame period of 1/120 seconds. As shown in FIG. 16D, the right-eye video signal and the left-eye video signal are alternately output with a black screen between each other in a frame period of 1/240 seconds.

  In FIGS. 16 (e), (f), and (g), the vertical axis indicates the height direction of the screen. The right-eye video signal and the left-eye video signal that are alternately output from the double frame processing unit 38 with a frame period of 1/240 seconds with a black screen interposed therebetween are as shown in FIG. The data is sequentially written on the liquid crystal display panel 17 by one frame.

  In this case, the writing of the video signal for one frame to the liquid crystal display panel 17 is sequentially performed from the top to the bottom of the screen by one horizontal line. Therefore, writing to the bottom horizontal line is performed at a time close to the writing start timing for the next frame. Since the liquid crystal is a fold type device, it holds the same signal until the next writing.

  The backlight 19 is turned off for each frame as shown in FIG. In this case, the plurality of light sources 24 constituting the backlight 19 are controlled to be turned on and off for each area 23 in synchronization with the writing of the video signal to the liquid crystal display panel 17.

  Then, the backlight 19 controlled as shown in FIG. 16 (f) illuminates the liquid crystal display panel 17 in which the video signal is written as shown in FIG. 16 (e), and the display shown in FIG. 16 (g). The user visually recognizes the video, that is, the video in which the black screen for one frame is inserted between the right-eye video and the left-eye video alternately displayed with the stereoscopic glasses 21.

  In this case, as shown in FIG. 16 (h), the eyeglass control unit 20 becomes L level at the timing when the black screen and the subsequent right-eye video are displayed, for the right-eye of the stereoscopic glasses 21. The shutter is opened, and at the timing when the black screen and the subsequent left-eye video are displayed, the level becomes H level, and a right-eye shutter control signal for closing the right-eye shutter of the stereoscopic glasses 21 is output.

  In addition, as shown in FIG. 16 (i), the eyeglass control unit 20 becomes L level at the timing when the black screen and the video for the left eye following it are displayed, and the left eye shutter of the stereoscopic glasses 21 is opened. Then, at the timing when the black screen and subsequent right-eye video are displayed, the level becomes H level, and the left-eye shutter control signal for closing the left-eye shutter of the stereoscopic glasses 21 is output.

  As described with reference to FIGS. 15 (g) and 16 (g), by sandwiching a black screen between alternately displayed right-eye video and left-eye video, a clear stereoscopic view with high contrast for the user is provided. It is possible to visually recognize the video.

  Further, in the above-described embodiment, the display of the image using the liquid crystal display panel 17 has been described. However, the image display panel is not limited to the liquid crystal, and the image is displayed using illumination light from the backlight 19 as illumination. If it is a panel, this invention can be applied widely.

  Note that the present invention is not limited to the above-described embodiments as they are, and can be embodied by variously modifying the constituent elements without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above-described embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements according to different embodiments may be appropriately combined.

  DESCRIPTION OF SYMBOLS 11 ... Stereoscopic video display, 12, 13 ... Input terminal, 14 ... Serialization process part, 15 ... Liquid crystal display panel control part, 16 ... Backlight control part, 17 ... Liquid crystal display panel, 18 ... Backlight drive part, DESCRIPTION OF SYMBOLS 19 ... Back light, 20 ... Glasses control part, 21 ... Stereoscopic glasses, 22 ... Pixel, 23, 23a ... Area, 24 ... Light source, 25 ... Reflecting plate, 26 ... Diffusing plate, 27-29 ... Input terminal, 30 ... brightness return part, 31 ... n pixel maximum value detection part, 32 ... comparison part, 33 ... j area maximum value storage part, 34 ... all area maximum value storage part, 34a ... input terminal, 34b ... write / read control part, 34c ... maximum value storage unit, 34c1 ... maximum value storage area for right eye, 34c2 ... maximum value storage area for left eye, 34d ... output terminal, 35 ... LPF, 35a ... input terminal, 35b ... multiplication processing unit, 35c ... coefficient K1 held , 35d ... addition processing unit, 35e ... input terminal, 35f ... multiplication processing unit, 35g ... coefficient K2 processing unit, 35h ... output terminal, 36 ... control value storage unit, 36a ... input terminal, 36b ... write / read control unit, 36c ... Light emission amount control value storage unit 36d... Output terminal 37... Output terminal 38.

Claims (7)

A display panel for alternately displaying the first and second images;
A plurality of light sources arranged corresponding to the display panel surface, and illuminating means for irradiating the display panel with illumination light from the back side;
When the first image is displayed with the maximum luminance value and the second image for each of a plurality of areas obtained by dividing the display panel surface in correspondence with a plurality of light sources constituting the illumination means. Obtaining means for obtaining a larger one of the maximum luminance values of
A stereoscopic video display apparatus comprising: a control unit that controls a light emission amount of the light source corresponding to each area based on a luminance value in each of the plurality of areas acquired by the acquisition unit. The acquisition means includes
For each of a plurality of areas obtained by dividing the display panel surface, first acquisition means for acquiring a maximum luminance value when the first video is displayed;
For each of a plurality of areas obtained by dividing the display panel surface, second acquisition means for acquiring a maximum luminance value when the second video is displayed;
For each of a plurality of areas obtained by dividing the display panel surface, the larger one of the maximum luminance value acquired by the first acquisition unit and the maximum luminance value acquired by the second acquisition unit. The stereoscopic image display apparatus according to claim 1, further comprising selection means for selecting and outputting the image. The acquisition means includes
For each of a plurality of areas obtained by dividing the display panel surface, first acquisition means for acquiring a maximum luminance value when the first video is displayed;
First storage means for storing a maximum value of luminance in each of the plurality of areas acquired by the first acquisition means;
For each of a plurality of areas obtained by dividing the display panel surface, second acquisition means for acquiring a maximum luminance value when the second video is displayed;
Second storage means for storing a maximum value of luminance in each of the plurality of areas acquired by the second acquisition means;
For each of a plurality of areas obtained by dividing the display panel surface, the larger one of the maximum brightness value stored in the first storage means and the maximum brightness value stored in the second storage means The stereoscopic image display apparatus according to claim 1, further comprising selection means for selecting and outputting the image.   The acquisition means detects, for each of a plurality of areas obtained by dividing the display panel surface, a maximum value among luminances of a plurality of pixels for each horizontal line from a plurality of horizontal lines included in the area. The stereoscopic video display apparatus according to claim 1, wherein the largest value among the maximum luminance values of the horizontal lines is selected.   The stereoscopic video display device according to claim 1, wherein a black screen is inserted between the first video and the second video that are alternately displayed on the display panel.   The stereoscopic image display apparatus according to claim 1, wherein the display panel is a liquid crystal display panel, and the light source is an LED. Alternately displaying the first and second images on the display panel;
Irradiating illumination light from the back side of the display panel by illumination means having a plurality of light sources arranged corresponding to the display panel surface,
When the first image is displayed with the maximum luminance value and the second image for each of a plurality of areas obtained by dividing the display panel surface in correspondence with a plurality of light sources constituting the illumination means. Get the larger value of the maximum brightness of
A stereoscopic video display method for controlling the light emission amount of the light source corresponding to each area based on the acquired luminance value in each of the plurality of areas.

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