The present invention relates to a liquid crystal display device which performs a display using local dimming.
In recent years, a liquid crystal display device has been generally used which is capable of realizing a high image quality thereby performing display using a local dimming technique.
As illustrated in the drawing, full HD image data (image data of a 2K1K size) is input to a local dimming control circuit 50, and backlight luminance data, which is the luminance data of each area in the backlight is calculated in the local dimming control circuit 50, and is output to a backlight driving circuit 51. In addition, in the local dimming control circuit 50, gradation data of each pixel for the full HD (2K1K size) is calculated using the backlight luminance data and the above-described full HD image data, and is output to a liquid crystal driving circuit 52.
In other words, the local dimming control circuit 50 is configured to determine the gradation data of each pixel by adding the backlight luminance data.
There is no particular problem in a case where the image data of the 2K1K size as the image size that may be processed is input to the local dimming control circuit 50 in which the image size that may be processed is fixed to the 2K1K size.
Incidentally, the image data of the 2K1K size is image data of approximately horizontal 2000 pixels×vertical 1000 pixels. Specifically, a representative example is image data of 1920×1080.
However, in a case where, for example, UHD image data (image data of a 4K2K size) as an image size that is not assumed is input to the local dimming control circuit 50 in which the image size that may be processed is fixed to the 2K1K size, there is a need for providing an additional processing circuit (a backlight luminance distribution estimation circuit, a liquid crystal luminance calculation circuit or the like) to the outside in order to perform the process, calculate the gradation data of each pixel for the UHD (4K2K size) and output the gradation data to the liquid crystal driving circuit, which causes complexity in the process and increase in the process time and cost.
Incidentally, the image data of the 4K2K size is image data of approximately horizontal 4000 pixels×vertical 2000 pixels. Specifically, a representative example is image data of 3840×2160 dots, 4096×2160 dots, 4096×1776 dots, 3300×2160 dots and the like.
As described above, the local dimming control circuit 50 is configured to calculate the gradation data of each pixel using the backlight luminance data and the full HD image data. Meanwhile, the backlight luminance data is also required for each pixel unit in terms of granularity, and a memory is required for storing each data, but in general, the image size that may be processed is fixed in the specification so as to reduce the cost.
As illustrated in
Further, the image data of the 2K1K size converted by the down-converter 53 is input to the local dimming control circuit 50, the luminance data (a control block size of the local dimming) of each area of the backlight and the gradation data (2K1K size) of each pixel are calculated in the local dimming control circuit 50, and the unnecessary gradation data (2K1K size) of each pixel is discarded without being used.
Incidentally, the backlight luminance data is output in the block size of the backlight (for example, in a case where the division number is horizontally 24 divisions and vertically 12 divisions, the data size of 24×12 blocks) and is supplied to the backlight driving circuit 51, and is also supplied to a backlight luminance distribution estimation circuit 54.
In the backlight luminance distribution estimation circuit 54, the backlight luminance data of the block size is converted to the backlight luminance distribution data (4K2K size) by estimation of luminance distribution (superimposing the luminance distribution on the entire block in accordance with the luminance distribution of each block using the input backlight luminance data of the block size and backlight illumination distribution of one block that is measured or estimated in advance), and the backlight luminance distribution data is supplied to a liquid crystal gradation calculation circuit 55.
Then, the liquid crystal gradation calculation circuit 55 calculates the gradation data (4K2K size) of each pixel based on the image data of the 4K2K size input to the down-converter 53 and the backlight luminance distribution data (4K2K size) to be supplied from the backlight luminance distribution estimation circuit 54, and the gradation data is supplied to the liquid crystal driving circuit 56.
Hereinafter, a description will be made regarding a method of the related art in which the liquid crystal gradation data of the 4K2K size is obtained from the input image data of the 4K2K size with reference to
First, the input image data of the 4K2K size is reduced into reduced image data for local dimming (2K1K size) by the down-converter 53.
Incidentally, a method that is generally known may be employed as a reduction method, and any method of a nearest neighbor method, a linear interpolation method, quadratic interpolation, cubic interpolation, an average pixel method, and the like may be employed. It is possible to obtain a reduced result VI1 by any one of the above-described methods (for example, the linear interpolation method) from 4K2K-size input image data Vi1 to Vi4, and it is possible to obtain a reduced result VI2 from 4K2K-size input image data Vi5 to Vi8 in the same manner.
As described above, it is configured to obtain one reduced image data for the local dimming by reducing pixel data having an aspect ratio of 2×2 of the 4K2K-size input image data.
Then, reduced image data for the local dimming VI1, VI2 and so on are processed by the local dimming control circuit 50, and backlight luminance data VB1, VB2 and so on are output.
Then, 4K2K-size backlight luminance distribution data Vd1, Vd2, . . . , Vd8 and so on are obtained by the backlight luminance distribution estimation circuit 54 from the illumination distribution of one block obtained from the backlight luminance data VB1, VB2 and so on, which are the luminance values of one block of the backlight sought from the pixel group of the input image data of 2×2.
Further, it is configured to calculate the final 4K2K-size liquid crystal gradation data Vo1, Vo2, . . . , Vo8 and so on by the liquid crystal gradation calculation circuit 55 based on the luminance value corresponding to each pixel position of the backlight luminance distribution data Vd1, Vd2, . . . , Vd8 and so on, and the corresponding gradation value of each pixel of the 4K2K-size input image data Vi1 to Vi8 and so on.
Meanwhile,
As illustrated in
Further, the control device 101 is provided with a preprocessing circuit 110, dividing circuits 111a and 111b, upscaling circuits 112a to 112d, a down-converter 113, compensating circuits 114a to 114d, a liquid crystal driving circuit 115, a display map generating circuit 116, an LED resolution signal generating circuit 117, an luminance distribution data generating circuit 118, an LED driving circuit 119, and switches SW1 and SW2a to SW2d.
In such a circuit configuration, in a case where an image having a size larger than the image size that may be processed by the LED resolution signal generating circuit 117 is input, the compensating circuits 114a to 114d which calculate the gradation data to be output to the liquid crystal driving circuit 115 are capable of processing the image size that may be processed by the LED resolution signal generating circuit 117, and are configured to receive the input image divided by the dividing circuit 111a or the input image output from the dividing circuit 111b and processed by the upscaling circuits 112a to 112d, and the backlight luminance distribution data created by the luminance distribution data generating circuit 118.
Further, the backlight luminance distribution input to the compensating circuits 114a to 114d uses data from the common LED resolution signal generating circuit 117, and thus, it is possible to realize a high image quality using continuous emission distribution and the gradation data in accordance with the continuous emission distribution as compared to a simple multi-display.
Patent Literature 1: International Publication “WO 2009/157221 (published on Dec. 30, 2009)”
However, in the above-described circuit configuration of the related art as illustrated in
Accordingly, in such a circuit configuration of the related art, there is a problem that the circuit size is increased and it takes a great deal of time for calculation. In particular, for the backlight luminance distribution data of the 4K2K size, it is necessary to superimpose the illumination distribution of one block in accordance with the luminance data of each backlight for the number of blocks by granularity of the 4K2K size, and it requires a great deal of calculation.
In addition, the liquid crystal display device 100 described in Patent Literature 1 has the following problem.
It is necessary to enlarge the luminance distribution data, output from the luminance distribution data generating circuit 118 illustrated in
The present invention has been made in view of the above-described problems, and an object thereof is to provide a liquid crystal display device capable of processing an image having an unassumed image size, and further, reducing the storage area, the processing load and the circuit size.
To solve the above-described problems, a liquid crystal display device of the present invention includes: a local dimming control circuit configured to output first-size liquid crystal gradation data in accordance with first-size input image data, and output backlight luminance data; a liquid crystal panel; a backlight; at least one or more a down-converter configured to convert second-size image data, which is larger than the first-size image data, to the first-size image data; a luminance ratio calculation circuit configured to calculate a gradation ratio by dividing the first-size liquid crystal gradation data output from the local dimming control circuit by the first-size image data output from the down-converter, each of the data corresponding to the same position on a display face; and a gradation conversion circuit configured to calculate second-size liquid crystal gradation data by multiplying a plurality of data, which corresponds to neighboring positions on the display face and selected from the second-size image data in accordance with a reduction rate between the second-size image data and the first-size image data by the gradation ratio at the corresponding position on the display face.
As described above, the liquid crystal display device of the present invention is configured to include: at least one or more a down-converter configured to convert second-size image data, which is larger than the first-size image data, to the first-size image data; a luminance ratio calculation circuit configured to calculate a gradation ratio by dividing the first-size liquid crystal gradation data output from the local dimming control circuit by the first-size image data output from the down-converter, each of the data corresponding to the same position on a display face; and a gradation conversion circuit configured to calculate second-size liquid crystal gradation data by multiplying a plurality of data, which corresponds to neighboring positions on the display face and selected from the second-size image data in accordance with a reduction rate between the second-size image data and the first-size image data by the gradation ratio at the corresponding position on the display face.
Therefore, it is possible to realize the liquid crystal display device that may process the image having the unassumed image size, and further, reduce the storage area, the processing load and the circuit size.
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, dimensions, materials, shapes, relative arrangement or the like of components described in the embodiment are only an embodiment, and it should not be interpreted such that the scope of the invention is limited thereto.
Incidentally, in each embodiment hereinafter, a description will be made exemplifying a liquid crystal display device provided with a general LED backlight or the like, however, the present invention may be employed in, for example, a multicolor liquid crystal display device of a surface emitting type in which an ultraviolet light-emitting diode (such as an LED) is used as an excitation light source and a light-emitting position in a visually-recognizable color is not a backlight but a surface, or the like.
Hereinafter, a liquid crystal display device 1 according to an embodiment of the present invention will be described with reference to
As illustrated in
Further, the control section 2 is provided with a down-converter 7, a local dimming control circuit 8 and an upscaling control circuit 9.
There are two types of sizes of image data handled in the control section 2 of the liquid crystal display device 1. One of them is a size that the local dimming control circuit 8 may process, and will be referred to as an LD size (Local Dimming size) in the description, and the description will be made exemplifying a 2K1K size as an example thereof. Specifically, a representative example is image data of 1920×1080.
Meanwhile, the control section 2 of the liquid crystal display device 1 is assumed to be capable of processing image data of a size larger than the LD size. The size larger than the LD size will be referred to as an I/O size (Input Output size) in the description, and the description will be made exemplifying a 4K2K size as an example thereof.
In the control section 2 of the liquid crystal display device 1 according to the present embodiment, which performs a local dimming process, in a case where the I/O size is larger than the LD size, it is possible to reduce a storage area such as a frame memory, a processing load and a circuit size compared to a configuration of the related art.
Hereinafter, the control section 2 of the liquid crystal display device 1 will be described.
An input image (image data of a 4K2K size) in the drawing is the image data to be input to the control section 2 of the liquid crystal display device 1. If a description is made for a case of a television, a main image engine such as a tuner is positioned in front of the control section 2, and the image data of the 4K2K size as the input image is output from the main image engine.
The image data of the 4K2K size output from the main image engine is input to the down-converter 7, and output as reduced image data for the local dimming having a 2K1K size that may be handled in the local dimming control circuit 8.
Further, the local dimming control circuit 8 is configured to increase a dynamic range of an output image by allowing luminance of the backlight 4 to be changed locally in accordance with content of the input image, for example, by lowering the luminance of the backlight 4 for a dark part in the image in a case of display in which a display device of a non-emitting type such as the liquid crystal panel 6 is applied with the luminance by the backlight 4 which is provided independently from the back surface of the liquid crystal panel being divided into several blocks capable of adjusting the luminance.
The local dimming control circuit 8 calculates luminance data of each block of the backlight 4 divided into the blocks based on the content of the image data when receiving the reduced image data for the local dimming having the 2K1K size (for example, a data size of 24×12 in a case where a division number is horizontally 24 divisions and vertically 12 divisions).
Then, the local dimming control circuit 8 superimposes illumination distribution of the backlight of one block, which is measured or estimated in advance, on the luminance data of each block, calculates gradation of each pixel of the liquid crystal panel 6 that the original input image may reproduce, and calculates liquid crystal gradation data of the 2K1K size.
The luminance data of each block output from the local dimming control circuit 8 is input to the backlight driving circuit 3 and causes lighting of the backlight 4.
Meanwhile, since the liquid crystal gradation data of the 2K1K size output from the local dimming control circuit 8 is not the 4K2K size which is the size to be finally displayed on the liquid crystal panel 6, the liquid crystal gradation data of the 2K1K size is input to the upscaling control circuit 9 in order to be enlarged into the 4K2K size.
The upscaling control circuit 9 calculates liquid crystal gradation data of the 4K2K size, which is the same size as the image data, based on three types of the image data, that is, the image data (the reduced image data for the local dimming having the 2K1K size and the liquid crystal gradation data of the 2K1K size) before and after the processing in the local dimming control circuit 8, and the initial input image data (the image data of the 4K2K size), and output the result to the liquid crystal driving circuit 5.
Further, the liquid crystal driving circuit 5 outputs the received liquid crystal gradation data of the 4K2K size to the liquid crystal panel 6. Incidentally, the lighting of the backlight 4 and the display of the liquid crystal panel 6 are configured such that the display is performed being synchronized therebetween for a frame by a synchronization circuit (not illustrated).
As illustrated in
The local dimming control circuit 8 first calculates the luminance data of each block of the backlight 4 divided into the blocks based on the content of the image data when receiving the image data of the 2K1K size.
Then, the local dimming control circuit 8 superimposes the illumination distribution of the backlight of one block, which is measured or estimated in advance, on the luminance data of each block, calculates the gradation of each pixel of the liquid crystal panel 6 in which the original input image may be reproduced, and calculates the liquid crystal gradation data of the 2K1K size.
Further, the liquid crystal gradation data of the 2K1K size is input to the upscaling control circuit 9, upscaled by horizontally and vertically doubling, and is output as the liquid crystal gradation data of the 4K2K size.
As illustrated in
Any generally-known method of a nearest neighbor method, a linear interpolation method, quadratic interpolation, cubic interpolation, an average pixel method, and the like may be employed as a reduction method. The result obtained by reducing Vi1 to Vi4 among the image data of the 4K2K size by any one of the above-described methods is referred to as VI1, and result obtained by reducing Vi5 to Vi8 among the image data of the 4K2K size by any one of the above-described methods is referred to as VI2. Hereinafter, in the same manner, pixels of the aspect ratio 2×2 of the image having the 4K2K size are reduced thereby obtaining 2K1K-size reduced image data for the local dimming VI1, VI2, and so on.
Further, the 2K1K-size reduced image data for the local dimming VI1, VI2 and so on are processed by the local dimming control circuit 8 and backlight luminance data VB1, VB2, and so on, and 2K1K-size liquid crystal gradation data Vo1, Vo2 and so on are output. Incidentally, content of an internal process of the local dimming control circuit 8 will be described later.
The backlight luminance data of a block of the backlight, which is obtained from the reduced image data for the local dimming of a certain, for example, n×m size by the local dimming control circuit 8 is referred to as VBi. Meanwhile, 2K1K-size liquid crystal gradation data, which is obtained by the local dimming control circuit 8 in the same manner, corresponding to VI1 is referred to as VO1, and 2K1K-size liquid crystal gradation data corresponding to VIi is referred to as Voi, in general.
Then, when the 2K1K-size liquid crystal gradation data VOi is obtained, the final 4K2K-size liquid crystal gradation data Vo(4×i-3), Vo(4×i-2), Vo(4×i-1) and Vo(4×i) may be obtained by Formulas (1) to (4) to be described below using the 2K1K-size liquid crystal gradation data VOi, the 2K1K-size reduced image for the local dimming VIi and data of the 4K2K-size image data Vi(4×i-3), Vi(4×i-2), Vi(4×i-1) and Vi(4×i).
Vo(4×i-3)=C×Vi(4×i-3) Formula (1)
Vo(4×i-2)=C×Vi(4×i-2) Formula (2)
Vo(4×i-1)=C×Vi(4×i-1) Formula (3)
Vo(4×i)=C×Vi(4×i) Formula (4)
In the above-described Formulas (1) to (4), a gradation ratio C=VOi/VI1.
As described above, in the control section 2 of the liquid crystal display device 1, the final 4K2K-size liquid crystal gradation data is obtained by a simple process.
When it is described with a specific example, in a case where Vi1, Vi2, Vi3 and Vi4 are respectively 128, 140, 116 and 136, for example, VI1 becomes 130 by using an average thereof. Further, when the liquid crystal gradation data VO1 to be output from the local dimming control circuit 8 at the time is 240, the 4K2K-size liquid crystal gradation data Vo1, Vo2, Vo3 and Vo4 to be output from the upscaling control circuit 9 are respectively as follows (a decimal is set to be rounded down, but a real number may be used).
Vo1=128×240/130=236,
Vo2=140×240/130=258,
Vo3=116×240/130=214,
Vo4=136×240/130=251,
The gradation ratio of each pixel at the time almost maintains a ratio of the input image data of the 4K2K size, and it may be confirmed that there is no problem in terms of accuracy from the following numbers.
Vi2/Vi3=140/116=1.2
Vo2/Vo3=258/214=1.2
Incidentally, in the above description, although it is confirmed that the gradation ratio of each pixel of the 4K2K-size liquid crystal gradation data almost maintains the ratio of the input image data of the 4K2K size by comparing only Vi2/Vi3 and Vo2/Vo3, the confirmation is possible by comparing, for example, Vi1/Vi2 and Vo1/Vo2.
As illustrated in
In the luminance ratio calculation circuit 10, it is possible to obtain the gradation ratio C=VOi/VIi using the 2K1K-size reduced image for the local dimming VIi and the 2K1K-size liquid crystal gradation data VOi.
Further, in the gradation conversion circuit 11, it is possible to obtain the 4K2K-size liquid crystal gradation data Vo1, Vo2 and so on using the gradation ratio C obtained by the luminance ratio calculation circuit 10 and the 4K2K-size input image data Vi1, Vi2 and so on.
As illustrated in
The backlight 4 (illustrated in
The luminance data of one block of the backlight 4 obtained from the image data of a certain, for example, total n×m size having vertical n and horizontal m is referred to as VBi (in the drawings, VB1, VB2 and the like).
Meanwhile, there are various calculation methods for the 2K1K-size liquid crystal gradation data, and for example, the 2K1K-size liquid crystal gradation data may be obtained by increasing or decreasing each pixel value of the image data input to the local dimming control circuit 8 in accordance with the average luminance value of the above-described backlight luminance data VB1, VB2 and so on (for example, if the average value is low, it becomes dark, and thus, the number of pixels is increased as the inverse number).
In the backlight luminance distribution estimation circuit 13 according to the present embodiment, the backlight luminance distribution data of the block size is superimposed on the illumination distribution of one block, which is determined in advance by measurement or estimation, and the backlight luminance distribution in which the image data is enlarged to have the resolution of 2K1K is obtained (in the drawings, Vd1, Vd2 and the like). Further, in the liquid crystal gradation calculation circuit 14, the 2K1K-size liquid crystal gradation data VOi (in the drawings, Vo1, Vo2 and the like) is obtained by performing increase or decrease in accordance with the luminance value of a pixel unit (for example, each gradation value of the 2K1K-size reduced image data for the local dimming VI1, VI2 and so on are divided by each luminance value of the 2K1K-size backlight luminance distribution data Vd1, Vd2 and so on, or the gradation value of the liquid crystal panel 6 in association with the luminance value is stored in a look up table, and the gradation data is obtained from the association).
As described above, the control section 2 of the liquid crystal display device 1 according to the present embodiment is provided with the down-converter 7, local dimming control circuit 8 that may calculate the 2K1K-size liquid crystal gradation data VOi from the 2K1K-size reduced image for the local dimming VIi, and the upscaling control circuit 9 which performs relatively simple calculation as illustrated in
Meanwhile, in the configuration of the related art illustrated in
Accordingly, in the configuration of the related art illustrated in
In other words, in a case of a liquid crystal panel, as the configuration of the related art illustrated in
First, it is necessary to perform a superimposing step for the times of (the number of blocks of the backlight×the illumination distribution granularity of one block), a step of storing the superimposition result, and a step of calculating the liquid crystal gradation data for the times of the pixel numbers of the 4K2K size (dividing, referring to a table or the like).
Meanwhile, in the control section 2 of the liquid crystal display device 1 according to the present embodiment, the gradation ratio C=VOi/VIi may be obtained from the 2K1K-size reduced image for the local dimming VIi and the 2K1K-size liquid crystal gradation data VOi in the luminance ratio calculation circuit 10, and the 4K2K-size liquid crystal gradation data Vo1 Vo2 and so on may be obtained from the gradation ratio C obtained by the luminance ratio calculation circuit 10 and the 4K2K-size input image data Vi1, Vi2 and so on, in the gradation conversion circuit 11.
As described above, in the configuration of the related art, in a case where an image size out of specification is input, backlight data having the same granularity as the final output gradation data in order to obtain the final output gradation data. However, in the liquid crystal display device 1 according to the present embodiment, only the original input data (the 4K2K-size input image data), data (the 2K1K-size reduced image data for the local dimming) reduced to a size of specification in order to be input to the local dimming control circuit, and the gradation data (the 2K1K-size liquid crystal gradation data) output from the local dimming control circuit are used, and the backlight luminance data is not used. Further, the final output gradation data (the 4K2K-size liquid crystal gradation data) is calculated from the data (the 2K1K-size reduced image data for the local dimming) input to the local dimming control circuit, and the original input data (the 4K2K-size input image data) multiplied by a ratio between the data input to the local dimming control circuit and the output gradation data (the 2K1K-size liquid crystal gradation data) at the same pixel position. Accordingly, it is possible to reduce the storage area, the processing load and the circuit size as compared to the related art, and further, it is possible to obtain the gradation ratio equal to or greater than that in the configuration of the related art.
In addition, a description will be made as follows by comparing the configuration of the related art illustrated in
In the liquid crystal display device 1 according to the present embodiment, the data input to the liquid crystal driving circuit, which corresponds to a liquid crystal driving circuit 115 of the configuration of the related art illustrated in
Next, a second embodiment of the present invention will be described with reference to
As illustrated in
As illustrated in
The 4K2K-size input image input to the upscaling control circuit 9a is branched inside the upscaling control circuit 9a and input also to the down-converter 15 and the 2K1K-size reduced image for the local dimming VIi, which is necessary for obtaining the gradation ratio C, is generated. Further, in the subsequent luminance ratio calculation circuit 10, the gradation ratio C is calculated from the 2K1K-size reduced image for the local dimming VIi and the 2K1K-size liquid crystal gradation data received from the local dimming control circuit 8. Further, in the gradation conversion circuit 11, the final 4K2K-size liquid crystal gradation data is calculated from the calculated gradation ratio C and the original 4K2K-size input image, and is output.
Next, a third embodiment of the present invention will be described with reference to
As illustrated in
According to such a configuration, it is possible to form the simpler upscaling control circuit 9b, and further, a degree of freedom increases in selecting the arrangement position of the luminance ratio calculation circuit 10.
As illustrated in
Further, in the gradation conversion circuit 11 provided in the upscaling control circuit 9b, the final 4K2K-size liquid crystal gradation data is calculated from the gradation ratio C and the original 4K2K-size input image, and is output.
The present invention is not limited to each embodiment described above, and various modifications may be possible in the scope described in the claim. Further, an embodiment obtained by appropriately combining technical means disclosed, respectively, in the different embodiments may be included in the technical scope of the present invention.
A liquid crystal display device according to a first aspect of the present invention is a liquid crystal display device including: a local dimming control circuit configured to output first-size liquid crystal gradation data in accordance with first-size input image data, and output backlight luminance data; a liquid crystal panel; a backlight; at least one or more a down-converter configured to convert second-size image data, which is larger than the first-size image data, to the first-size image data; a luminance ratio calculation circuit configured to calculate a gradation ratio by dividing the first-size liquid crystal gradation data output from the local dimming control circuit by the first-size image data output from the down-converter, each of the data corresponding to the same position on a display face; and a gradation conversion circuit configured to calculate second-size liquid crystal gradation data by multiplying a plurality of data, which corresponds to neighboring positions on the display face and selected from the second-size image data in accordance with a reduction rate between the second-size image data and the first-size image data by the gradation ratio at the corresponding position on the display face.
According to the configuration described above, since the local dimming control circuit configured to calculate the first-size liquid crystal gradation data from the first-size image data which is smaller than the second-size image data, and the luminance ratio calculation circuit and the gradation conversion circuit configured to perform relatively simple calculation are provided, it is possible to realize the liquid crystal display device capable of processing an image having an image size that is not assumed, and further, reducing the storage area, the processing load and the circuit size.
The liquid crystal display device according to a second aspect of the present invention may be configured such that the number of the down-converter is one, and the first-size image data output from the down-converter is supplied to the local dimming control circuit and the luminance ratio calculation circuit.
According to the configuration described above, it is possible to use only one down-converter.
The liquid crystal display device according to a third aspect of the present invention may be configured such that the down-converter includes a first down-converter and a second down-converter, and the first-size image data output from the first down-converter is supplied to the local dimming control circuit and the first-size image data output from the second down-converter is supplied to the luminance ratio calculation circuit.
According to the configuration described above, it is possible to supply the first-size image data to the local dimming control circuit and the luminance ratio calculation circuit via the down-converters different from one another.
The liquid crystal display device according to a fourth aspect of the present invention may be configured such that the luminance ratio calculation circuit and the gradation conversion circuit are provided in an upscaling control circuit.
According to the configuration described above, it is possible to provide the upscaling control circuit with a relatively simple configuration.
The liquid crystal display device according to a fifth aspect of the present invention may be configured such that the luminance ratio calculation circuit, the gradation conversion circuit and the second down-converter are provided in an upscaling control circuit.
According to the configuration described above, since the upscaling control circuit also includes the second down-converter and there is no need to input the output from the first down-converter to the upscaling control circuit, the timing synchronization is not necessary so that it is possible to provide a simpler configuration.
The liquid crystal display device according to a sixth aspect of the present invention may be configured such that the upscaling control circuit includes the gradation conversion circuit.
According to the configuration described above, it is possible to provide the upscaling control circuit with further simple configuration, and the degree of freedom increases in selecting the arrangement position of the luminance ratio calculation circuit as compared to a case where the luminance ratio calculation circuit is provided in the upscaling control circuit.
The present invention may be employed to a liquid crystal display device.
Number | Date | Country | Kind |
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2013-009551 | Jan 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/084072 | 12/19/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/115449 | 7/31/2014 | WO | A |
Number | Name | Date | Kind |
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20070047019 | Toyoda | Mar 2007 | A1 |
20090184915 | Tsai | Jul 2009 | A1 |
20110037784 | Shiomi | Feb 2011 | A1 |
20110037785 | Shiomi | Feb 2011 | A1 |
20150049132 | Johnson | Feb 2015 | A1 |
Number | Date | Country |
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2009157221 | Dec 2009 | WO |
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20150348469 A1 | Dec 2015 | US |