JP4631163B2 - Display control device and image display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides a plasma-driven liquid crystal display (PALC) for supplying an image signal every frame to an image display device having a response time corresponding to a luminance gradation level, and a liquid crystal television (LCDTV). ), A display control apparatus and an image display apparatus suitable for application to a liquid crystal projector (LCDPJ) or the like.
[0002]
[Prior art]
In recent years, liquid crystal display panels that are thinner than cathode ray tubes (CRTs) can be made larger in size with improved production yield, and analog terrestrial broadcast programs can be similar to televisions equipped with ordinary CRTs. It has come to receive and display.
[0003]
A liquid crystal driving circuit is connected to this type of liquid crystal display panel, and a predetermined driving voltage is generated based on the input video data of the luminance gradation level, and this driving voltage is applied to the liquid crystal display panel to obtain the luminance gradation. Control is performed. In this luminance gradation control, a driving voltage can be generated by sufficiently following the luminance gradation level by the liquid crystal driving circuit, and this driving voltage can be applied to the liquid crystal display panel.
[0004]
[Problems to be solved by the invention]
By the way, according to the liquid crystal display device according to the conventional example, there are cases where the liquid crystal cannot sufficiently follow the driving voltage due to the change pattern of the luminance gradation level of the video data in response to the transmitted light of the liquid crystal. This is considered to depend on the return time of the twist of the liquid crystal.
[0005]
For this reason, when fast-moving video data, for example, a video with a sharp change in luminance, is input to the liquid crystal drive circuit, the luminance change, that is, the image in which the liquid crystal cannot follow the drive voltage and the outline is blurred. There's a problem.
[0006]
To solve this problem, Japanese Patent Publication No. 2708746, which is a technical document, describes a liquid crystal control circuit. According to this liquid crystal control circuit, the stored gradation data A of the frame immediately before the current frame is compared with the input gradation data B of the current frame, and if B> A, the predicted corrected gradation data When A <B, the input gradation data B is output as it is. Therefore, there is a problem that the luminance gradation control greatly depends on the prediction accuracy.
[0007]
Japanese Patent Application Laid-Open No. 4-288589, which is a technical document, describes a liquid crystal display device. According to this liquid crystal display device, the level fluctuation in the time axis direction of each pixel is detected from the image signal of the field image immediately before the current frame and the input image signal of the current frame, and the high frequency band is detected based on the detected level. By controlling the enhancement filter, the response speed at the intermediate gradation is increased. Therefore, there is a problem that the luminance gradation control largely depends on the characteristics of the high frequency enhancement filter.
[0008]
Therefore, the present invention solves such a conventional problem, and can sufficiently cope with a fast-moving video signal even when a liquid crystal display panel is used as an image display means, and a video with a sharp change in luminance. It is an object of the present invention to provide a display control device and an image display device that can prevent a phenomenon that the outline of a video is blurred even when an image is input.
[0009]
[Means for Solving the Problems]
The above-described problem is in an apparatus that controls display of an image display unit that has different response times according to luminance gradations based on an image signal input for each frame.
First storage means for storing at least the image signal of the frame immediately before the current frame, the luminance gradation of the image signal of the previous frame stored in the first storage means, and the image of the current frame Solved by a display control device comprising a correcting means for calculating a difference from a luminance gradation of a signal and calculating and outputting a correction value corresponding to the difference to a luminance gradation of an image signal of a current frame. The
[0010]
According to the first display control apparatus of the present invention, when the display control is performed on the image display unit having different response times according to the luminance gradation based on the image signal input for each frame, the first storage is performed. The means stores the image signal of the previous frame of the current frame. The correction means calculates the difference between the luminance gradation of the image signal of the previous frame and the luminance gradation of the image signal of the current frame, and the correction value corresponding to this difference becomes the luminance gradation of the image signal of the current frame. After the calculation, the corrected image signal of the frame is output.
[0011]
Therefore, when the luminance gradation of the image signal of the current frame is lower than the luminance gradation of the image signal of the previous frame, the luminance is further reduced by subtracting the correction value from the luminance gradation of the image signal of the frame. If the image signal of the current frame is higher than the luminance gradation of the image signal of the previous frame, or if the luminance gradation of the image signal of the current frame is higher than the luminance gradation of the image signal of the previous frame, It is possible to output an image signal having a higher luminance gradation obtained by adding a correction value to the tone. Thereby, even when a liquid crystal display panel is used for the image display unit, it is possible to sufficiently cope with a video signal that moves quickly.
[0012]
A second display control device according to the present invention is a device for controlling display of an image display unit having a response time different according to the luminance gradation of an image signal based on an image signal input for each frame, and at least the current frame. First storage means for storing the image signal of the previous frame, the luminance gradation of the image signal of the previous frame stored in the first storage means and the luminance scale of the image signal of the current frame And second storage means for outputting an image signal of a luminance gradation after the correction of the frame using the key as an address.
[0013]
According to the second display control device of the present invention, when display control is performed on an image display unit having a response time that differs according to the luminance gradation of the image signal based on the image signal input for each frame, One storage means stores an image signal of the previous frame of the current frame. The second storage means uses the luminance gradation of the image signal of the previous frame and the luminance gradation of the image signal of the current frame stored in the first storage means as addresses, and the corrected luminance scale of the frame. A tone image signal is read out.
[0014]
Therefore, when the luminance gradation of the image signal of the current frame is lower than the luminance gradation of the image signal of the previous frame, the luminance is further reduced by subtracting the correction value from the luminance gradation of the image signal of the frame. If the image signal of the current frame is higher than the luminance gradation of the image signal of the previous frame, or if the luminance gradation of the image signal of the current frame is higher than the luminance gradation of the image signal of the previous frame, It is possible to output an image signal having a higher luminance gradation obtained by adding a correction value to the tone. Thereby, even when a liquid crystal display panel is used for the image display unit, it is possible to sufficiently cope with a fast-moving video signal without imposing a burden on other control systems. In addition, it can be configured at a lower cost than the first display control device.
[0015]
The first image display device according to the present invention includes an image display means for displaying an image based on a drive voltage applied every frame, a display drive means for supplying a drive voltage to the image display means, and the display drive. Display control means for controlling the input / output of the means, and the display control means includes at least first storage means for storing an image signal of a frame immediately preceding the current frame, and the first storage means. The difference between the stored luminance gradation of the image signal of the previous frame and the luminance gradation of the image signal of the current frame is calculated, and the correction value corresponding to the difference is used as the luminance gradation of the image signal of the current frame. It has a correction means for calculating and outputting.
[0016]
According to the first image display device of the present invention, since the above-described first display control device is applied, even when a liquid crystal panel is used as the image display means, without burdening other control systems, It is possible to sufficiently cope with a fast moving video signal.
[0017]
In addition, even when an image with a large luminance change is input, the luminance change, that is, a phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the image is blurred can be prevented.
[0018]
The second image display device according to the present invention includes an image display means for displaying an image based on a drive voltage applied every frame, a display drive means for supplying a drive voltage to the image display means, and the display drive. Display control means for controlling the input / output of the means, and the display control means includes at least first storage means for storing an image signal of a frame immediately preceding the current frame, and the first storage means. Second storage means for outputting an image signal having a corrected luminance gradation of the frame by using the luminance gradation of the stored image signal of the previous frame and the luminance gradation of the image signal of the current frame as addresses. It is characterized by having.
[0019]
According to the second image display device of the present invention, since the above-described second display control device is applied, even when a liquid crystal panel is used as the image display means, without burdening other control systems, It is possible to sufficiently cope with a fast moving video signal.
[0020]
In addition, even when an image with a large luminance change is input, the luminance change, that is, a phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the image is blurred can be prevented. Further, it can be constructed at a lower cost than the second image display device.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Subsequently, an embodiment of a display control device and an image display device according to the present invention will be described with reference to the drawings.
(1) First embodiment
FIG. 1 is a block diagram illustrating a configuration example of an image display apparatus 201 to which the display control apparatus 101 according to the first embodiment of the present invention is applied.
In this embodiment, a correction unit is provided in the case where display control is performed on an image display unit whose response time varies depending on the luminance gradation based on an image signal input for each frame. The difference between the luminance gradation and the luminance gradation of the image signal of the current frame is calculated, the correction value corresponding to this difference is calculated as the luminance gradation of the image signal of the current frame, and the liquid crystal panel is used for the image display unit. In this case, it is possible to sufficiently cope with a fast moving video signal, and to prevent a phenomenon that the outline of the video is blurred even when a video with a sharp change in luminance is input (first). Image display device).
[0022]
A first image display apparatus 201 shown in FIG. 1 is an apparatus to which the first display control apparatus 101 according to the present invention is applied, and image display means 12 having different response times according to luminance gradation is input for each frame. The display is controlled based on the image signal SIN. The image display device 201 includes a display control device 101, display drive means 11, and image display means 12.
[0023]
The display control device 101 controls the input / output of the display driving means 11, and at least the first storage means 1 is provided to store the image signal SIN of the frame immediately before the current frame. . As the storage means 1, a memory (RAM) capable of randomly accessing information is used.
[0024]
A correction unit 3 is connected to the storage unit 1 to calculate a difference between the luminance gradation of the image signal SIN of the previous frame and the luminance gradation of the image signal SIN of the current frame, and corresponds to the difference. The correction value is calculated and output to the luminance gradation of the image signal SIN of the current frame. This is to improve the response speed associated with the change in the gradation level of each frame of the image signal SIN in the image display means 12. A CPU (central processing unit) is used for the correction means 3.
[0025]
In this correction means 3, when the difference between the luminance gradation of the image signal SIN of the previous frame stored in the storage means 1 and the luminance gradation of the image signal SIN of the current frame is almost zero, the image of the current frame The signal SIN is output as it is. Regarding the specific luminance gradation range of the image signal SIN, the luminance gradation of the image signal SIN of the current frame is lower than the luminance gradation of the image signal SIN of the previous frame stored in the storage unit 1 The image signal SIN having a lower luminance gradation obtained by subtracting the correction value from the luminance gradation of the image signal SIN of the current frame is output.
[0026]
When the luminance gradation of the image signal SIN of the current frame is higher than the luminance gradation of the image signal SIN of the previous frame stored in the storage unit 1, the luminance scale of the image signal SIN of the current frame is high. An image signal SIN with a higher luminance gradation obtained by adding a correction value to the tone is output. In this display control apparatus 101, the second storage means 2 is connected to the correction means 3, and the correction value corresponding to this difference is stored. A read only memory (ROM) is used for the storage means 2. As the correction value, an optimum value is obtained in advance according to the type of the image display means 12, and this correction value is made into a reference table and stored in a ROM or the like.
[0027]
The display drive means 11 is connected to the correction means 3, generates a drive voltage VOUT based on the corrected image signal SOUT, and supplies the drive voltage VOUT to the image display means 12. For example, when a liquid crystal display panel is used, a scanning electrode driving IC or a signal electrode driving IC is used as the display driving unit 11 depending on the display format of the image display unit 12. An image display means 12 is connected to the display drive means 11 so that an image is displayed based on a drive voltage VOUT applied every frame.
[0028]
FIG. 2 is a luminance gradation level diagram showing an example of correction processing in the correction means 3. FIG. 3 is an image diagram showing an example of the contents of the reference table in the storage means (ROM) 2.
The vertical axis shown in FIG. 2 is the luminance gradation level L of the image signal SIN input to the correction means 3, and the horizontal axis is time t. L1 is the luminance gradation level of the image signal SIN of the frame before the current frame. L2 is the luminance gradation level of the image signal SIN of the current frame. Lε is a difference between the luminance gradation level L1 of the image signal SIN of the frame before the current frame and the luminance gradation level L2 of the image signal SIN of the current frame, and is calculated by the equation (1).
Lε = L1-L2 (1)
[0029]
Lr is a correction value for the luminance gradation level L2 of the image signal SIN of the current frame, and is read from the ROM shown in FIG. In this ROM, when the difference Lε between the luminance gradation level L1 of the image signal SIN of the previous frame and the luminance gradation level L2 of the image signal SIN of the current frame is almost zero, the image signal of the current frame In order to output SIN as it is, “0” is described as the correction value.
[0030]
When the luminance gradation level L2 of the image signal SIN of the current frame is lower than the luminance gradation level L1 of the image signal SIN of the frame before the current frame, that is, the calculation result of the expression (1) is Lεi> 0. In this case, -Lr1, -Lr2, -Lr3, -Lri, ... -Lrn are prepared as negative correction values. On the contrary, when the luminance gradation level L2 of the image signal SIN of the current frame is higher than the luminance gradation level L1 of the image signal SIN of the previous frame, that is, the calculation result of the expression (1) is Lεi. When <0, + Lr1, + Lr2, + Lr3, + Lri,... + Lrn are prepared as positive correction values (see FIG. 3).
[0031]
Further, L2 ′ shown in FIG. 2 is the luminance gradation level of the image signal SIN of the current frame after correction, and is calculated by the equation (2).
L2 ′ = L2 + Lri (2)
That is, when the luminance gradation level L2 of the image signal SIN of the current frame is lower than the luminance gradation level L1 of the image signal SIN of the previous frame, the negative correction value -Lri is applied. The image signal SIN having a lower luminance gradation obtained by subtracting the correction value Lri from the luminance gradation level L2 of the image signal SIN of the current frame is output.
[0032]
Further, when the luminance gradation level L2 of the image signal SIN of the current frame is higher than the luminance gradation level L1 of the image signal SIN of the previous frame, the positive correction value + Lri is applied. An image signal SIN with a higher luminance gradation obtained by adding the correction value + Lri to the luminance gradation level L2 of the image signal SIN of the current frame is output.
[0033]
Subsequently, an operation example of the first image display apparatus 201 will be described. FIG. 4 is a flowchart showing an operation example of the first image display apparatus 201. In this embodiment, it is assumed that display control is performed on the image display means 12 having different response times according to the luminance gradation based on the image signal SIN input every frame.
[0034]
In the image display device 201, the correction value ± Lri as shown in FIG. 3 is stored in the storage means 2 shown in FIG. 1, and the luminance gradation level L1 of the image signal SIN of the frame before the current frame and the current frame are displayed. When the difference Lε with respect to the luminance gradation level L2 of the image signal SIN is almost zero, the image signal SIN of the current frame is output as it is and compared with the luminance gradation level L1 of the image signal SIN of the frame before the current frame. When the luminance gradation level L2 of the image signal SIN of the current frame is low or high, it is assumed that correction is performed with the correction value ± Lri.
[0035]
With this as a correction condition, the image signal SIN is input to the storage means 1 and the correction means 3 in step A1 of the flowchart shown in FIG. Thereafter, the process proceeds to step A2 where the correction means 3 calculates the difference Lε between the luminance gradation level L1 of the image signal SIN of the frame before the current frame and the luminance gradation level L2 of the image signal SIN of the current frame by the equation (1). ).
[0036]
Thereafter, the process proceeds to step A3, and the correction value Lri corresponding to the difference Lε is read from the storage unit 2 to the correction unit 3. Then, the process proceeds to step A4, where the correction means 3 calculates the luminance gradation level L2 ′ of the image signal SIN of the current frame according to the equation (2) using the correction value Lri.
[0037]
Thereby, the image display means 12 is driven based on the luminance gradation level L2 ′ of the image signal SIN of the current frame corrected in step A5. For example, the display drive unit 11 generates a drive voltage VOUT based on the corrected image signal SOUT, and supplies the drive voltage VOUT to the image display unit 12. The image display means 12 displays an image based on the drive voltage VOUT applied every frame.
[0038]
As described above, according to the image display apparatus 201 to which the display control apparatus 101 according to the first embodiment of the present invention is applied, it is compared with the luminance gradation level L1i of the image signal SIN of the frame immediately before the current frame. When the luminance gradation level L2i of the image signal SIN of the current frame is low, an image signal SOUT having a lower luminance gradation obtained by subtracting the correction value Lri from the luminance gradation level L2i of the image signal SIN of the frame is output. If the luminance gradation level L2i of the image signal SIN of the current frame is higher than the luminance gradation level L1i of the image signal SIN of the previous frame, the luminance gradation of the image signal SIN of the frame It is possible to output an image signal SOUT having a higher luminance gradation obtained by adding the correction value Lri to the level L2i.
[0039]
Thereby, even when a liquid crystal display panel is used as the image display means 12, it is possible to sufficiently cope with a video signal that moves quickly. In addition, even when an image with a large luminance change is input, the luminance change, that is, a phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the image is blurred can be prevented.
[0040]
(2) Second embodiment
FIG. 5 is a block diagram illustrating a configuration example of an image display apparatus 202 to which the display control apparatus 102 according to the second embodiment of the present invention is applied.
In this embodiment, the image signal SIN is divided into upper bits and lower bits, and only the upper bits are corrected to reduce the memory capacity of the storage means compared to the first embodiment.
[0041]
An image display device 202 illustrated in FIG. 5 includes a display control device 102, a display driving unit 11, and an image display device 12. In addition, since the thing with the same code | symbol and the same name as 1st Embodiment has the same function, the description is abbreviate | omitted.
[0042]
The display control device 102 controls input / output of the display driving means 11 and is provided with at least a first storage means 4 for storing the image signal SIN of the upper bits of the frame preceding the current frame. The The storage unit 4 uses a RAM having a smaller memory capacity than that of the first embodiment.
[0043]
Correction means 6 is connected to this storage means 4, and the luminance gradation level L1 of the upper bit image signal SIN of the previous frame and the luminance gradation level L2 of the upper bit image signal SIN of the current frame. The difference is calculated, and the correction value Lri corresponding to the difference is calculated and output to the luminance gradation level L2 of the higher-order bit image signal SIN of the current frame. This is to improve the response speed associated with the change in the gradation level of each frame of the image signal SIN in the image display means 12. A CPU (central processing unit) is used for the correction means 6.
[0044]
In this correction means 6, the difference between the luminance gradation level L1 of the upper bit image signal SIN of the previous frame stored in the storage means 4 and the luminance gradation level L2 of the upper bit image signal SIN of the current frame is calculated. If it is almost zero, the image signal SIN of the upper bits of the current frame is output as it is.
[0045]
As for the specific luminance gradation level range of the image signal SIN, the image of the upper bit of the current frame compared to the luminance gradation level L1 of the upper bit image signal SIN of the previous frame stored in the storage means 4 When the luminance gradation level L2 of the signal SIN is low, an upper bit image signal SIN having a lower luminance gradation obtained by subtracting the correction value Lri from the luminance gradation level L2 of the upper bit image signal SIN of the current frame is output. Is made.
[0046]
When the luminance gradation level L2 of the upper bit image signal SIN of the current frame is higher than the luminance gradation level L1 of the upper bit image signal SIN of the previous frame stored in the storage unit 4 The upper bit image signal SOUT having a higher luminance gradation level obtained by adding the correction value Lri to the luminance gradation level L2 of the upper bit image signal SIN of the current frame is output.
[0047]
In this display control apparatus 102, the second storage means 5 is connected to the correction means 6 so as to store the correction value Lri corresponding to this difference. As the storage means 6, a ROM having a smaller memory capacity than that of the first embodiment is used. As the correction value Lri, an optimum value is obtained in advance according to the type of the image display means 12, and this correction value Lri is made into a reference table and stored in a ROM or the like.
[0048]
In this display control device 102, the adding means 7 is connected to the correcting means 6, and the upper bit image signal SIN of the lower bits of the current frame before the correction calculation is added to the upper bit image signal SIN of the current frame after the correction calculation. Is output. The image signal SOUT of the current frame after the addition is output to the display driving unit 11. The display driving unit 11 generates a driving voltage VOUT based on the corrected image signal SOUT of the luminance gradation level L2i ′ and supplies the driving voltage VOUT to the image display unit 12. The image display means 12 displays an image based on the drive voltage VOUT applied every frame.
[0049]
As described above, according to the image display device 202 according to the second embodiment, the upper bit of the current frame is compared with the luminance gradation level L1 of the image signal SIN of the upper bit of the previous frame of the current frame. When the luminance gradation level L2 of the image signal SIN is low, an upper bit image signal SOUT having a lower luminance gradation obtained by subtracting the correction value Lri from the luminance gradation level L2 of the upper bit image signal SIN of the frame is output. If the luminance gradation level L2 of the upper bit image signal SIN of the current frame is higher than the luminance gradation level L1 of the upper bit image signal SIN of the previous frame, An upper bit image signal SOUT having a higher luminance gradation obtained by adding the correction value Lri to the luminance gradation level L2 of the upper bit image signal SIN can be output.
[0050]
Thereby, even when a liquid crystal display panel is used as the image display means 12, it is possible to sufficiently cope with a video signal that moves quickly. In addition, even when an image with a large luminance change is input, the luminance change, that is, a phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the image is blurred can be prevented.
[0051]
(3) Third embodiment
FIG. 6 is a block diagram showing a configuration example of an image display apparatus 203 to which the display control apparatus 103 as the third embodiment according to the present invention is applied.
In this embodiment, when display control is performed on the image display unit 12 having a different response time according to the luminance gradation level based on the image signal SIN input for each frame, the correction unit described in the first embodiment. Instead, a read-only storage means such as a correction value look-up table is provided, and this storage means stores an image signal of an optimal brightness gradation level that has been corrected and obtained in advance and is stored in the current frame. The luminance gradation level L1 of the image signal SIN of the previous frame and the luminance gradation level L2 of the image signal SIN of the current frame are used as addresses to read out the corrected luminance gradation image signal SOUT. Even when a video with a sharp change in luminance is input, the burden on the calculation control system can be further reduced (second image display device).
[0052]
The image display device 203 shown in FIG. 6 is an application of the second display control device according to the present invention, and the image display means 12 having different response times according to the luminance gradation of the image signal SIN is input for each frame. The display is controlled based on the image signal SIN. The image display device 203 includes a display control device 103, a display driving unit 11, and an image display device 12. In addition, since the thing with the same code | symbol and the same name as 1st Embodiment has the same function, the description is abbreviate | omitted.
[0053]
This display control device 103 controls the input / output of the display driving means 11 and is provided with at least a first storage means 4 for storing the image signal SIN of the frame immediately before the current frame. The
[0054]
The storage means 4 is connected to a second read-only storage means 8, and the luminance gradation level L 1 of the image signal SIN of the frame immediately before the current frame stored in the storage means 4 and the current frame Using the luminance gradation level L2 of the image signal SIN as an address, the corrected luminance gradation image signal SOUT of the frame is read out from the second storage means 8 and output.
[0055]
In this example, a correction value Lri is obtained in advance corresponding to the response time of the image display means 11, and further, the correction value Lri is used, and the correction of the frame is performed by the equation (2) described in the first embodiment. The image signal SOUT of the luminance gradation level L2 ′ in the entire range from the later 0 gradation to the n gradation is calculated. This calculation is performed in accordance with the display characteristics of the image display means 11 every time the image display means 11 is manufactured. Therefore, the image display means 11 and the storage means 8 storing the correction value are preferably traded as a set. Of course, trading these as a set is not limited.
[0056]
FIG. 7 is an image diagram showing an example of the content of the image signal SOUT of the corrected luminance gradation level L2i ′ stored in the storage means 8. For the image signal SOUT after the correction of the frame, the luminance gradation level L2i ′ in the entire range from the 0th gradation to the nth gradation is obtained.
[0057]
According to the content example of the image signal SOUT of the corrected luminance gradation level L2i ′ shown in FIG. 7, the horizontal axis indicates the luminance gradation levels L11 to L1n (n of the image signal SIN of the frame immediately before the current frame. : Gradation), and the luminance gradation levels L21 to L2n (n: gradation) of the image signal SIN of the current frame are plotted on the vertical axis. The image signal SOUT of the luminance gradation level L2 ′ in the entire range from the 0th gradation to the nth gradation is applied to each lattice portion of the matrix formed by the vertical and horizontal luminance gradation levels L11 to L1n and the luminance gradation levels L21 to L2n. It is made to memorize.
[0058]
In FIG. 7, the image signal SIN from the 0th gray level to the nth gray level of the current frame is stored as it is in the lattice portion on the diagonal line A0 from the upper left 0th gray level to the lower right nth gray level. This is to cope with a case where the difference between the luminance gradation level L1i of the image signal SIN of the frame immediately before the current frame and the luminance gradation level L2i of the image signal SIN of the current frame is substantially zero.
[0059]
In the grid portion of the upper right region A1, which is an example of a specific luminance gradation range of the image signal SIN with reference to the grid portion of the diagonal line A0, the 0 gradation calculated from L2i ′ = L2i−Lr is changed to n gradation. The image signal SOUT of the luminance gradation level L2i ′ in the entire range is stored. This is to cope with the case where the luminance gradation level L2i of the image signal SIN of the current frame is lower than the luminance gradation level L1i of the image signal SIN of the frame immediately before the current frame. As a result, in the left region A1, an image signal SOUT having a luminance gradation level lower than that of the image signal SIN of the current frame is output.
[0060]
Further, in the lattice portion of the lower left region A2 with reference to the lattice portion of the diagonal line A0, the image signal SOUT of the luminance gradation level L2i ′ of the entire range from 0 gradation to n gradation calculated by L2i ′ = L2i + Lr is obtained. It is made to memorize. This is to cope with the case where the luminance gradation level L2i of the image signal SIN of the current frame is higher than the luminance gradation level L1i of the image signal SIN of the frame immediately before the current frame. As a result, in the left region A2, the image signal SOUT having a luminance gradation level higher than that of the image signal SIN of the current frame is output.
[0061]
Next, an operation example of the image display device 203 will be described. FIG. 8 is an image diagram showing an example of reading the image signal SOUT of the luminance gradation level L2i ′ after correction in the storage means 8. FIG. 9 is a flowchart illustrating an operation example of the image display device 203.
In this embodiment, it is assumed that display control is performed on the image display means 12 having different response times according to the luminance gradation based on the image signal SIN input every frame.
[0062]
In the image display device 203, the image signal SOUT of the corrected luminance gradation level L2i ′ as shown in FIG. 7 is stored in the storage means 8 shown in FIG. 6, and the image signal of the frame immediately before the current frame is stored. It is assumed that the corrected luminance gradation image signal SOUT is read using the luminance gradation level L1 of SIN and the luminance gradation level L2 of the image signal SIN of the current frame as addresses.
[0063]
With this as a correction condition, the image signal SIN is input to the storage means 1 and the storage means 8 in step B1 of the flowchart shown in FIG. Thereafter, the process proceeds to step B2 where the luminance gradation level L1 of the image signal SIN of the frame immediately before the current frame and the luminance gradation level L2 of the image signal SIN of the current frame are used as addresses for the corrected luminance scale. The tone image signal SOUT is read out.
[0064]
For example, when the luminance gradation level of the image signal SIN of the frame before the current frame shown in FIG. 8 is L1i and the luminance gradation level of the image signal SIN of the current frame is L22 (L22 <L1i), the frame The image signal SOUT is output as a corrected image signal SOUT of the luminance gradation level calculated by L2i ′ = L22−Lr (see the upper right area).
[0065]
Further, when the luminance gradation level of the image signal SIN of the frame before the current frame shown in FIG. 8 is L1i and the luminance gradation level of the image signal SIN of the current frame is L2n-2 (L2n-2> L1i). In addition, the image signal SOUT of the frame is output as a corrected image signal SOUT of the luminance gradation level calculated by L2i ′ = (L2n−2) −Lr (see the lower left area).
[0066]
Thereafter, the process proceeds to step B3, and the image display means 12 is driven based on the luminance gradation level L2 ′ of the corrected image signal SIN of the current frame. For example, the display drive unit 11 generates a drive voltage VOUT based on the corrected image signal SOUT, and supplies the drive voltage VOUT to the image display unit 12. The image display means 12 displays an image based on the drive voltage VOUT applied every frame.
[0067]
As described above, according to the image display device 203 to which the display control device 103 according to the third embodiment of the present invention is applied, the comparison is made with the luminance gradation level L1i of the image signal SIN of the frame immediately before the current frame. If the luminance gradation level L2i of the image signal SIN of the current frame is low, the image signal SOUT having a lower luminance gradation level obtained by subtracting the correction value Lri from the luminance gradation level L2i of the image signal SIN of the current frame is directly selected. When the luminance gradation level L2i of the image signal SIN of the current frame is higher than the luminance gradation level L1i of the image signal SIN of the previous frame The image signal SOUT of higher luminance gradation obtained by adding the correction value Lri to the luminance gradation level L2i of the image signal SIN of the frame directly from the storage means 8 to the display driving means 1 It is possible to output to.
[0068]
Thereby, it is possible to sufficiently cope with a fast moving video signal even when a liquid crystal display panel is used as the image display unit 12 without depending on the correction unit as in the first embodiment. In addition, even when an image with a large luminance change is input, the burden on the arithmetic and control system can be reduced. In addition, the phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the image is blurred can be prevented. A liquid crystal television or the like can be configured at a lower cost than the first image display device 201.
[0069]
(4) Fourth embodiment
FIG. 10 is a block diagram showing a configuration example of an image display device 204 to which the display control device 104 as the fourth embodiment according to the present invention is applied.
In this embodiment, the image signal SIN is divided into upper bits and lower bits, and correction is applied to only the upper bits, and the image signal SOUT of the luminance gradation level L2i ′ in the entire range from 0 gradation to n gradation after correction. The image signal SOUT is stored in a read-only storage means such as a correction value lookup table, and the luminance gradation level L1i of the upper bit image signal SIN of the frame immediately before the current frame and the current frame Even when an image signal SOUT having a corrected luminance gradation is read out by using the luminance gradation level L2i of the higher-order bit image signal SIN as an address and an image having a sharp luminance change is input, the burden on the arithmetic control system Can be further reduced. In addition, the memory capacity of the storage means is reduced as compared with the third embodiment.
[0070]
An image display device 204 illustrated in FIG. 10 includes a display control device 104, a display driving unit 11, and an image display device 12. In addition, since the thing of the same code | symbol and the same name as 3rd Embodiment has the same function, the description is abbreviate | omitted.
[0071]
The display control device 104 controls the input / output of the display driving means 11 and is provided with at least the first storage means 4 so as to store the image signal SIN of the upper bits of the previous frame. The The storage unit 4 uses a RAM having a smaller memory capacity than that of the third embodiment.
[0072]
The storage means 4 is connected to a second read-only storage means 9, and the luminance gradation level L 1 i of the higher-order image signal SIN of the frame immediately before the current frame stored in the storage means 4 and the current Using the luminance gradation level L2i of the image signal SIN of the upper bit of the frame as an address, the upper bit image signal SOUT of the luminance gradation after the correction of the frame is read out from the storage means 9 and output.
[0073]
According to the content example of the storage means 9, the upper bit from the 0th gray level to the nth gray level of the current frame is displayed in the diagonal grid line from the upper left 0th gray level to the lower right nth gray level shown in FIG. The image signal SIN is stored as it is. The grid portion in the upper right area shown in FIG. 7 stores the image signal SOUT of the upper bits of the luminance gradation level L2i ′ in the entire range from 0 gradation to n gradation calculated by L2i ′ = L2i−Lr. It is made like. In the lattice portion of the lower left region shown in FIG. 7, the image signal SOUT of the upper bits of the luminance gradation level L2i ′ in the entire range from 0 gradation to n gradation calculated by L2i ′ = L2i + Lr is stored. Made.
[0074]
In this display control device 104, the adding means 7 is connected to the storage means 9 shown in FIG. 10, and the lower bit image signal SOUT of the current frame before the correction calculation is added to the upper bit image signal SOUT of the current frame after the correction calculation. Is output. The image signal SOUT of the current frame after the addition is output to the display driving unit 11. The display driving unit 11 generates a driving voltage VOUT based on the corrected image signal SOUT of the luminance gradation level L2i ′ and supplies the driving voltage VOUT to the image display unit 12. The image display means 12 displays an image based on the drive voltage VOUT applied every frame.
[0075]
As described above, according to the image display device 204 according to the fourth embodiment, the higher-order bit of the current frame is compared with the luminance gradation level L1i of the upper-order image signal SIN of the previous bit of the current frame. When the luminance gradation level L2i of the image signal SIN is low, the upper bit image signal SOUT having a lower luminance gradation obtained by subtracting the correction value Lri from the luminance gradation level L2i of the upper bit image signal SIN of the frame directly. The data can be output from the storage means 9 to the adding means 7.
[0076]
When the luminance gradation level L2i of the upper bit image signal SIN of the current frame is higher than the luminance gradation level L1i of the upper bit image signal SIN of the previous frame, the upper bit of the frame The higher-order bit image signal SOUT having a higher luminance gradation obtained by adding the correction value Lri to the luminance gradation level L2i of the image signal SIN can be directly output from the storage means 9 to the adding means 7.
[0077]
Therefore, even when a liquid crystal display panel is used as the image display means 12, it is possible to sufficiently cope with a fast moving video signal as in the third embodiment. Moreover, even when a video with a large luminance change is input, the luminance change, that is, the phenomenon that the outline of the video is blurred because the liquid crystal cannot follow the applied voltage is prevented without imposing a burden on the calculation control system. it can. Compared with the third embodiment, the memory capacity of the storage means 4 and the storage means 9 can be reduced.
[0078]
(5) Examples
FIG. 11 is a block diagram showing a configuration example of a liquid crystal television 300 as an embodiment according to the present invention.
In this embodiment, a liquid crystal television 300 as an example of an image display device is configured, and the display control device 103 described in the third embodiment is applied to this display control means. That is, the display control means is provided with a ROM for a correction value lookup table. In this ROM, luminance gradation levels L2i ′ in the entire range from 0 gradation to n = 248 gradations are obtained and stored for the corrected video data DOUT of the frame.
[0079]
Then, the luminance gradation level L1i of the image signal SIN of the frame immediately before the current frame and the luminance gradation level L2i of the image signal SIN of the current frame are used as addresses to obtain the corrected luminance gradation image signal SOUT. Even when a video with a sharp change in luminance is input in such a manner as to be read, the burden on the arithmetic control system can be further reduced.
[0080]
A liquid crystal television 300 shown in FIG. 11 receives, for example, analog terrestrial broadcast waves and displays a broadcast program on the liquid crystal display panel 26. The liquid crystal television 300 has an antenna 21 and receives broadcast radio waves from the Yagi antenna 21 and the like. A tuner & IF amplifier 22 is connected to the antenna 21 to detect video signals and audio signals of R (red), G (green), and B (blue) by performing signal processing on NTSC broadcast radio waves. An audio amplifier circuit 23 is connected to one of the tuner & IF amplifier 22, and the audio signal is amplified and output to the speaker 25.
[0081]
A video amplifier circuit 24 is connected to the other of the tuner & IF amplifier 22 to amplify R, G, B video signals (hereinafter simply referred to as an image signal SIN) and to separate a synchronization signal SY. The display control means 10 and the display driving means 11 are connected to the video amplification circuit 24. The display control device 103 described in the third embodiment is applied to the display control means 10, and an analog / digital converter (hereinafter referred to as an A / D converter 31), a frame memory 32, a ROM 33, and a CPU 34 are provided. Yes.
[0082]
The A / D converter 31 is connected to the video amplification circuit 24, and converts the image signal SIN from analog to digital to output R, G, B video data DIN. The A / D converter 31 is connected to a frame memory 32 as an example of a first storage unit, and stores video data DIN of the frame immediately before the current frame.
[0083]
The A / D converter 31 and the frame memory 32 are connected to a ROM 33 for a correction value look-up table as an example of the second storage means, and the image of the frame before the current frame stored in the frame memory 32. Using the luminance gradation level L1i of the data DIN and the luminance gradation level L2i of the video data DIN of the current frame as addresses, the video data DOUT of the corrected luminance gradation level of the frame is read from the ROM 33 and output. To be made.
[0084]
In the lookup table of the ROM 33, every time the luminance gradation level L2i changes, the luminance gradation close to the optimum luminance gradation level L2i ′, which is supposed to be displayed with no blur on the liquid crystal display panel 26. It is only necessary to store the video data DOUT corrected so as to obtain the level.
[0085]
A CPU 34 is connected to the frame memory 32 and the ROM 33, and writing / reading control of the frame memory 32 and the ROM 33 is performed based on the horizontal synchronizing signal HS and the vertical synchronizing signal VS. The CPU 34 generates a write / read control signal WE and a read permission signal OE based on the horizontal synchronization signal HS and the vertical synchronization signal VS, and outputs the write / read control signal WE to the frame memory 32, so that the frame immediately before the current frame is generated. Control the writing and reading of the video data DIN and output the read permission signal OE to the ROM 33 to control the timing of taking in the video data DIN of the current frame and the timing of reading out the corrected video data DOUT of one frame. To be made. In this example, the correction calculation in the CPU 34 can be omitted.
[0086]
Further, the display driving means 11 is connected to the video amplification circuit 24. The display driving unit 11 includes a horizontal synchronizing circuit 41, a vertical synchronizing circuit 42, a scan electrode driving circuit 43, and a signal electrode driving circuit 44. The scan electrode driving circuit 43 and the signal electrode driving circuit 44 are connected to an active matrix type liquid crystal display panel 26 as an example of an image display means.
[0087]
A horizontal synchronization circuit 41 is connected to one of the video amplification circuits 24, and a horizontal synchronization signal HS is detected from the synchronization signal SY. A vertical synchronization circuit 42 is connected to the other side of the video amplification circuit 24, and a vertical synchronization signal VS is detected from the synchronization signal SY. The horizontal synchronization signal HS and the vertical synchronization signal VS are output to the CPU 34, the horizontal synchronization signal HS is output to the scan electrode drive circuit 43, and the vertical synchronization signal VS is output to the signal electrode drive circuit 44.
[0088]
A scanning electrode driving circuit 43 is connected to the horizontal synchronizing circuit 41 so that the liquid crystal display panel 26 is line-sequentially scanned based on the horizontal synchronizing signal HS. A plasma drive driver IC or the like is used for the scan electrode drive circuit 43. A signal electrode drive circuit 44 is connected to the vertical synchronization circuit 42, a drive voltage is generated based on the vertical synchronization signal VS and the corrected video data DOUT, and this drive voltage is supplied to the liquid crystal display panel 26. . For the signal electrode driving circuit 44, a data driver IC corresponding to plasma driving column inversion is used. A backlight 27 is attached to the back surface of the liquid crystal display panel 26. Of course, the liquid crystal television 300 is provided with a power supply unit 28 to supply power to the backlight 27 and each functional circuit.
[0089]
Subsequently, an example of the contents of the ROM 33 will be described. FIG. 12 is an image diagram showing an example of the contents of the corrected video data DOUT of the luminance gradation level L2i ′ stored in the ROM 33. FIG. 13 shows the correction value Lr of the video data DOUT shown in FIG. It is the image figure displayed by color coding.
The ROM 33 of this example stores the video data DOUT of the brightness gradation level L2i ′ after correction of 0 to 248 gradations with 8 gradations as one unit, and according to the content example, the horizontal axis shown in FIG. Is plotted with video data DIN of i = 0 to 248 gradation as the luminance gradation level L1i of the previous frame, and the vertical axis represents the video of i = 0 to 248 gradation as the luminance gradation level L2i of the current frame. Data DIN is plotted. The video data DOUT of the luminance gradation level L2i ′ of the entire range from 0 gradation to 248 gradation is stored in each lattice portion of the matrix created by the video data DIN of the previous and subsequent frames and the video data DIN of the current frame. To be made.
[0090]
In this example of content, the grid portion on the diagonal line A0 descending from the upper left 0 gradation to the lower right 248 gradation has 0, 8, 16, 24, 32, 40 from 0 gradation to 248 gradation of the current frame. ... 240,248 gradation video data DIN is stored as it is. This is to cope with a case where the difference between the luminance gradation level L1i of the video data DIN of the previous frame and the luminance gradation level L2i of the video data DIN of the current frame is almost zero.
[0091]
In the lattice portion of the upper right area A1 of the video data DIN with reference to the lattice portion of the diagonal line A0, the luminance gradation level L2i ′ of the entire range from 0 gradation to 248 gradation calculated by L2i ′ = L2i−Lr. The video data DINDOUT is stored. This is to cope with the case where the luminance gradation level L2i of the video data DIN of the current frame is lower than the luminance gradation level L1i of the video data DIN of the previous frame. In the upper right area A1, video data DOUT having a lower luminance gradation level L2i ′ than the video data DIN of the current frame is output.
[0092]
Further, in the lattice portion of the lower left region A2 with reference to the lattice portion of the diagonal line A0, the video data DINDOUT of the luminance gradation level L2i ′ of the entire range from 0 gradation to 248 gradation calculated by L2i ′ = L2i + Lr is obtained. It is made to memorize. This is to cope with the case where the luminance gradation level L2i of the video data DIN of the current frame is higher than the luminance gradation level i of the video data DIN of the previous frame. In the lower left area A2, the video data DOUT having a higher luminance gradation level L2i ′ than the video data DIN of the current frame is output.
[0093]
As for the correction value Lr in the above-mentioned upper right area A1 and lower left area A2, 8, 16, 24, 32, 40, 48, 56, and 64 gradations are applied depending on the display characteristics of the liquid crystal display panel 26. . In this example, particularly in the intermediate gradation, the luminance gradation level is lowered from the upper gradation level to the lower gradation level, and a larger correction value is applied as the reduction amount increases.
[0094]
For example, when the luminance gradation level L1 of the video data DIN of the previous frame is i = “72” and the luminance gradation level L2 of the video data DIN of the current frame is i = “88”, the corrected current frame A luminance gradation level L2 ′ of i = “96” is read as the video data DIN. The correction value Lr at this time is +8.
[0095]
Similarly, when L1 = “72” and L2 = “104”, L2 ′ = “128” is read. The correction value Lr at this time is +24. When L1 = “72” and L2 = “120”, L2 ′ = “152” is read. The correction value Lr at this time is +32. When L1 = “72” and L2 = “128”, L2 ′ = “168” is read. The correction value Lr at this time is +40. In any case, this is to improve response time delay when the luminance gradation level is lowered from the upper gradation level to the lower gradation level in the intermediate gradation in the liquid crystal display panel 26.
[0096]
Further, in the case where the luminance gradation level is increased from the lower gradation level to the upper gradation level, a larger correction value is applied as the increase amount increases. For example, when the luminance gradation level L1 of the video data DIN of the previous frame is i = “160” and the luminance gradation level L2 of the video data DIN of the current frame is i = “72”, the corrected current frame A luminance gradation level L2 ′ of i = “8” is read as the video data DIN. The correction value Lr at this time is −64.
[0097]
Similarly, when L1 = “160” and L2 = “80”, L2 ′ = “24” is read. The correction value Lr at this time is −56. When L1 = “160” and L2 = “96”, L2 ′ = “48” is read. The correction value Lr at this time is −48. When L1 = “160” and L2 = “104”, L2 ′ = “64” is read. The correction value Lr at this time is −40.
[0098]
When L1 = “160” and L2 = “120”, L2 ′ = “88” is read. The correction value Lr at this time is −32. When L1 = “160” and L2 = “136”, L2 ′ = “112” is read. The correction value Lr at this time is −24. When L1 = “160” and L2 = “144”, L2 ′ = “128” is read. The correction value Lr at this time is −16.
[0099]
In either case, the response time delay is improved when the luminance gradation level is increased from the lower gradation level to the upper gradation level in the intermediate gradation in the liquid crystal display panel 26.
[0100]
FIG. 14 is an image diagram of a three-dimensional reference table showing an example of the relationship between L1i, L2i, and Lr in the ROM 33. Since the angle at which the three-dimensional reference table is viewed is changed, it does not necessarily match the value of the reference table shown in FIG. In FIG. 14, L1i is the luminance gradation level of 0 to 248 of the video data DIN of the previous frame, L2i is the luminance gradation level of 0 to 248 of the video data DIN of the current frame, and Lr is The correction value is 0 to 64 gradations.
[0101]
That is, the current frame video data DOUT is prepared on the liquid crystal display panel 26 so that the video data DIN of the next frame can be quickly changed to the luminance gradation level L2i with respect to the video data DIN of the previous frame. Alternatively, when there is a luminance gradation level L2i whose response speed is faster near the luminance gradation level L2i to be changed due to the characteristics of the liquid crystal display panel 26, the luminance gradation level L2i is changed. Prepare corrected video data DOUT.
[0102]
Next, an operation example of the liquid crystal television 300 will be described. In this example, it is assumed that in the liquid crystal television 300 shown in FIG. 11, the corrected video data DOUT described in FIG. 12 is stored in the ROM 33, and an NTSC broadcast program is displayed on the liquid crystal display panel 26. . Of course, power is supplied to the backlight 27 on the back surface of the liquid crystal display panel 26, and power is supplied to each functional circuit.
[0103]
Under these operating conditions, when an analog terrestrial broadcast radio wave is received by the antenna 21 shown in FIG. 11, an NTSC broadcast radio wave is output from the antenna 21 to the tuner & IF amplifier 22. The tuner & IF amplifier 22 detects broadcast signals and detects audio signals and R, G, and B video signals. The audio signal is amplified by the audio amplification circuit 23 and output to the speaker 25.
[0104]
The R, G, B video signals (image signal SIN) are amplified by the video amplification circuit 24 and the synchronization signal SY is separated. The horizontal synchronization circuit 41 detects the horizontal synchronization signal HS from the synchronization signal SY, and the vertical synchronization circuit 42 detects the vertical synchronization signal VS from the synchronization signal SY. The horizontal synchronization signal HS and the vertical synchronization signal VS are output to the CPU 34, the horizontal synchronization signal HS is output to the scan electrode drive circuit 43, and the vertical synchronization signal VS is output to the signal electrode drive circuit 44.
[0105]
The image signal SIN is amplified by the video amplifying circuit 24 and then analog / digital converted by the A / D converter 31 to be converted into R, G, B video data DIN. The video data DIN of the frame immediately before the current frame is stored in the frame memory 32. The video data DIN of the current frame and the video data DIN read from the frame memory 32 are input to the correction value lookup table ROM 33 based on the write / read control signal WE.
[0106]
In the ROM 33, the luminance gradation level L1i of the video data DIN of the frame immediately before the current frame stored in the frame memory 32 and the luminance gradation level L2i of the video data DIN of the current frame are used as addresses to correct the frame. The video data DOUT of the later luminance gradation level is read out.
[0107]
The ROM 33 can correct the video data DOUT in accordance with the change in the luminance gradation level of the image signal SIN. The corrected video data DOUT is read out by the CPU 34 and output to the signal electrode drive circuit 44.
[0108]
On the other hand, the scan electrode drive circuit 43 scans the liquid crystal display panel 26 line-sequentially based on the horizontal synchronization signal HS. In the signal electrode drive circuit 44, a drive voltage is generated based on the vertical synchronization signal VS and the corrected video data DOUT, and this drive voltage is supplied to the liquid crystal display panel 26. For example, when changing from a certain luminance gradation level L1i to a lower luminance gradation level L2i, if the response time of the liquid crystal display panel 26 is delayed, the luminance gradation level of the video data DIN is further lowered and the drive voltage is reduced. It is made to increase the change. The liquid crystal display panel 26 displays high-definition NTSC broadcast programs with high movement.
[0109]
Thus, according to the liquid crystal television 300 as an example according to the present invention, the display control device 103 according to the third embodiment described above is applied, so that the previous level is changed when the luminance gradation level changes. It can be replaced with corrected video data DOUT that has been corrected so that the luminance gradation level is optimized on the liquid crystal display panel 26 based on the video data DIN of the frame and the video data DIN of the current frame.
[0110]
Further, the corrected video data DIN can be output by the ROM 33 without imposing a calculation burden on the luminance gradation of the video data DIN on the CPU 34 and the like, so that the liquid crystal display panel 26 sufficiently copes with the fast moving video data DOUT. It becomes possible to do. Therefore, even when the video data DOUT with a sharp luminance change is input to the signal electrode drive circuit 44, the luminance change, that is, the phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the video is blurred can be prevented.
[0111]
In this embodiment, the case where the display control device 103 according to the third embodiment is used with respect to the display control means 10 has been described. However, the present invention is not limited to this, and the display control device according to the first and second embodiments is used. 101 and 102 and the display control apparatus 104 according to the fourth embodiment can also be used.
[0112]
By using the correction value look-up table in these display control devices 101 to 104, the correction value can be read for each change of the video data DIN of various luminance gradation levels L2i, and correction is made so as not to overcorrect. It is also possible to finely adjust the value Lr. The response time can be made constant with high accuracy in all changes in the luminance gradation level L2i. Further, even when the liquid crystal display panel 26 having a different response speed with respect to the drive voltage is used, it can be easily handled by replacing the lookup data.
[0113]
In the embodiment, the case where the display control means 10 is provided with one lookup table ROM 33 has been described. However, the present invention is not limited to this. For example, a plurality of lookup table ROMs corresponding to temperature changes are provided. You may make it provide. This look-up table is a table in which a correction value corresponding to a temperature change is calculated in advance for video data of the luminance gradation level of the frame, and the temperature-dependent correction gradation data after this calculation is made into a reference table.
[0114]
The display control means 10 switches the reading of the temperature dependent gradation data according to the use environment temperature. When the liquid crystal display panel 26 is driven with the temperature-dependent corrected gradation data, it is possible to eliminate the variation in the response time of the liquid crystal due to the operating environment temperature of the backlight 27 and make it constant.
[0115]
In the above-described embodiments, the case of a liquid crystal television (LCDTV) is described with respect to the image display device. However, the display control devices 101 to 104 can be similarly applied to PALC, LCDPJ, etc., and also applied to a plasma display (PDP). can do.
[0116]
【The invention's effect】
As described above, according to the first display control apparatus of the present invention, the display control is performed on the image display unit having a different response time according to the luminance gradation based on the image signal input for each frame. The correction means calculates a difference between the luminance gradation of the image signal of the previous frame and the luminance gradation of the image signal of the current frame, and calculates a correction value corresponding to the difference of the current frame. The luminance gradation of the image signal is calculated and output.
[0117]
With this configuration, when the luminance gradation of the image signal of the current frame is lower than the luminance gradation of the image signal of the previous frame, the correction value is further subtracted from the luminance gradation of the image signal of the frame. When an image signal with a low luminance gradation is output or the luminance gradation of the image signal of the current frame is higher than the luminance gradation of the image signal of the previous frame, the image signal of the frame is Since it is possible to output an image signal with a higher luminance gradation obtained by adding a correction value to the luminance gradation, even when a liquid crystal display panel is used for the image display section, it is possible to sufficiently cope with a fast moving video signal. Become.
[0118]
According to the second display control apparatus of the present invention, when display control is performed on an image display unit having a different response time according to the luminance gradation of the image signal based on the image signal input for each frame, the correction is performed. And storing the luminance gradation of the image signal of the previous frame and the luminance gradation of the image signal of the current frame as an address and correcting the image signal of the luminance gradation after correction of the frame. It is made to output.
[0119]
With this configuration, when the luminance gradation of the image signal of the current frame is lower than the luminance gradation of the image signal of the previous frame, the correction value is further subtracted from the luminance gradation of the image signal of the frame. When an image signal with a low luminance gradation is output or the luminance gradation of the image signal of the current frame is higher than the luminance gradation of the image signal of the previous frame, the image signal of the frame is Since it is possible to output an image signal with a higher luminance gradation that is obtained by adding a correction value to the luminance gradation, even when a liquid crystal display panel is used for the image display section, the movement can be performed without imposing a burden on other control systems. It is possible to sufficiently cope with a fast video signal. In addition, it can be configured at a lower cost than the first display control device.
[0120]
According to the first image display device of the present invention, since the first display control device described above is applied, even when a liquid crystal display panel is used as the image display means, there is no burden on other control systems. Thus, it is possible to sufficiently cope with a fast moving video signal.
Therefore, even when an image having a large luminance change is input, the luminance change, that is, a phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the image is blurred can be prevented.
[0121]
According to the second image display device of the present invention, since the above-described second display control device is applied, even when a liquid crystal display panel is used as the image display means, there is no burden on other control systems. Thus, it is possible to sufficiently cope with a fast moving video signal.
Therefore, even when an image having a large luminance change is input, the luminance change, that is, a phenomenon that the liquid crystal cannot follow the applied voltage and the outline of the image is blurred can be prevented. In addition, it can be configured at a lower cost than the first image display device.
[0122]
The present invention is very suitable when applied to PALC, LCDTV, LCDPJ, etc., which display an image by supplying an image signal for each frame to an image display device having different response times according to luminance gradation.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration example of an image display apparatus 201 to which a display control apparatus 101 according to a first embodiment of the invention is applied.
FIG. 2 is a luminance gradation level diagram showing an example of correction processing in the correction means 3;
FIG. 3 is an image diagram showing an example of contents of a reference table stored in a storage unit (ROM) 2;
4 is a flowchart illustrating an operation example of the image display apparatus 201. FIG.
FIG. 5 is a block diagram illustrating a configuration example of an image display apparatus 202 to which a display control apparatus 102 as a second embodiment according to the present invention is applied.
FIG. 6 is a block diagram illustrating a configuration example of an image display apparatus 203 to which a display control apparatus 103 as a third embodiment according to the present invention is applied.
FIG. 7 is an image diagram showing an example of the content of an image signal SOUT of a luminance gradation level L2i ′ after correction stored in a storage unit 8;
FIG. 8 is an image diagram showing an example of reading out an image signal SOUT of a luminance gradation level L2i ′ after correction in the storage unit 8;
FIG. 9 is a flowchart showing an operation example of the image display apparatus 203;
FIG. 10 is a block diagram showing a configuration example of an image display device 204 to which a display control device 104 as a fourth embodiment according to the present invention is applied.
FIG. 11 is a block diagram showing a configuration example of a liquid crystal television 300 as an embodiment according to the present invention.
12 is an image diagram showing an example of the content of video data DOUT at a corrected luminance gradation level L2i ′ stored in a ROM 33. FIG.
13 is an image diagram in which the correction value Lr of the video data DOUT shown in FIG. 12 is color-coded with equivalent level lines.
14 is a three-dimensional reference table showing an example of the relationship between L1i, L2i, and Lr in the ROM 33. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1,4 ... 1st memory | storage means, 2,5,8 ... 2nd memory | storage means, 3,6 ... Correction means, 7 ... Addition means, 10 ... Display control means, DESCRIPTION OF SYMBOLS 11 ... Display drive means, 12 ... Image display means, 32 ... Frame memory (1st memory means), 33 ... ROM (2nd memory means), 101-104 ... Display Control device (display control means) 201-204 ... image display device, 300 ... liquid crystal television (image display device)

Claims (4)

In an apparatus for controlling display of an image display unit having a different response time according to luminance gradation based on an image signal input for each frame,
First storage means for storing at least an upper 6-bit image signal obtained by discarding the lower 2 bits of an image signal consisting of 8 bits of a frame immediately preceding the current frame;
The difference between the luminance gradation of the image signal of the previous frame stored in the first storage means and the luminance gradation of the image signal of the current frame is calculated, and a correction value corresponding to the difference is calculated for the current frame. Correction means for calculating and outputting the luminance gradation of the image signal,
The correction means has an 8 * N (N is an integer of 0 ≦ N ≦ 31) floor ranging from 0 gradation to 248 gradations of the image signal of the previous frame stored in the first storage means. 8 * N (N is 0) , from the 0 gradation to the 248 gradation of the upper 6-bit image signal obtained by discarding the lower 2 bits of the 8-bit image signal of the current frame. ≦ N ≦ 31 (integer) The difference between the gradation and the luminance gradation level is calculated, and the 8, 16, 24, 32, 40, 48, 56, and 64 gradation correction values corresponding to the difference are calculated for the current frame. A display control apparatus that adds or subtracts to a luminance gradation of an image signal and adds and outputs a lower 2 bits image signal of a current frame before correction calculation to an upper 6 bits image signal of the current frame after correction calculation .   The display control apparatus according to claim 1, further comprising a second storage unit that stores a correction value corresponding to the difference. The correction means includes
When the difference between the luminance gradation of the image signal of the previous frame stored in the first storage means and the luminance gradation of the image signal of the current frame is zero at the luminance gradation level, Output the image signal of the current frame as it is,
Regarding the specific luminance gradation range of the image signal,
When the luminance gradation of the image signal of the current frame is lower than the luminance gradation of the image signal of the previous frame stored in the first storage means, the luminance gradation of the image signal of the current frame is An image signal with a lower luminance gradation obtained by subtracting the correction value is output.
When the luminance gradation of the image signal of the current frame is higher than the luminance gradation of the image signal of the previous frame stored in the first storage means, the luminance gradation of the image signal of the current frame is The display control apparatus according to claim 1, wherein an image signal having a higher luminance gradation to which a correction value is added is output. Image display means for displaying an image based on a driving voltage applied for each frame;
Display driving means for supplying an applied voltage to the image display means;
Display control means for controlling input / output of the display drive means,
The display control means includes
Storage means for storing at least a high-order 6-bit image signal obtained by discarding low-order 2 bits of an 8-bit image signal of a frame immediately preceding the current frame;
The difference between the luminance gradation of the image signal of the previous frame stored in the storage means and the luminance gradation of the image signal of the current frame is calculated, and a correction value corresponding to the difference is calculated for the image signal of the current frame. Correction means for calculating and outputting the luminance gradation,
The correction means has a luminance of 8 * N (N is an integer of 0 ≦ N ≦ 31) gradation ranging from 0 gradation to 248 gradations of the image signal of the previous frame stored in the storage means. 8 * N (N is 0 ≦ N ≦ N) from the gradation level 0 to 248 gradations of the upper 6-bit image signal obtained by discarding the lower 2 bits of the 8-bit image signal of the current frame. 31) The difference between the gradation level and the luminance gradation level is calculated, and the 8, 16, 24, 32, 40, 48, 56, and 64 gradation correction values corresponding to the difference are calculated from the image signal of the current frame. An image display device that adds or subtracts to a luminance gradation and adds and outputs a lower 2 bits image signal of a current frame before correction calculation to an upper 6 bits image signal of a current frame after correction calculation .

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