JP2010091729A - Backlight device, display, electronic equipment, and method for driving backlight - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a backlight device reducing a steep brightness change in a boundary portion between adjoining split regions without increasing the load on a driving system, and to provide a display mounted with the backlight device, electronic equipment, and a method for driving the backlight. <P>SOLUTION: A block brightness value calculating section 51 calculates a brightness value in each of 40 section light source blocks 6, that is, of each section light source block 6, based on a brightness signal detected by a brightness signal detecting circuit. A brightness value calculating section 52 calculates a brightness value of each light source 5B, which is a light source except for a representative light source and disposed around the representative light source 5A, based on the calculated representative brightness value. A whole brightness value output section 53 outputs the data of the representative brightness of the calculated representative light source 5A and the data of whole brightness values of the respective calculated light sources 5B to a backlight driving section 10. Thereby, a steep brightness change in a boundary portion between adjoining section light source blocks 6 can be reduced. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a backlight device used for, for example, a liquid crystal panel, a display device equipped with the backlight device, an electronic apparatus, and a backlight driving method.

  In the liquid crystal display, since the pixels of the liquid crystal panel do not emit light, a so-called direct-type backlight having a plurality of light sources is disposed on the back side of the liquid crystal panel. The backlight illuminates the back of the liquid crystal panel to display an image.

  Such a direct type backlight employs a partial drive method. In the partial drive method, an image for one frame of a video signal is divided into a plurality of regions corresponding to each light source constituting the backlight, and the luminance of each light source is determined according to luminance information for each divided region. This is a method for controlling. (For example, refer to Patent Document 1). This reduces the power consumption of the backlight and increases the contrast ratio on the display screen.

  In recent years, thinning of liquid crystal displays has been demanded. In the above-described liquid crystal display using a direct backlight, it is necessary to reduce the distance between the liquid crystal panel and the backlight in order to reduce the thickness. However, since the light emitted from each light source is diffused light, if the distance becomes small, the irradiation area of the light from each light source on the liquid crystal panel becomes small, and it becomes difficult to faithfully reproduce the original image. Therefore, in order to secure an irradiation area that covers the entire liquid crystal panel, a configuration in which the number of light sources included in the backlight is increased and the light source that illuminates each area of the divided screen is composed of a plurality of light sources is considered. It is done.

  As described above, in a backlight in which a plurality of light sources correspond to one divided area, the distance between the liquid crystal panel and the backlight is set so that the light beams traveling from the light sources to the liquid crystal panel do not overlap between the liquid crystal panel and the backlight. In such a case, the following problems arise.

JP 2007-286627 A (paragraph [0004])

  For example, when each light source emits light so that the brightness is different for each divided region, the smaller the distance between the liquid crystal panel and the backlight, that is, the smaller the irradiation area from each light source to the liquid crystal panel, the adjacent divided region The change in the brightness of light at the boundary between them becomes steep. This is considered to be because the irradiation area becomes smaller as the distance between the liquid crystal panel and the backlight becomes smaller, and the uniformity of the illuminance distribution in the liquid crystal panel for each divided region increases. Conversely, as the distance between the liquid crystal panel and the backlight increases, the irradiation area increases, and the uniformity of the illuminance distribution in the liquid crystal panel for each divided region decreases, so that light is emitted at the boundary between adjacent divided regions. It will be blurred and the luminance change will be moderate.

  That is, as the distance between the liquid crystal panel and the backlight is smaller, smooth luminance changes are not expressed at the boundary portion between the divided regions, and the original image may not be faithfully reproduced. In order to solve this problem, it is conceivable that the backlight is configured so that each divided region is made smaller and the light source that illuminates each region is composed of one light source. However, in that case, construction of a new arithmetic circuit, installation of wiring, etc. are required, and the load on the drive system increases.

  In view of the circumstances as described above, an object of the present invention is to provide a backlight device that can alleviate a steep luminance change at a boundary portion between adjacent divided regions without increasing the load on the drive system. An object is to provide a display device, an electronic device, and a driving method of a backlight.

In order to achieve the above object, a backlight device according to an embodiment of the present invention includes a light source unit, setting means, and driving means.
The light source unit includes a unit light source block in which a plurality of light sources are configured as one block, and the plurality of unit light source blocks are arranged so as to correspond to a screen of a display panel.
The setting unit is a representative luminance for each unit light source block according to a video signal to be displayed on the screen, and is a representative block luminance that is a luminance of at least one representative light source among the plurality of light sources. A value is set, and each luminance value of a light source other than the representative light source among the plurality of light sources is set based on the set block representative luminance value.
The driving means drives each light source of the light source unit based on the set block representative luminance value and each luminance value of a light source other than the set representative light source.

  In other words, the setting means relies on the representative light source so as to alleviate a steep luminance change between adjacent divided regions of the video signal to be displayed on the screen, that is, at the boundary between the unit light source blocks, based on the block representative luminance value. Each luminance value of the light source other than can be set.

  For example, when a light source other than the representative light source is arranged around the representative light source in the one unit light source block, the setting means performs interpolation and extrapolation based on the set block representative luminance value. The brightness values of the light sources other than the representative light source may be obtained by the calculation according to.

  The driving means may include a driver for driving the representative light source and a light source other than the representative light source for each unit light source block. In this case, at least one of the drivers is configured to time-divide the representative light source and the light source other than the representative light source according to the set block representative luminance value and the luminance values of light sources other than the set representative light source. It may be driven by.

  The number of drivers can be reduced by driving the representative light sources and light sources other than the representative light sources in a time division manner.

A display device according to one embodiment of the present invention includes a display panel and a backlight.
The display panel has a screen and displays video on the screen in accordance with an input video signal.
The backlight having the above-described configuration may be used.

  An electronic device according to an embodiment of the present invention includes the display device.

A backlight driving method according to an aspect of the present invention includes a unit light source block in which a plurality of light sources are configured as one block, and the plurality of unit light source blocks are arranged so as to correspond to a screen of a display panel. This is a method of driving a backlight including the light source unit configured as described above.
In accordance with the video signal to be displayed on the screen, a block representative luminance value that is a representative luminance for each unit light source block and that is a luminance of at least one representative light source among the plurality of light sources is set. .
Based on the set block representative luminance value, each luminance value of a light source other than the representative light source among the plurality of light sources is set.
The light sources of the light source unit are driven by the set block representative brightness value and the brightness values of light sources other than the set representative light source.

  As described above, according to the present invention, it is possible to alleviate a steep luminance change at a boundary portion between adjacent divided regions without increasing the load on the drive system.

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

  FIG. 1 is a diagram showing a configuration of a display device according to an embodiment of the present invention.

  The display device 100 includes a liquid crystal panel 4 as a display panel for displaying an image, a backlight 2 disposed on the back side of the liquid crystal panel 4, and a control unit that performs various controls on the backlight 2 and the liquid crystal panel 4. 3 is provided.

  The liquid crystal panel 4 includes a liquid crystal device 1 including a screen, and a source driver 21 and a gate driver 22 that input display drive signals to the liquid crystal device 1.

  FIG. 2 is a plan view showing the configuration of the backlight 2. The backlight 2 has a substrate 23 and a plurality of light sources 5 arranged in a matrix on the substrate 23 so as to correspond to the screen of the liquid crystal device 1, that is, along the screen. The backlight 2 includes, for example, unit light source blocks 6 virtually divided into a plurality of regions on the substrate 23, and one unit light source block 6 is configured by arranging a plurality of light sources 5 in a matrix. Yes. The number of light sources 5 included in one unit light source block 6 is nine, for example, but is not limited to this and may be any number.

  The number of unit light source blocks 6 is typically 40 in total, 5 in the vertical direction of the substrate 23 and 8 in the horizontal direction. However, each unit light source block 6 is not limited to such division, and the number of unit light source blocks 6 may be any number.

  The substrate 23 may be constituted by a single substrate, or a substrate is prepared for each unit light source block 6 divided into a plurality of regions, and these substrates are arranged in a matrix to constitute the substrate 23. May be.

  As the light source 5, an LED (Light Emitting Diode) is typically used. In the present embodiment, as the light source 5, for example, an LED chip (not shown) sealed with a resin in the shape of a hemispherical lens is used, but the shape of the sealing portion may not be a lens shape. By providing the lens-shaped sealing member, light distribution characteristics with desired luminance can be obtained.

  FIG. 3 is a block diagram showing the configuration of the control unit 3.

  The control unit 3 includes a video signal detection circuit 7, a light emission luminance setting unit 8, a liquid crystal panel drive control unit 9, and a backlight drive unit 10.

  The video signal detection circuit 7 includes a luminance signal detection circuit 7 a that detects a luminance signal in the video signal 24 and a color signal detection circuit 7 b that detects a color signal.

  The liquid crystal panel drive control unit 9 sends data signals, control signals, etc. to the source driver 21 and the gate driver 22 based on the luminance signal detected by the luminance signal detection circuit 7a and the color signal detected by the color signal detection circuit. Is output. The source driver 21 and the gate driver 22 receive these data signals and control signals and drive the liquid crystal device 1 as described above.

  FIG. 4 is a block diagram showing the configuration of the light emission luminance setting unit 8 and the backlight driving unit 10 shown in FIG.

  The light emission luminance setting unit 8 includes a block luminance value calculation processing unit 51, a luminance value calculation processing unit 52, and a total luminance value output unit 53.

  The block luminance value calculation processing unit 51 calculates the luminance value for each of the 40 unit light source blocks 6, that is, all the unit light source blocks 6, based on the luminance signal detected by the luminance signal detection circuit 7a.

  Here, the luminance values of all the unit light source blocks 6 are the luminance values of at least one representative light source 5 (hereinafter referred to as a representative light source) among the nine light sources 5 in one unit light source block 6. This is hereinafter referred to as a representative luminance value. For example, as shown in FIG. 5, among the nine light sources 5 in one unit light source block 6, the light source 5 arranged in the center is taken as a representative light source 5A.

  Based on the calculated representative luminance value, the luminance value calculation processing unit 52 calculates the luminance value of each light source 5B other than the representative light source 5A and disposed around the representative light source 5A. The total luminance value output unit 53 outputs the calculated representative luminance value data of the representative light source 5 </ b> A and the calculated total luminance value data of each light source 5 </ b> B to the backlight driving unit 10.

  FIG. 6 is a diagram showing the arrangement relationship of the 40 unit light source blocks 6. FIG. 7 is a diagram showing the arrangement relationship of the light sources 5 in the nine unit light source blocks 6 in the upper left among the 40 unit light source blocks 6.

As shown in FIG. 6, unit light source blocks 6 of <11> to <18>, <21> to <28>,..., <51> to <58> are arranged. As shown in FIG. 7, for example, the nine unit light source blocks 6 at the upper left of the backlight 2 will be described. The luminance values of the light sources (11a _LS ) to (11i _LS ) in the unit light source block <11> are expressed as (11a ) To (11i), the luminance values of the light sources (12a _LS ) and (13i _LS ) in the unit light source block <12> are (12a) to (12i),. The luminance values of the representative light source 5A, that is, the light sources (11e _LS ), (12e _LS ),... (58e _LS ) are luminance values (11e), (12e),.

Referring to FIG. 4, the backlight drive section 10, using the 360 total luminance values outputted from the overall brightness value output unit 53, a driver for driving all source 5, respectively (11a _DRV), (11b _DRV ), ... (58i _DRV ).

The total luminance value output unit 53 according to the present embodiment outputs 360 total luminance value data to the upper left light source (11a _LS ) in the upper left unit light source block <11>, for example. For example, if the total luminance value output unit 53 adds a header including address data of each light source 5 to each of 360 total luminance value data, each driver (11a _DRV ), (11b _DRV ) _,. ... (58i _DRV ) can distribute the data of each luminance value.

However, for each unit light source block <11>, <12>,... <58>, the total luminance value output unit 53 converts the data of nine luminance values included in each unit light source block to each driver. You may output to (11a _DRV ), (12a _DRV ),... (58a _DRV ), respectively. In this case, for example, when focusing on the unit light source block <11>, the luminance values (11a _LS ), (11b _LS ) are arranged in the order of drivers (11a _DRV ), (11b _DRV ), (11c _DRV ) _,. , (11c _LS ),...

  Alternatively, the total luminance value output unit 53 is divided into unit light source blocks <11> to <18>, <21> to <28>,... <51> to <58>, that is, divided into five groups. The data of each luminance value may be output.

  The block luminance value calculation processing unit 51, the luminance value calculation processing unit 52, the total luminance value output unit 53, and the like are hardware such as a CPU (Central Processing Unit), a RAM (Random Access Memory), and a ROM (Read Only Memory). Hardware, or hardware such as FPGA (Field Programmable Gate Array), ASIC (Application Specific Integrated Circuit), or the like. The driver is typically configured by hardware using an IC. Further, as a driving method of each luminance by the driver, PWM (Pulse Width Modulation) is typically used, but is not limited thereto.

  The block luminance value calculation processing unit 51, the luminance value calculation processing unit 52, the total luminance value output unit 53, and the like execute processing based on a synchronization signal (vertical and horizontal) included in the video signal and other clock signals. .

  Next, the operation of the backlight 2 configured as described above will be described.

  The block luminance value calculation processing unit 51 sets the luminance values (11e), (12e),... (58e) of the representative light source 5A according to the luminance signal detected from the video signal. For example, the luminance of the representative light source 5A is set to increase as the luminance signal increases.

  The luminance value calculation processing unit 52 calculates the luminance value of each light source 5B by interpolation and extrapolation based on the calculated representative luminance values (11e), (12e),... (58e) of the representative light source 5A. To do.

For example, in the example shown in FIG. 7, the luminance values (a) and (b) and the luminance values (a) and (d) of the unit light source block <11> are calculated by extrapolation. Light source (11a _LS), the position is on the extended line of a straight line connecting the representative light source (11e _LS) and (12e _LS). For example, the luminance value (11a) is calculated by extrapolation based on the representative luminance values (11e) and (12e) of the unit light source blocks <11> and <12> according to the solid arrow A. Further, for example, the luminance value (11c) is calculated by interpolation based on (11b) and (12a) obtained as a result of the extrapolation calculation according to the broken arrow B.

  Hereinafter, the representative luminance values of the unit light source blocks <11>, <12>,... <58> are simply expressed as (11), (12),.

Examples of extrapolation and interpolation calculation are shown below. “f” represents a function and is an extrapolation correction function. In the case of linear extrapolation, f (x) = x. In the following calculation formula, for example, the reason for multiplying (22)-(11) by 1/3 is that the distance between the representative light sources (22e _LS ) and (11e _LS ) is a distance corresponding to three of the one light source 5. It is.

<Example of extrapolation calculation>
(11a) = f ((11)-{(22)-(11)} / 3)
(11b) = f ((11)-{(21)-(11)} / 3)
(11d) = f ((11)-{(12)-(11)} / 3)
(12a) = f ((12)-{(23)-(12)} / 3)
(12b) = f ((12)-{(22)-(12)} / 3)
(12c) = f ((12)-{(21)-(12)} / 3)
(21g) = f ((21)-{(12)-(21)} / 3)
(58i) = f ((58)-{(47)-(58)} / 3).

<Example of interpolation calculation>
(11c) = f ((11b) + {(12a)-(11b)} / 2)
(11g) = f ((11d) + {(21a)-(11d)} / 2)
(11i) = f ((11) + {(22)-(11)} / 3)
(22a) = f ((11) + {(22)-(11)}. 2/3)
(21h) = f ((21) + {(31)-(21)} / 3).

  The function f is not limited to a linear function, and may be a quadratic or higher function, an exponential function, a logarithmic function, a hyperbolic function, a trigonometric function, or other functions.

  FIG. 8 is a diagram illustrating a correction function f (x) by extrapolation and interpolation. The vertical axis represents luminance values (representative luminance values and other luminance values), and the horizontal axis represents, for example, each representative light source 5A of unit light source blocks <11>, <12>, and <13> and other light sources 5B ( This corresponds to the position of the horizontal column of luminance values (see FIG. 5).

  The unit light source block 6 (<11>, <12) is set when each luminance value of the light source 5 is set by the calculated value f (x) or f (x) = x by extrapolation and interpolation calculation. >, <13>), a sharper luminance change is suppressed than when the luminance value is set, and it can be seen that the luminance change is smooth.

  As described above, the light emission luminance setting unit 8 is a light source other than the representative light source 5A so as to relieve a sharp luminance change at the boundary between the unit light source blocks 6 based on the representative luminance value for each unit light source block 6. Each luminance value can be set.

  Next, the number of the light sources 105 included in the unit light source block 106 and the irradiation area S on the liquid crystal panel 104 by the light of the entire light source 105 will be described using a comparative example shown in FIG.

  Since the light emitted from each light source 105 to the liquid crystal panel 104 is diffused light, when the distance between the unit light source block 106 and the liquid crystal panel 104 is reduced, the irradiation area S on the liquid crystal panel 104 of the light from each light source 105 is reduced. Becomes smaller. Therefore, the irradiation area S on the liquid crystal panel 104 by the light of the entire light source 105 included in the unit light source block 106 is also reduced. In that case, if the number of the light sources 105 included in the unit light source block 106 is increased, the reduced irradiation area S can be a desired area.

In Figure 9, when the distance between the unit light source block 106 and the liquid crystal panel 104 is t _1, the light from one light source 105 disposed on the unit light source blocks 106, a desired irradiation area S is secured . When the distance between the unit light source block 106 and the liquid crystal panel 104 is t ₂ which is smaller than t ₁ , a desired irradiation area S is secured by the light from the entire four light sources 105 arranged in the unit light source block 106. Has been. Further, when the distance between the unit light source block 106 and the liquid crystal panel 104 is t ₃ which is smaller than t ₂ , a desired irradiation area S is obtained by the light from all nine light sources 105 arranged in the unit light source block 106. Is secured. In other words, the smaller the distance between the unit light source block 106 and the liquid crystal panel 104, the greater the number of light sources 105 included in the unit light source block 106 in order to ensure a desired irradiation area S.

FIG. 10 is a diagram illustrating a state in which three unit light source blocks 106 including nine light sources 105 illustrated in FIG. 9 are arranged to emit light to the liquid crystal panel 104. As shown in FIG. 9, the distance between the unit light source block 106 and the liquid crystal panel 104 is t ₃ .

  FIG. 10A shows a liquid crystal of light from the entire three unit light source blocks 106 in a case where the luminance of the light from each light source 105 included in the three unit light source blocks 106 is almost the maximum value. 6 is a graph showing light intensity in an irradiation region on the panel 104. FIG. 10B is also a graph showing the light intensity in the irradiation region on the liquid crystal panel 104 of the light from the entire three unit light source blocks 106 arranged side by side. In FIG. 10B, the luminance of the light from each light source 105 included in the central unit light source block 106 among the three unit light source blocks 106 arranged is almost the maximum value. In addition, the luminance of light from each light source 105 included in the unit light source blocks 106 adjacent to the central unit light source block 106 among the three unit light source blocks 106 arranged is approximately 50% of the maximum value. It has become.

  In the case of FIG. 10A, as shown in the graph, the light intensity in the irradiation region on the liquid crystal panel 104 of the light from the entire three unit light source blocks 106 is substantially uniform at the maximum value. .

  In the case of FIG. 10B, the light intensity in the irradiation area on the liquid crystal panel 104 of the light from the entire three unit light source blocks 106 is in the form shown in the graph. That is, on the liquid crystal panel 104, in the region that receives light from the central unit light source block 106, light having the maximum intensity is received from the central unit light source block 106, and the central unit light source is surrounded around the region. Light having intensity smaller than the maximum value is received from the unit light source blocks 6 on both sides of the block 106. In this case, the luminance of the screen of the liquid crystal panel 104 is divided into a region that receives light from the unit light source block 106 at the center of the three unit light source blocks 106 and a region that receives light from the adjacent unit light source blocks 106. Are displayed differently.

  FIG. 11 is a plan view showing the screen 112 of the liquid crystal panel 104. In FIG. 11, the luminance on the screen 112 when the light intensity in the irradiation region on the liquid crystal panel 104 of the light from the entire three unit light source blocks 106 is the graph of FIG. 10B. Is schematically shown.

  As shown in the graph of FIG. 10B, the light intensity at the boundary between the central unit light source block 106 and the adjacent unit light source blocks 106 of the three unit light source blocks 106 arranged abruptly changes. Yes. For this reason, the luminance on the screen 112 due to the light from each unit light source block 106 also changes sharply. Therefore, on the screen 112, as shown in FIG. 11, the luminance change may be displayed in stages.

  In order to solve such a problem, for example, in the method of calculating the luminance value of each of 360 light sources, the processing capability by the software for real-time processing becomes a problem.

  On the other hand, in the backlight 2 of the present embodiment, such a steep luminance change at the boundary between the adjacent unit light source blocks 6 can be alleviated as shown in FIG. In addition, since the calculation process of interpolation and extrapolation can be realized mainly by simple hardware, the processing time can be greatly improved, and the number of light sources 5 in the unit light source block 6 can be easily increased. Can do.

  FIG. 13 is a block diagram illustrating a main part of a control unit of a display device according to another embodiment. In FIG. 9, description of the same blocks as those in the embodiment shown in FIG. 4 will be simplified or omitted, and different points will be mainly described.

The control unit of this display device shows an example in which the number of drivers included in the backlight driving unit 60 is reduced. For example, one driver (11 _DRV ), (12 _DRV ),...・ (58 _DRV ) is provided. That is, in the embodiment shown in FIG. 4, 360 drivers are provided, but in the embodiment shown in FIG. 13, 40 drivers are provided. For example, one driver drives the light sources 5A and 5B using the luminance values of the light sources 5A and 5B (see FIG. 5) set by the light emission luminance setting unit 8.

  In the control unit of the display device, for example, a vertical synchronization signal (frame synchronization signal) included in the video signal is detected, and the detected vertical synchronization signal is input to the light emission luminance setting unit 8, and the backlight is transmitted via the frequency converter 54. Input to the drive unit. For the time division processing, the frequency converter 54 generates a pulse signal in which the frequency of the pulse signal obtained based on the vertical synchronization signal (vertical synchronization frequency) is increased to the frequency corresponding to the number of time divisions.

  In FIG. 9, the block configurations of the block luminance value calculation processing unit 51, the luminance value calculation processing unit 52, the total luminance value output unit 53 and the like included in the light emission luminance setting unit 8 are substantially the same as those shown in FIG. Is the same. The block luminance value calculation processing unit 51, the luminance value calculation processing unit 52, and the total luminance value output unit 53 execute processing based on a vertical synchronization signal, other clock signals, and the like.

Each driver (11 _DRV ), (12 _DRV ),... (58 _DRV ) uses each of the nine luminance values of 40 groups output from the total luminance value output unit 53, and thereby each light source (11 a _LS). ), (11b _LS ),... (58i _LS ) are driven. For example, the driver paying attention to (11 _DRV), the driver (11 _DRV), depending on the timing of the pulse signal of the converted frequency by the frequency converter 54, when the light source is divided _{(11a LS), (11b LS} ) ... (11i _LS ) is driven.

  By such time division driving, the number of drivers can be reduced, and the cost can be reduced.

  Embodiments according to the present invention are not limited to the embodiments described above, and other various embodiments are conceivable.

In the above embodiment, one representative light source 5A is provided for each unit light source block 6, but two or more representative light sources may be provided. For example, when focusing on the unit light source block <11>, two light sources (11b _LS ) and (11e _LS ) or three light sources (11b _LS ), (11e _LS ) and (11h _LS ) are representative. It may be a light source. Alternatively, for example, when more than nine light sources 5 are included in one unit light source block 6, the designer can appropriately set the number and position of representative light sources.

  Examples of the electronic device on which the display device according to the present embodiment is mounted include a liquid crystal TV, a PC (Personal Computer), a PDA (Personal Digital Assistant), a mobile phone, a car navigation system, and the like.

It is a figure which shows the structure of the display apparatus which concerns on one Embodiment of this invention. It is a top view which shows the structure of a backlight. It is a block diagram which shows the structure of the control part of a display apparatus. FIG. 4 is a block diagram illustrating configurations of a light emission luminance setting unit, a backlight driving unit, and the like illustrated in FIG. 3. It is a top view which shows the arrangement | positioning relationship between the representative light source in one unit light source block, and the other light source. It is a figure which shows the arrangement | positioning relationship of 40 unit light source blocks. It is a figure which shows the arrangement | positioning relationship of each light source in nine unit light source blocks at the upper left among 40 unit light source blocks. FIG. 8 is a diagram illustrating a correction function f (x) by extrapolation and interpolation. It is a figure for demonstrating the number of the light sources contained in a unit light source block, and the irradiation area on the liquid crystal panel by the light of the whole light source. 10 is a graph showing light intensity (or luminance) when three unit light source blocks including nine light sources shown in FIG. 9 are arranged to emit light to a liquid crystal panel. It is a top view which shows the screen of a liquid crystal panel. It is a graph which shows the intensity | strength (or brightness | luminance) of light at the time of making each light source contained in the unit light source block shown in FIG. 10 into the light source which concerns on this embodiment. It is a block diagram which shows the principal part of the control part of the display apparatus which concerns on other embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 2 ... Backlight 3 ... Control part 4 ... Liquid crystal panel 5 ... Light source 5A ... Representative light source 5B ... Light sources other than a representative light source 6 ... Unit light source block 8 ... Light emission luminance setting part 9 ... Liquid crystal panel drive control part 10, 60 ... Backlight Drive unit 51 ... Block luminance value calculation processing unit 52 ... Luminance value calculation processing unit 53 ... Total luminance value output unit 100 ... Display device

Claims (6)

A plurality of light source units each having a unit light source block configured as one block, and the plurality of unit light source blocks arranged to correspond to a screen of a display panel;
In accordance with a video signal to be displayed on the screen, a representative luminance for each unit light source block, and a block representative luminance value that is a luminance of at least one representative light source among the plurality of light sources is set. Based on the set block representative luminance value, setting means for setting each luminance value of a light source other than the representative light source among the plurality of light sources;
And a driving unit that drives each light source of the light source unit based on the set block representative brightness value and each brightness value of a light source other than the set representative light source. The backlight device according to claim 1,
Light sources other than the representative light source are arranged around the representative light source in the one unit light source block,
The said setting means is a backlight apparatus which calculates | requires each said luminance value of light sources other than the said representative light source by the calculation by the interpolation and extrapolation based on the set block representative luminance value. The backlight device according to any one of claims 1 and 2,
The driving means has a driver for driving the representative light source and a light source other than the representative light source for each unit light source block,
At least one of the drivers drives the light source other than the representative light source and the representative light source in a time-sharing manner according to the set block representative luminance value and the luminance values of light sources other than the set representative light source. Backlight device. A display panel having a screen and displaying video on the screen in accordance with an input video signal;
A plurality of light source units having a unit light source block configured as one block, and a plurality of the unit light source blocks arranged to correspond to the screen, and according to the video signal, A block representative luminance value, which is a representative luminance for each unit light source block and is the luminance of at least one representative light source among the plurality of light sources, is set, and based on the set block representative luminance value, the plural Among the light sources, a setting means for setting each luminance value of a light source other than the representative light source, and the set block representative luminance value and each luminance value of a light source other than the set representative light source, And a backlight having driving means for driving each light source. A display panel having a screen and displaying video on the screen in accordance with an input video signal;
A plurality of light source units having a unit light source block configured as one block, and a plurality of the unit light source blocks arranged to correspond to the screen, and according to the video signal, A block representative luminance value, which is a representative luminance for each unit light source block and is the luminance of at least one representative light source among the plurality of light sources, is set, and based on the set block representative luminance value, the plural Among the light sources, a setting means for setting each luminance value of a light source other than the representative light source, and the set block representative luminance value and each luminance value of a light source other than the set representative light source, An electronic device equipped with a display device comprising: a backlight having a driving means for driving each light source. Driving a backlight having a light source unit in which a plurality of light sources have unit light source blocks configured as one block, and the plurality of unit light source blocks are arranged to correspond to a screen of a display panel A method,
In accordance with a video signal to be displayed on the screen, a representative luminance for each unit light source block, and a block representative luminance value that is a luminance of at least one representative light source among the plurality of light sources is set.
Based on the set block representative luminance value, set each luminance value of a light source other than the representative light source among the plurality of light sources,
A backlight driving method for driving each light source of the light source unit based on the set block representative brightness value and each brightness value of a light source other than the set representative light source.