JP4894358B2 - Backlight drive device, display device, and backlight drive method - Google Patents

Description

  The present invention relates to a display device that displays an image by controlling light transmittance, a backlight driving device used in the display device, and a driving method thereof.

  In a display device that controls the light transmittance and displays an image, for example, a liquid crystal display device, since a pixel of the liquid crystal panel does not emit light, a backlight is disposed on the back side of the liquid crystal panel, and the backlight uses the backlight of the liquid crystal panel. The back is illuminated to display the image.

  Conventionally, in a liquid crystal display device, the entire display screen of the liquid crystal panel is illuminated with uniform brightness by a backlight, the transmittance of each pixel of the liquid crystal panel is controlled, and the shielding amount of light emitted from the backlight is adjusted. Thus, necessary brightness is obtained in each part of the display screen. Therefore, for example, even when the entire display screen is dark, the backlight emits light with substantially the maximum brightness that can be set, and there is a problem that the backlight emits light unnecessarily brightly and consumes a large amount of power.

  In order to solve the problem of the liquid crystal display device having such a backlight, for example, a method of controlling the light emission luminance of the entire backlight based on display luminance information of the entire display screen has been proposed.

  Also, a method of dividing the display screen into a plurality of regions corresponding to each light source constituting the backlight, and partially suppressing the light emission luminance of the light source corresponding to the display luminance required for each divided region Has been proposed (see, for example, Patent Document 1). Thereby, power consumption is reduced.

The above-mentioned “light emission luminance” means the luminance when light is emitted from the light source, and the above “display luminance” means that the light emitted from the light source is transmitted through the display unit (display screen). Of the brightness (hereinafter the same).
JP 2004-212503 A (paragraph [0035])

  However, in the conventional partial control of the light emission luminance described above, the display luminance distribution on the display screen may not match the light emission luminance distribution of the backlight, and the original image may not be faithfully reproduced.

  For example, it is assumed that there is a region with a low display luminance in a part of the screen to be displayed, and a region with a high display luminance is included in the low luminance region. In this case, it is assumed that a backlight light source that can be individually controlled vertically and horizontally is provided. In this case, since there is a low luminance area around the high luminance area, if the light source corresponding to the low luminance area is set low, the high luminance area is displayed with the necessary display luminance due to the influence. There is a problem that the image quality is deteriorated.

  In view of the circumstances as described above, an object of the present invention is to provide a backlight driving device capable of improving image quality while reducing power consumption, a display device equipped with the backlight driving device, and a backlight driving method. is there.

  Another object of the present invention is to provide a backlight driving device, a display device, and a backlight driving method capable of stabilizing the control of the backlight.

In order to achieve the above object, a backlight driving device according to the present invention includes:
A backlight drive device for a display unit that has a display screen and displays an image corresponding to an input video signal on the display screen,
A backlight having a plurality of light source blocks arranged corresponding to a plurality of areas into which the display screen is divided;
Detecting means for detecting display brightness of the display screen by the video signal;
The first light source block corresponding to a second region separated from the first region of the regions corresponding to the first light source block among the light source blocks by a predetermined region. Correction means for correcting the data of the display luminance contribution ratio for each area of the display screen when each light source block emits light so as to eliminate the contribution to the area;
Luminance distribution setting means for setting a light emission luminance distribution of each light source block according to the detected display luminance using the corrected contribution rate data;
Lighting control means for lighting the backlight with the set emission luminance distribution, and
The display unit includes a transmittance variable element that varies a transmittance of light emitted from the backlight,
The backlight driving device further includes transmittance control means for controlling the transmittance by the transmittance variable element in accordance with the contribution rate data before correction.

  “Data of display luminance contribution ratio for each area of the display screen when each light source block emits light” is data of display luminance contribution ratio for all areas affected by one light source block. is there. That is, in the present invention, since data on how the luminance of one light source block affects the entire display screen is stored, high-definition image quality can be obtained.

  Moreover, in the present invention, when the contribution to the first region by the second light source block corresponding to the second region separated from the first region of the display screen by a predetermined region is low, the second light source block corresponds to the second region. The contribution rate data is corrected by the correction means so that the contribution by the region is eliminated, that is, the contribution rate is set to zero. Therefore, it is possible to solve the problem that the change in the luminance signal of the video signal in the first region brings about a large luminance change in the second light source block, resulting in unstable luminance control.

  The “predetermined area” means, for example, one area, two areas, or more areas, and can be set as appropriate.

If transparently rate variable element is controlled, not the corrected contribution data, uncorrected contribution rate data is used. Therefore, an image can be displayed with a luminance that matches the actually input image signal, and no error occurs due to the correction of the contribution rate data.

  In the present invention, the backlight driving device compensates for the light emission luminance of the first light source block in order to compensate for the decrease in the display luminance caused by the correction means correcting the contribution rate data. Is further provided. In the present invention, since the lighting control is performed with the light emission luminance distribution based on the corrected contribution rate data in which the contribution rate by the second light source block is zero as described above, at least the display luminance of the first region is given. It becomes smaller than the value of the period. In order to compensate for this, at least the emission luminance of the first light source block can be increased to obtain the desired display luminance.

A display device according to the present invention has a display screen, and displays a video corresponding to an input video signal on the display screen;
A backlight having a plurality of light source blocks arranged corresponding to a plurality of areas into which the display screen is divided;
Detecting means for detecting display brightness of the display screen by the video signal;
The first light source block corresponding to a second region separated from the first region of the regions corresponding to the first light source block among the light source blocks by a predetermined region. Correction means for correcting the data of the display luminance contribution ratio for each area of the display screen when each light source block emits light so as to eliminate the contribution to the area;
Luminance distribution setting means for setting a light emission luminance distribution of each light source block according to the detected display luminance using the corrected contribution rate data;
Lighting control means for lighting the backlight with the set emission luminance distribution ;
In order to compensate for the decrease in the display brightness due to the correction means correcting the contribution rate data, the light emission brightness compensation means for compensating the light emission brightness of the first light source block is provided.

The backlight driving method according to the present invention includes:
A display unit having a display screen and displaying a video corresponding to the input video signal on the display screen ;
A backlight driving method for a display device including a backlight having a plurality of light source blocks arranged corresponding to a plurality of regions into which the display screen of the display unit is divided ,
Detecting a display luminance of the display screen by the prior SL video signal,
A second light source block corresponding to a second region separated from the first region of the plurality of regions of the display screen corresponding to the first light source block among the light source blocks by a predetermined region. In order to eliminate the contribution to the first area, the display luminance contribution data for each area of the display screen when a plurality of light source blocks arranged corresponding to each area emit light. A correction step;
Using the corrected contribution rate data, setting a light emission luminance distribution of each of the light source blocks according to the detected display luminance;
Lighting the backlight with the set emission luminance distribution ;
Controlling the transmittance by the transmittance variable element of the display unit, which varies a transmittance of light emitted from the backlight according to the contribution rate data before the correction .

  As described above, according to the present invention, it is possible to improve image quality while reducing power consumption. In addition, the backlight control can be stabilized.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a diagram showing a configuration of a liquid crystal display device according to an embodiment of the present invention. As shown in FIG. 1, the liquid crystal display device 10 includes a display unit 11 that displays an image, a backlight 12 disposed on the back side of the display unit 11, and various controls for the backlight 12 and the display unit 11. The control part 20 which performs is provided. A backlight driving device is configured by the backlight 12 and the control unit 20 (or the backlight 12 and the backlight lighting control circuit 15).

  The display unit 11 includes a liquid crystal panel 13, and further includes a source driver 17 and a gate driver 18 for sending drive signals to the liquid crystal panel 13. The liquid crystal panel 13 has a display screen divided into a plurality of regions, for example, nine regions A1 to A9 in the vertical direction (see FIG. 2).

  The backlight 12 is composed of a plurality of light source blocks, for example, nine light source blocks 1, 2,..., 9 and each of the light source blocks 1, 2,. It is arranged directly behind A1 to A9. Each light source block 1 to 9 is composed of one block for each control unit of the backlight lighting control circuit 15. As a light emitting element which comprises the light source blocks 1-9, a light emitting diode (LED: Light Emitting Diode) is mentioned, for example.

  As the plurality of light emitting diodes constituting the light source blocks 1 to 9, for example, a red light emitting diode, a green light emitting diode, and a blue light emitting diode are used. By arranging these light emitting diodes in order in a predetermined state, Each color is mixed so that it becomes white. The light emitted from each of the light source blocks 1 to 9 is diffused by a scattering plate or a scattering sheet (not shown) and applied to the back surface of the liquid crystal panel 13.

  Here, in order to simplify the description, as an example of the backlight 12, the light source blocks 1 to 9 are illustrated as being divided and arranged only in the vertical direction. Actually, it is preferable to use a light source block which is divided and arranged in both the vertical direction and the horizontal direction. However, the light source block may be one in which the light source is divided and arranged only in the horizontal direction. 1 and 2 show an example in which the display screen area is divided into nine areas, the number may be less than nine or more, but it is preferable that the area is as large as possible. One light source block may be composed of, for example, three light emitting diodes (one provided with one red, blue and green light emitting diodes), or a multiple of 3n (n is an integer of 1 or more). It may be comprised. The number of the light emitting diodes can be appropriately designed depending on the size of the display screen of the liquid crystal panel 13.

  Moreover, each area | region A1-A9 of a display screen is not set as an area | region where the light radiate | emitted only from the light source blocks 1-9 located right behind reaches | attains. Therefore, the light emitted from each of the light source blocks 1 to 9 reaches a region other than the region located immediately before by the scattering plate or the like, as will be described later.

  FIG. 3 is a block diagram showing the configuration of the control unit 20 and the memory 16. The control unit 20 includes a video signal detection circuit 19, a light emission luminance distribution setting unit 22, a contribution rate data correction unit 21, a liquid crystal panel control circuit 14, and a backlight lighting control circuit 15. The memory 16 includes a light emission luminance distribution data storage unit 36 and a contribution rate data storage unit 37.

  The video signal detection circuit 19 includes a luminance signal detection circuit 25 that detects a luminance signal in the video signal, and a color signal detection circuit 26 that detects a color signal.

  The light emission luminance distribution setting unit 22 sets the light emission luminance distribution of each of the light source blocks 1 to 9 according to the luminance signal detected by the luminance signal detection circuit 25. The emission luminance distribution data storage unit 36 stores the emission luminance distribution data set by the emission luminance distribution setting unit 22. The light emission luminance distribution data storage unit 36 often functions as a temporary buffer and is not always necessary in principle.

  The contribution rate data storage unit 37 stores display luminance contribution rate data that the light source blocks 1 to 9 affect the areas A1 to A9. The contribution rate data correction unit 21 applies predetermined correction to the contribution rate data stored in advance in the contribution rate data storage unit 37. The contribution rate data does not necessarily have to be stored as data in the contribution rate data storage unit 37 in advance, and can be derived by calculation in some form of function or the like. Therefore, the contribution rate data storage unit 37 may not be provided, or the contribution rate data storage unit 37 may function as a temporary buffer. The contribution rate data and the correction process will be described in detail later.

  The memory 16 is preferably a semiconductor memory or a dielectric memory, but is not limited to this, and may be a memory using other magnetism or light.

  When a video signal is input to the video signal detection circuit 19, the liquid crystal panel control circuit 14 generates a display drive signal for performing display drive on the liquid crystal panel 13 based on the input video signal.

  The generated display drive signal is sent to the source driver 17 and the gate driver 18 of the liquid crystal panel 13 and input to each pixel of the liquid crystal panel 13 via the source driver 17 and the gate driver 18. The display drive signal is input in one field period or one frame period in synchronization with the field period or frame period of the input video signal. When a display drive signal is input to each pixel of the liquid crystal panel 13, a correction process described later is performed. In the case of the interlace method, one field consists of two frames, and in the case of the progressive method, one field consists of one frame. “One field or one frame” is simply referred to as “one field”.

  The backlight lighting control circuit 15 receives an individual lighting control signal for each of the light source blocks 1 to 9 from the liquid crystal panel control circuit 14 when a video signal is input to the liquid crystal panel control circuit 14. In response to this, the driving of each of the light source blocks 1 to 9 is individually controlled.

  FIG. 4 is a diagram illustrating an example of light emission luminance of each of the light source blocks 1 to 9. In this example, the light emission luminance distribution of the backlight 12 is set in a state where the contribution rate is not corrected. In FIG. 4, the horizontal axis indicates the position in the vertical direction of the display screen, the vertical axis indicates the light emission luminance, and is an example in which each of the light source blocks 1 to 9 emits light with substantially the maximum uniform luminance. The brightness is shown. Specifically, the value on the vertical axis is a value when the total light emission luminance of each of the regions A1 to A9 is normalized to 1 when each of the light source blocks 1 to 9 emits light at substantially maximum luminance. . In the case of the example shown in FIG. 4, the maximum value of the light emission luminance by one light source block among the light source blocks 1 to 9 is about 0.44 to 0.45, but it goes without saying that the value is not limited to this value.

  In the liquid crystal display device 10, a partition or the like for preventing the light emitted from each of the light source blocks 1 to 9 from reaching an area other than the area located immediately before each of the light source blocks 1 to 9. Not provided. Therefore, the light emitted from each of the light source blocks 1 to 9 reaches another area other than the area located immediately before, and contributes to the display luminance in the other area.

  FIG. 5 shows the luminance contribution ratio of each light source block to each position on the display screen when the emitted light is incident on the liquid crystal panel 13 when each light source block having the light emission luminance shown in FIG. 4 is used. It is a thing. That is, the contribution rate data stored in the contribution rate data storage unit 37 is shown. The horizontal axis represents the position in the vertical direction of the display screen, and the vertical axis represents the luminance contribution ratio to the display luminance of the light emitted from each light source block 1-9.

  As shown in FIG. 5, the luminance contribution ratios of the light emitted from the light source blocks 1 to 9 are the highest in the corresponding regions A1 to A9 of the light source blocks 1 to 9, respectively, and gradually increase as the distance from the regions A1 to A9 increases. To drop. In other words, taking only the area A1 as an example, the luminance contribution ratio by the light source block 1 is highest in the area A1 corresponding thereto. Taking only the area A2 as an example, the luminance contribution ratio by the light source block 2 is high in the area A2 corresponding thereto. Further, in the vicinity of the boundary between the areas A1 and A2, the luminance contribution ratios of the light source blocks 1 and 2 intersect, and the combined luminance contribution ratio appears to be high. For the light source blocks 1 and 9 arranged at both ends in the vertical direction, the luminance contribution ratio in the corresponding regions A1 and A9 is about 40%, and for the light source blocks 2 to 8 arranged in the middle position, The luminance contribution ratios in the areas A2 to A8 corresponding to the respective areas are about 20 to 30%. The reason why the luminance contribution ratios in the areas A1 and A9 are high is due to the structure of the liquid crystal panel 13 due to the relationship between the reflector and the scattering plate.

  Thus, in the liquid crystal display device 10, the light emitted from each of the light source blocks 1 to 9 reaches an area other than the area corresponding to the light source blocks 1 to 9. That is, each light emitted from each of the light source blocks 1 to 9 is not irradiated to only the corresponding areas A1 to A9 separately, but is irradiated to other areas.

  In the liquid crystal display device 10, it is measured in advance how much the light emission luminance of each of the light source blocks 1 to 9 contributes to the display luminance of the regions A1 to A9, and this measured value is a simultaneous equation described later. Used as data for calculation.

  Next, a processing example of control related to screen display will be described with reference to the flowchart of FIG. This control is executed by the liquid crystal panel control circuit 14 and the backlight lighting control circuit 15 of the control unit 20 and is performed every time a video signal of one field is input to the liquid crystal panel control circuit 14.

  When a one-field video signal is input to the liquid crystal panel control circuit 14 (step 601), the luminance signal detection circuit 25 detects the distribution of the display luminance of one video (original video) generated by the input video signal. (Step 602). Therefore, the display brightness of each area A1 to A9, for example, the average display brightness obtained by averaging the display brightness of each part for each area A1 to A9 is detected.

  On the other hand, the contribution rate data correction unit 21 corrects the contribution rate data stored in the contribution rate data storage unit 16 (step 603). FIG. 7 is a diagram illustrating an example of light emission luminance distribution data set using the corrected contribution rate data. Here, in order to make the explanation easy to understand, data by the maximum luminance display of the backlight 12 shown in FIG. 4 is shown. FIG. 8 is a diagram showing data obtained by correcting the contribution rate data shown in FIG. Referring to FIG. 7, specifically, among the regions A1 to A9, for example, the contribution of the light source block (which may be a plurality of light source blocks) corresponding to a region separated from the central region A5 by a predetermined region is eliminated. That is, the contribution rate data is corrected to be zero. The reason why the contribution rate data is corrected in this way will be described later.

  The light emission luminance distribution setting unit 22 sets the light emission luminance distribution of each of the light source blocks 1 to 9 constituting the backlight 12 according to the display luminance distribution using the corrected contribution rate data (step 604). . Specifically, the light emission luminances of the light source blocks 1 to 9 are set by the simultaneous equations (2) to (10) using the contribution rate Kx, y.

  Note that corrected contribution rate data as shown in FIG. 8 may be stored in the memory 16 or the like in advance. Alternatively, the contribution rate data may be derived by calculation as described above, and the derived contribution rate data may be used in step 604.

  Next, after the light emission luminances of the light source blocks 1 to 9 are set as described above, the liquid crystal panel control circuit 14 uses the contribution rate data before correction to each area A1 of the display screen of the liquid crystal panel 13. A drive signal for the liquid crystal panel 13 generated so as to optimize the display brightness of the pixels corresponding to .about.A9 is generated (step 605). More specifically, the drive signal is generated based on the amount of deviation between the set light emission luminance of each of the light source blocks 1 to 9 and the optimum value of the display luminance in each part of the display screen. The optimum value is the display luminance required in each part of the display screen when the original video is displayed based on the input video signal. Accordingly, a deviation amount correction value for correcting the deviation amount is required in each part of the display screen when light is emitted from each of the light source blocks 1 to 9 with the light emission luminance set as described above. It is a value for calculating the transmissivity of the liquid crystal required in each pixel in order to obtain a display luminance of the same. To put it simply, for example, when the light emission luminance of a certain region of each of the regions A1 to A9 is ½ of the constant luminance as in the conventional case, the light of the liquid crystal pixel corresponding to that region. Correction is performed so that the transmittance is doubled.

  The control unit 20 sends a light emission drive signal corresponding to the light emission luminance distribution set in step 604 from the backlight lighting control circuit 15 to each of the light source blocks 1 to 9, and each of the light source blocks 1 to 9 is set to the set light emission. Light up with brightness. In synchronization with the operation of the backlight 12, the control unit 20 sends the driving signal for the liquid crystal panel 13 generated in step 605 to each pixel of the liquid crystal panel 13 from the liquid crystal panel control circuit 14. The video is displayed on the display screen (step 606). When a display drive signal is sent from the liquid crystal panel control circuit 14 to each pixel of the liquid crystal panel 13, the transmittance of each pixel is varied according to the display drive signal for each field and emitted from the light source blocks 1 to 9. The transmission state of each light for each pixel is controlled.

  Therefore, the video is displayed in each part of the display screen in a state where the display luminance corresponding to the input video signal is obtained.

  Below, the concrete method of the control performed in above-mentioned step 601-step 606 (refer FIG. 6) is demonstrated.

  If the number of light source blocks of the backlight 12 is N (N is an integer of 2 or more), N = 9 in this example.

  In the liquid crystal display device 10, as described above, the display screen is divided into nine regions A1 to A9, as shown in FIG. 2, with the number corresponding to the number of light source block divisions N (= 9). Has been.

  For each of the regions A1 to A9, the maximum display luminance Ln_max (n = 1 to 9) determined by the input video signal is obtained. The maximum display brightness Ln_max is a value that provides the maximum display brightness in each part of the areas A1 to A9. The maximum display luminance is a value corresponding to the video signal for each field, and is different for each field.

  Here, the display brightness of all white (when the white peak is set for both the liquid crystal panel 13 and the backlight 12 (usually when the transmittance of the liquid crystal panel 13 is 100% and the output of the backlight 12 is 100%)) is L_peak. A ratio αn (n = 1 to 6) of the maximum display luminance Ln_max with respect to the display luminance L_peak of all white is obtained for the regions A1 to A9. Here, Ln_max ≦ L_peak.

αn = (Ln_max / L_peak) (1)
The ratio αn is a recovery limit indicating how much the light emission luminance of the light source blocks 1 to 9 corresponding to the regions A1 to A9 can be suppressed. That is, the display brightness of the liquid crystal panel 13 is roughly determined by “the transmittance of the liquid crystal panel (including the polarizing plate) × the light emission brightness of the backlight”, but the recovery limit is that the light emission brightness of the backlight 12 is further reduced. Even if the transmittance of the liquid crystal panel is set to 100%, the maximum display luminance Ln_max cannot be obtained. The recovery limit αn corresponds to the luminance signal of the video signal, and in step 602, the recovery limit αn is obtained.

  In the above, the value of the recovery limit αn is obtained based on the maximum display luminance Ln_max of each of the areas A1 to A9. However, depending on the video content, αn ′ = based on the average display luminance Ln_ave of each of the areas A1 to A9. It is also possible to perform luminance control by obtaining the value of the recovery limit αn ′ by (Ln_ave / L_peak). When the control is performed by obtaining the value of the recovery limit αn ′, it is difficult to reproduce a complete original image, but it is possible to reproduce the original image in a range that is less affected by appearance.

  As described above, the light emission luminances of the other light source blocks 1 to 9 contribute to the display luminances of the respective regions A1 to A9 in addition to the light emission luminances of the light source blocks 1 to 9 corresponding to the regions A1 to A9. Therefore, the light source blocks 1 to 9 that do not correspond to the regions A1 to A9 can be controlled only by controlling the emission luminance of the light source blocks 1 to 9 corresponding to the regions A1 to A9 according to the recovery limits αn of the regions A1 to A9. It is not possible to perform control in consideration of light emission luminance.

  Accordingly, the light emission rate βn (n = 1 to 9) for each of the light source blocks 1 to 9 is obtained in consideration of the light emission luminance of the light source blocks 1 to 9 that do not correspond to the regions A1 to A9. The light emission rate βn is a value indicating the ratio of the actual light emission luminance of each light source block 1 to the maximum light emission luminance (when white peak is set) of each light source block 1 to 9, and in the range of 0 ≦ βn ≦ 1. Desired.

The light emission rate βn is calculated using the luminance contribution ratios K _{X, Y} (see FIG. 5) of the light source blocks 1 to 9 for the regions A1 to A9. The luminance contribution rate data of the light source blocks 1 to 9 shown in FIG. 5 is stored in advance in the contribution rate data storage unit 37 as described above, and the stored light source blocks 1 to 1 are calculated when the light emission rate βn is calculated. 9 contribution rate data are read out.

In the luminance contribution rate Kx, y, X indicates the regions A1 to A9, and Y indicates the light source blocks 1-9. For example, K _1,1 indicates the luminance contribution ratio of the light source block 1 positioned at the top with respect to the area A1, and for example, K _2,3 indicates the luminance contribution ratio of the light source block 3 positioned at the third position from the top with respect to the area A2. Indicates. As shown in FIG. 5, the luminance contribution rate is not constant in each region for each of the light source blocks 1 to 9, but the contribution rate data storage unit 37 includes, for example, the region as the luminance contribution rate Kx, y. Data at the center of each of A1 to A9 is stored.

  The luminous rate βn is obtained by solving the multiple simultaneous equations (inequality) (2) to (10) shown in FIG.

In step 604, the light emission rate βn (0 ≦ βn ≦ 1) is calculated using the multiple simultaneous equations, and the light emission luminance of each of the light source blocks 1 to 9 is set so as to satisfy the light emission rate βn. A luminance distribution is set. In particular, in the present embodiment, the contribution of the light source block of another region to the light source block corresponding to a certain region is zero, so that in each of the equations (2) to (10), the predetermined Kx, y is Zero. For example, referring to FIG. 8, when viewed in a region A5, regions A1, A2, etc., which are separated from K ₅ , y by a predetermined region, that is, terms such as K _5,1 and K _5,2 are zero. . However, in this case, when the simultaneous equations (2) to (10) are solved, the light emission rate βn is obtained in consideration of all terms, and after the light emission rate βn is obtained, correction processing is performed. The predetermined term is set to zero.

  The multiple simultaneous equations described above can be used regardless of the configuration of the backlight because the number of n only changes according to the number of divisions of the backlight.

  Moreover, although the example which calculates | requires (beta) n for every light source block 1-9 was shown above, for example, for every primary color of red, green, blue, or every luminescent color of the backlight 12, (beta) n is calculated separately, and brightness | luminance It is also possible to perform control.

  FIG. 9 shows a state in which when a video signal for one field is input, the light emission rate βn is calculated using the above method, and the light emission luminance of each of the light source blocks 1 to 9 of the backlight 12 is controlled. It is an example.

  In FIG. 9, the horizontal axis indicates the position of the display screen in the vertical direction. In FIG. 9, the data of each point connected by a broken line indicates the recovery limit αn in each of the areas A1 to A9, and the data of each point connected by a solid line is the light emission rate βn of the light source blocks 1 to 9 in each of the areas A1 to A9. Indicates the total value. That is, the graph of FIG. 9 is a graph representing the above simultaneous equations. Thus, the light emission rate βn is set to a value close to the recovery limit αn, and the light emission luminance of the light source blocks 1 to 9 is efficiently controlled. In this example, the display brightness of the area A5 is the lowest, the display brightness increases as the distance from the area A5 increases, and the display brightness is the highest in the area A1.

  In this way, by using the recovery limit αn and the luminance contribution rate Kx, y, by solving the multiple simultaneous equations, the light emission rate βn of the light source blocks 1 to 9 is obtained and the light emission luminance of each of the light source blocks 1 to 9 is controlled, The light emission luminance of each of the light source blocks 1 to 9 can be suppressed according to the display state of the video. Thereby, the power consumption of the backlight 12 can be reduced. For example, for black parts in the video, the light source block corresponding to the area is turned off, and for bright parts in the video, the light source block corresponding to the area is turned on to display a high contrast video. It becomes possible to do.

  In the present embodiment, since display luminance contribution ratio data indicating how the luminance of one light source block affects the entire display screen is stored, high-definition image quality can be obtained.

  Next, the reason for correcting the contribution rate data will be described.

  In step 603, as described above, correction is performed in which the contribution ratio by the light source block corresponding to a region separated from a certain region among the regions A1 to A9 is regarded as zero. In the example shown in FIG. 8, the light emission luminance below the light emission luminance is corrected to zero for all the regions A1 to A9.

  For example, looking at the center area A5, the contribution ratio to the area A5 by the light source blocks 1, 2, 8, and 9 corresponding to the areas A1, A2, A8, and A9 separated from the area A5 by two or more areas is as follows. Since it is low, it is corrected to eliminate this. Alternatively, similarly, when the center area A5 is viewed in the center, the light source blocks 1, 2, 3, 7, 8, 9 of the areas A1, A2, A3, A6, A8, A9 that are three or more away from the area A5. Since the contribution ratio to the region A5 is low, correction is made to eliminate this. In the example illustrated in FIG. 8, in all the light source blocks 1 to 9, for example, a portion where the light emission luminance is 0.1 or less is zero.

  The “predetermined area” can be set as appropriate. In the example shown in FIG. 8, for example, a portion where the light emission luminance is approximately 0.1 or less is zero. The fact that “predetermined area” can be set as appropriate means that the numerical value of the light emission luminance “0.1 or less” can be set as appropriate. For example, it is not limited to 0.1 or less, and may be set to 0.05 or less and 0.2 or less.

  FIG. 10 corresponds to a region around the region A5 corresponding to a video signal for a certain field when the display luminance required for the central region A5 is 1 (= 100%) (horizontal axis), for example. It is a graph which shows the brightness | luminance (vertical axis) of each light source block. In this example, for example, the light source blocks 5 corresponding to the regions A3 to A7 are respectively lit with the maximum luminance.

  FIG. 11 is a diagram corresponding to FIG. 10, and shows a state in which the five light source blocks 3 to 7 are lit at the maximum brightness around the area A5 and are combined. As can be seen from FIG. 11, when the surrounding light source blocks 3 to 7 are turned on at the maximum luminance (for example, 0.44) with the light source block 5 as the center, the luminance in the region A5 is increased by the contribution of these light source blocks. It is set to 1. In order to make the explanation easier to understand, only the five light source blocks 3 to 7 of the nine light source blocks 1 to 9 are lit at the maximum luminance, and the luminance of only the area A5 is normalized to 1. The explanation is based on the assumption that Describing more specifically in FIG. 11, first, the light source block 5 is lit at the maximum luminance (for example, 0.44), so that the display luminance in the region A5 is 0.44. Next, in addition to this, when the light source block 6 is lit at the maximum luminance (for example, 0.44), the display luminance in the region A5 is 0.68. Next, in addition to this, when the light source block 4 is lit at the maximum luminance (for example, 0.44), the display luminance in the region A5 becomes 0.92. In order for the display luminance of the area A5 to be the maximum luminance 1, the remaining luminance of 0.08 is necessary. In order to obtain the luminance of 0.08, the remaining light source blocks 3 and 7 are set to the maximum luminance (for example, 0.44). ) Must be turned on respectively.

  Referring to FIG. 10, when the light source blocks 3 and 7 corresponding to the regions A3 and A7 separated by a predetermined distance from the central region A5 are viewed, the inclination is steep compared to the other light source blocks 4 to 6. Means that In FIG. 10, in order to obtain the luminance (= 0.08) of the portion a, the light source blocks 3 and 7 must be turned on at the maximum luminance (for example, 0.44). Therefore, in this case, due to the luminance change due to minute noise of the input video signal, for example, the light source block corresponding to the region away from the region A5 needs to change the luminance change more drastically. As a result, the luminance control of the backlight becomes unstable, and there are problems such as occurrence of flicker on the video.

  In this embodiment, in order to avoid such a problem, the contribution rate data is corrected as shown in FIG. 8 by setting the contribution rate of the light source blocks 3 and 7 corresponding to the regions A3 and A7 to the region A5 to zero. Is done. Referring to FIG. 7, for example, when viewed in the central area A5, correction is made so that the broken line portion disappears, as can be seen from FIG. Such correction processing is performed not only for the area A5 but also for all the areas A1 to A9.

  FIGS. 12 and 13 are diagrams corresponding to FIGS. 10 and 11, respectively, and are diagrams illustrating examples in which the light source blocks 3 and 7 are not considered as in the present embodiment. In this way, by ignoring the contribution ratio of the light source block having a low contribution ratio to the area A5, the luminance control of the backlight 12 is stabilized and the image quality is improved.

  Although not shown in FIG. 10, for the purpose of stabilizing the control, contribution ratios of the light source blocks 1, 2, 8, and 9 corresponding to them to the area A5 are also included for A1, A2, A8, and A9. Is preferably zero. Alternatively, it is of course possible that the contribution ratio of only the light source blocks 1 and 9 corresponding to A1 and A9 to the area A5 is zero.

  After the contribution rate data is corrected and the light emission luminance distribution is set as described above, the display luminance of each part of the display screen of the liquid crystal panel 13 is set to the optimum value at the time of video display as shown below. The shift amount correction value for each pixel is calculated. This is the process of step 605 described above. In step 605, a drive signal is generated based on the contribution rate data before correction, not on the contribution rate data after correction. Therefore, this step 605 may be performed before step 604 described above.

  The deviation amount correction value is calculated based on data on display luminance characteristics of the liquid crystal panel 13 shown in FIG. In FIG. 15, the horizontal axis indicates the set gradation (voltage) S_data of the liquid crystal panel 13 when the output of the backlight 12 is 100% (when fully lit), and the vertical axis indicates the liquid crystal panel 13 with respect to the set gradation S_data. Display luminance L_data is shown. Data of the display luminance characteristic f shown in FIG. 15 is obtained in advance and stored in the memory 16, for example.

  For each pixel, γ is the ratio between the display brightness L_peak of all white and the set display brightness L_set. The set display brightness L_set refers to the display brightness when the pixel has a transmittance of 100% when light is emitted from the light source blocks 1 to 9 for which the light emission brightness is set based on the light emission ratio βn.

γ = L_peak / L_set (11)
As described above, the set gradation S_data of the video (original video) displayed when the video signal is input is determined based on the display luminance L_data by the data shown in FIG.

L_data = f (S_data) (12)
The corrected set gradation S_data ′ with respect to the set display brightness L_set is calculated by the following expression based on the ratio γ between the display brightness L_peak of all white and the set display brightness L_set and the set gradation S_data. The correction setting gradation S_data ′ is a shift amount correction value for calculating the transmittance required for each pixel.

S_data ′ = f (γ × L_data) ⁻¹ (13)
By setting the transmissivity of each pixel so that the corrected set gradation S_data ′ is obtained, the original image is reproduced with the optimum display luminance.

  Further, as described above, the liquid crystal drive signal is generated according to the corrected contribution rate data, not the corrected contribution rate data. As a result, an image can be displayed with a luminance that matches the actually input image signal, and an error due to the correction of the contribution rate data does not occur.

  FIG. 16 is a diagram showing an outline of the operation of the liquid crystal display device 10 described above using actual images.

  FIG. 17 shows a flowchart according to another embodiment of the present invention. In this example, operations other than step 1605 are the same as those shown in FIG. In step 1604, when the contribution rate data is corrected by the same method as in step 604, as can be seen from FIG. 13, for example, the maximum luminance realized in the region A5 is 92% of the intended luminance. Depending on the state of the video, there may be a slight decrease in luminance. In this case, compensation is performed so that luminance according to the contribution rate data before correction is obtained.

  Specifically, the control unit 20 (see FIG. 3) generates a drive signal so as to overdrive each of the light source blocks 1 to 9 (step 1605). Overdrive means driving each light source block 1 to 9 with an output equal to or greater than a predetermined maximum value. That is, in this case, the control unit 20 and the backlight lighting control circuit 15 constitute light emission luminance compensation means for compensating the light emission luminance of the backlight 12 to an intended value.

  In the example of FIG. 13, when the necessary display luminance of the area A5 exceeds 0.92, that is, when it is 1, specifically, overdrive is performed as follows. For example, in the corrected emission luminance distribution data, the maximum luminance of the light source block 5 is 0.44, whereas the luminance is 0.44+ (1−0.92) = 0.52, that is, the maximum luminance is 0. .44 of 118% (= 0.52 / 0.44). Of course, in this case, the same overdrive is performed not only for the light source block 5 but also for the surrounding light source blocks 4 and 6 so that the display luminance of the area A5 becomes 1. Note that the “distribution” of the light emission luminance of the backlight 12 uses the contribution rate data corrected in step 1604 as in FIG. 6, and only the luminance magnitude is a predetermined area. (At least in the region A5 in the example shown in FIG. 13).

  However, when overdrive is performed as described above, for example, when the display brightness of the area A5 is set to 1, only the light source block 5 or only the surrounding light source block 4 or 6 is overdriven. It may be controlled so that the display brightness of the area A5 is 1.

  As described above, according to the present embodiment, desired display luminance can be obtained by overdriving at least one light source block.

  The present invention is not limited to the embodiment described above, and various modifications are possible.

  For example, in each of the above embodiments, an example in which liquid crystal is used as the transmittance variable element of the display unit has been described. However, any element may be used as long as a backlight is disposed on the back side of the display unit 11 and the transmittance of the pixels of the display unit 11 is controlled to display an image.

It is a figure which shows the structure of the liquid crystal display device which concerns on one embodiment of this invention. It is a figure which shows the structure of the display screen of a liquid crystal panel, and a backlight. It is a block diagram which shows the structure of the control part and memory which are shown in FIG. It is the figure which showed the example of the light emission luminance of each light source block. FIG. 5 shows the luminance contribution ratio of each light source block to each position on the display screen when the emitted light is incident on the liquid crystal panel when each light source block having the light emission luminance shown in FIG. 4 is used. It is a flowchart which shows operation | movement of a liquid crystal display device. It is a figure which shows an example of the data of the light emission luminance distribution set using the contribution rate data after correct | amending. It is a figure which shows the example by which the contribution rate data of FIG. 5 was correct | amended. This is an example showing a state in which when a video signal for one field is input, the light emission rate βn is calculated using the above method, and the light emission luminance of each light source block of the backlight is controlled. It is a graph which shows the brightness | luminance of each light source block corresponding to the area | region of area | region A5 according to the video signal for a certain field when the display brightness | luminance required for a center area | region is 1 (= 100%). It is a graph which shows a mode that five light source blocks are each lighted by the maximum brightness | luminance centering on the center area | region, and they were synthesize | combined. 11 is a graph according to the present embodiment corresponding to FIG. 12 is a graph according to the present embodiment corresponding to FIG. An example of a multiple simultaneous equation for setting the emission luminance distribution will be shown. It is a graph which shows the display-luminance characteristic with respect to the setting gradation of a liquid crystal panel. It is the figure which showed the outline of operation | movement of the demonstrated liquid crystal display device using the actual image | video. It is a flowchart which shows the operation | movement which concerns on other embodiment of this invention of a liquid crystal display device.

Explanation of symbols

A1 to A9: Display screen divided areas 1-9: Light source block 10 ... Liquid crystal display device 11 ... Display unit 12 ... Backlight 13 ... Liquid crystal panel 14 ... Liquid crystal panel control circuit 15 ... Backlight lighting control circuit 16 ... Memory DESCRIPTION OF SYMBOLS 19 ... Video signal detection circuit 20 ... Control part 21 ... Contribution rate data correction part 22 ... Light emission luminance distribution setting part 37 ... Contribution rate data memory | storage part 36 ... Light emission luminance distribution data memory part

Claims (6)

A backlight drive device for a display unit that has a display screen and displays an image corresponding to an input video signal on the display screen,
A backlight having a plurality of light source blocks arranged corresponding to a plurality of areas into which the display screen is divided;
Detecting means for detecting display brightness of the display screen by the video signal;
The first light source block corresponding to a second region separated from the first region of the regions corresponding to the first light source block among the light source blocks by a predetermined region. Correction means for correcting the data of the display luminance contribution ratio for each area of the display screen when each light source block emits light so as to eliminate the contribution to the area;
Luminance distribution setting means for setting a light emission luminance distribution of each light source block according to the detected display luminance using the corrected contribution rate data;
Lighting control means for lighting the backlight with the set emission luminance distribution, and
The display unit includes a transmittance variable element that varies a transmittance of light emitted from the backlight,
The backlight drive device further comprises a transmittance control means for controlling the transmittance by the transmittance variable element according to the contribution rate data before the correction . A backlight drive device for a display unit that has a display screen and displays an image corresponding to an input video signal on the display screen,
A backlight having a plurality of light source blocks arranged corresponding to a plurality of areas into which the display screen is divided;
Detecting means for detecting display brightness of the display screen by the video signal;
The first light source block corresponding to a second region separated from the first region of the regions corresponding to the first light source block among the light source blocks by a predetermined region. Correction means for correcting the data of the display luminance contribution ratio for each area of the display screen when each light source block emits light so as to eliminate the contribution to the area;
Luminance distribution setting means for setting a light emission luminance distribution of each light source block according to the detected display luminance using the corrected contribution rate data;
Lighting control means for lighting the backlight with the set emission luminance distribution ;
A backlight driving apparatus comprising: a light emission luminance compensation unit that compensates for the light emission luminance of the first light source block in order to compensate for a decrease in the display luminance due to the correction means correcting the contribution rate data . A display unit having a display screen and displaying a video corresponding to the input video signal on the display screen;
A backlight having a plurality of light source blocks arranged corresponding to a plurality of areas into which the display screen is divided;
Detecting means for detecting display brightness of the display screen by the video signal;
The first light source block corresponding to a second region separated from the first region of the regions corresponding to the first light source block among the light source blocks by a predetermined region. Correction means for correcting the data of the display luminance contribution ratio for each area of the display screen when each light source block emits light so as to eliminate the contribution to the area;
Luminance distribution setting means for setting a light emission luminance distribution of each light source block according to the detected display luminance using the corrected contribution rate data;
Lighting control means for lighting the backlight with the set emission luminance distribution ;
A transmittance variable element that varies the transmittance of light emitted from the backlight;
A display device comprising: transmittance control means for controlling the transmittance by the transmittance variable element according to the contribution rate data before the correction . A display unit having a display screen and displaying a video corresponding to the input video signal on the display screen;
A backlight having a plurality of light source blocks arranged corresponding to a plurality of areas into which the display screen is divided;
Detecting means for detecting display brightness of the display screen by the video signal;
The first light source block corresponding to a second region separated from the first region of the regions corresponding to the first light source block among the light source blocks by a predetermined region. Correction means for correcting the data of the display luminance contribution ratio for each area of the display screen when each light source block emits light so as to eliminate the contribution to the area;
Luminance distribution setting means for setting a light emission luminance distribution of each light source block according to the detected display luminance using the corrected contribution rate data;
Lighting control means for lighting the backlight with the set emission luminance distribution ;
A display apparatus comprising: a light emission luminance compensation unit that compensates for the light emission luminance of the first light source block in order to compensate for a decrease in the display luminance due to the correction means correcting the contribution rate data . A display unit having a display screen and displaying a video corresponding to the input video signal on the display screen ;
A backlight driving method for a display device including a backlight having a plurality of light source blocks arranged corresponding to a plurality of regions into which the display screen of the display unit is divided ,
Detecting a display luminance of the display screen by the prior SL video signal,
A second light source block corresponding to a second region separated from the first region of the plurality of regions of the display screen corresponding to the first light source block among the light source blocks by a predetermined region. In order to eliminate the contribution to the first area, the display luminance contribution data for each area of the display screen when a plurality of light source blocks arranged corresponding to each area emit light. A correction step;
Using the corrected contribution rate data, setting a light emission luminance distribution of each of the light source blocks according to the detected display luminance;
Lighting the backlight with the set emission luminance distribution ;
And a step of controlling the transmittance by the transmittance variable element of the display unit, wherein the transmittance of the light emitted from the backlight is varied according to the contribution rate data before the correction. . A display unit having a display screen and displaying a video corresponding to the input video signal on the display screen ;
A backlight driving method for a display device including a backlight having a plurality of light source blocks arranged corresponding to a plurality of regions into which the display screen of the display unit is divided ,
Detecting a display luminance of the display screen by the prior SL video signal,
A second light source block corresponding to a second region separated from the first region of the plurality of regions of the display screen corresponding to the first light source block among the light source blocks by a predetermined region. When the plurality of light source blocks arranged corresponding to the plurality of areas into which the display screen is divided emit light so as to eliminate the contribution to the first area, the display on each area of the display screen Correcting the luminance contribution data;
Using the corrected contribution rate data, setting a light emission luminance distribution of each of the light source blocks according to the detected display luminance;
Lighting the backlight with the set emission luminance distribution ;
Compensating the light emission luminance of the first light source block to compensate for the decrease in the display luminance due to the correction of the contribution rate data .