1. Field of the Invention
The present invention relates to an image display apparatus, and a method for controlling the same.
2. Description of the Related Art
As an image display apparatus, an impulse type or a hold type image display apparatus has been used. A characteristic of the impulse type image display apparatus is that the lighting time of display devices is short, and the ON/OFF of the display devices is recognized as flickering. This flickering can be controlled by increasing the frame frequency (increasing a number of images displayed per unit time), for example. But if the same frame is continuously output twice (double writing) in a moving image, the motion is viewed as double, which is recognized as interference.
For the hold type image display apparatus, on the other hand, a method for controlling motion blur is disclosed in Japanese Patent Application Laid-Open Nos. 2004-240317 and 2002-351382.
In concrete terms, Japanese Patent Application Laid-Open No. 2004-240317 discloses that a frame period (a period for displaying one frame) is divided into two periods (first period and second period), and pixel data is intensively written in the first period (the former period in time series). It is also disclosed that the portion exceeding the displayable dynamic range, out of the pixel data to be written in the first period, is written in the second period (the latter period in time series).
Japanese Patent Application Laid-Open No. 2002-351382 discloses that one frame is divided into a frame of a main image that contains unchanged high frequency components and a frame of a sub-image in which high frequency components are changed, so as to increase the frame frequency.
If a conventional technology of the hold type image display apparatus is applied to the impulse type image display apparatus, the length of the frame period after division is limited, and therefore the brightness of the display image may drop. In concrete terms, if two frames are generated out of one frame, the frame period becomes half of the original frame period. And if the brightness is changed between the main image and the sub-image, in some cases the brightness may become lower than the original image. In the method disclosed in Japanese patent Application Laid-Open No. 2004-240317, the portion exceeding the displayable dynamic range, out of the pixel data to be written in the first period, is written in the second period, so the pixel data having high brightness value is written twice, which may cause interference in the moving image.
The present invention provides a technology that can control the generation of interference in the moving image and drop in brightness of the image.
An image display apparatus according to the present invention, comprises:
a display panel driven by multiplex scanning; and
an image processing unit which divides one frame having a predetermined period into a frame of a main image and N (N is a positive integer) frame(s) of sub-image(s), and outputs a video signal that includes the frame of the main image and the frame(s) of the sub-image(s) to the display panel based on input image data, wherein
the image processing unit comprises:
a brightness control unit which generates frames corresponding to the main image and the sub-image based on the same input image data, and relatively reduces the brightness of the frame corresponding to the sub-image with respect to the brightness of the frame corresponding to the main image; and
a period setting unit which sets a length of respective horizontal scan periods so that the horizontal scan period in the frame of the main image is longer than the horizontal scan period in the frame of the sub-image.
A method for controlling an image display apparatus having a display panel driven by multiplex scanning, according to the present invention, comprises the steps of:
dividing one frame having a predetermined period into a frame of a main image and N (N is a positive integer) frame(s) of sub-image(s), and outputting a video signal that includes the frame of the main image and the frame(s) of the sub-image(s) to the display panel based on input image data; and
setting a length of respective horizontal scan periods so that the horizontal scan period in the frame of the main image is longer than the horizontal scan period in the frame of the sub-image, wherein
the main image and the sub-image are images generated from the same input image data, and the sub-image is an image of which brightness is relatively reduced with respect to the brightness of the main image.
According to the present invention, a technology that can control the generation of interference in the moving image and drop in brightness of the image can be provided.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
An image display apparatus and a method for controlling the image display apparatus according to an embodiment of the present invention will now be described. The image display apparatus according to this embodiment has a display panel driven by multiplex scanning and an image processing circuit (image processing unit). The image processing circuit divides one frame having a predetermined period into a frame of a main image and N (N is a positive integer) frame(s) of sub-image(s), and outputs a video signal that includes the frame of the main image and the frame(s) of the sub-image(s) to the display panel. The main image and the sub-image are images that have a same content and different brightness. Here “the main image and the sub-image have a same content” means there is no movement or no substantial movement between the main image and the sub-image. In concrete terms, the main image and the sub-image are images generated from a same image, and the only differences are the brightness and frequency component.
The present invention can be applied to the impulse type image display apparatus and the hold type image display apparatus, but can preferably be applied to the impulse type image display apparatus since a drop in brightness can be controlled.
In this example, it is assumed that the video signal that is input is not a video signal including a frame of a main image and N frame(s) of sub-image(s). And it is assumed that the image processing circuit has a function to generate frames corresponding to the main image and the sub-image respectively based on the same input image data, and to reduce the brightness of the frame corresponding to the sub-image to be relatively lower than the brightness of the frame corresponding to the main image. The main image and the sub-image to be generated are images obtained by reducing the brightness of the frame corresponding to each image at a mutually different reduction rate based on the input image data. A drive method for dividing (distributing) an image of one frame into a plurality of images having different brightness is called “brightness sharing”.
Now an image display device which drives at double speed (in the case of N=1) will be described as Example 1 of the present invention.
Now a method for controlling gradation in the impulse type image display apparatus will be described. In the impulse type image display apparatus, the gradation can be controlled by changing the pulse amplitude and/or the pulse width of the modulation signal.
In the pulse width modulation method, brightness can be increased by increasing the pulse width as the gradation value becomes higher. In this case, if the frame frequency is increased by brightness sharing, the horizontal scan period (maximum pulse with) per frame decreases, and therefore in some cases the pulse width corresponding to the gradation value of the image generated based on the brightness sharing (distributed image (main image, sub-image)) may exceed the maximum pulse width. A possible method for solving this problem is a method for limiting the pulse width so as to not exceed the maximum pulse width. This will be described in detail.
If the ratio of the brightness sharing (ratio of the brightness of the main image with respect to the brightness of the sub-image) is set high, the pulse width of the drive waveform 1001, for displaying the main image, exceeds the horizontal scan period, as shown by the reference numeral 1002 in
The frame data S210 of the distributed image (main image, sub-image) generated in the brightness sharing block in
In order to perform brightness sharing in the impulse type image display apparatus, which modulates the pulse width, with controlling interference and drop in brightness in the moving image, the main image must be displayed brighter than the prescribed value. The absolute rating of a modulation signal is determined by characteristics unique to the display, so the only way to implement high brightness is to increase the pulse width. Therefore in this example, the length of the respective horizontal scan periods is set by the time sharing block shown in
Thereby the pulse width of the drive waveform can be increased as shown in the drive waveform 103 in
In this example, a frame of one main image and a frame of one sub-image are generated from one frame of a video signal, which was input, by the brightness sharing block in
First the input image data S202 and a synchronization signal S201 thereof are input to the frequency conversion circuit 204. The dividing number S203 is input to a frequency conversion circuit 204 and the reduction rate table 205 (the dividing number S203 may be set by the user or may be predetermined). Then the frequency conversion circuit 204 converts the frame frequency according to the dividing number S203. In this example, the frame frequency is converted into double that which was input (multiplied by the dividing number). The reduction rate table 205 is a table in which a total number of frames in a frame group constituted by a frame of a main image and N frame(s) of sub-image(s) (that is a dividing number) is related with the ratio of the brightness between the main image and the sub-image(s). In concrete terms, the reduction rate table 205 is a table in which the dividing number is related with the reduction rate of the sub-image (as a result, the dividing number is related with the ratio of the brightness between the main image and the sub-image).
Then the frequency conversion circuit 204 outputs the synchronization signal S209 after the frequency conversion processing is performed (signal of which frame period and horizontal scan period are half of those which were input) to a switch circuit 208, and outputs the input image data S202 to a difference detection circuit 207 and a multiplication circuit 206. The reduction rate table 205 outputs the reduction rate related to the dividing number S203 (=2) to the multiplication circuit 206.
The multiplication circuit 206 generates frame data of the sub-image by reducing the brightness of the input image data S202 at the reduction rate which was input (multiplying each pixel value of the input image data S202 by the reduction rate which was input). The frame data of the sub-image is output to the difference detection circuit 207 and the switch circuit 208.
The difference detection circuit 207 generates the frame data of the main image by subtracting the frame data of the sub-image from the input image data S202. The frame data of the main image is output to the switch circuit 208.
The switch circuit 208 switches the frame data and outputs it according to the synchronization signal S209. The switch circuit 208 outputs the synchronization signal S209. The switch circuit 208 also outputs the main/sub-identification signal S211 for easily determining whether the frame data, which was output, is the frame data of the main image frame data or the frame data of the sub-image frame data. A main/sub-identification signal S211 is a signal which becomes H at the same time with the rise of Vsync to indicate the start of the main image, and becomes L at the same time with the rise of Vsync to indicate the start of the sub-image.
In the present example, it is assumed that the reduction rate is stored in the reduction rate table 205 in advance, but the reduction rate and the ratio of brightness between the main image and sub-image may be input from the outside (may be set by the user). These values may also be calculated based on the characteristics of the input image data S202.
In this example, the frame data of the main image frame data is calculated (generated) by subtracting the frame data of the sub-image from the input image data S202, but the method for generating the main image frame data is not limited to this. Only if the reduction rate of the main image can be set (obtained), then the frame data of the main image can be generated by multiplying the input image data S202 by this reduction rate. In this case however, the respective reduction rate must be set so that the total of the horizontal scan period in each distributed image frame does not exceed the horizontal scan period in the frame of the input image data S202.
In this example, the table in which the dividing number is related with the reduction rate of the sub-image is the reduction rate table 205, but the reduction rate table 205 may be a table in which the dividing number is related with the reduction rate of the main image. The reduction rate table 205 may also be a table in which the dividing number is related with the reduction rates of the main image and sub-image, or a table in which the dividing number is related with the ratio of brightness between the main image and sub-image.
A method for appropriately setting the horizontal scan period of the brightness-distributed frame data will now be described.
Frame data S210 of the distributed image generated in the brightness sharing block is input to a frame cycle conversion circuit 402.
The synchronization signal S209 and main/sub-identification signal S211, which were generated in the brightness sharing block, and the dividing number S203, which was input in the brightness sharing block in
The frame length setting circuit 401 sets the length of the respective horizontal scan periods so as to correspond to the ratio of brightness between the main image and sub-image (changes the space of synchronization signals). In concrete terms, the maximum pulse width and horizontal scan period, required for displaying the main image and sub-image, are determined depending on the brightness of the main image and sub-image respectively. In this example, the frame length setting circuit 401 sets the length of the horizontal scan period for the frame of the main image and frame of the sub-image respectively, by referring to the reduction rate table 205. Since the dividing number is related with the ratio of the brightness between the main image and sub-image in advance, the frame length setting circuit 401 sets the respective length of the horizontal scan period so as to correspond to the ratio of brightness related with the dividing number S203. The frame length setting circuit 401 determines whether the frame data which was input is the main image frame data or the sub-image frame data, by the main/sub-identification signal S211. The changed synchronization signal is output to the frame cycle conversion circuit 402.
The frame cycle conversion circuit 402 outputs the frame data of the distributed image, generated in the brightness sharing block, synchronizing with the synchronization signals changed by the frame length setting circuit 401. The frame cycle conversion circuit 402 also outputs the synchronization signal changed by the frame length setting circuit 401. In the brightness sharing block, the frame period is divided into two, and output, so data contention may be generated in the blanking period between frames or during the main image frame period, depending on the horizontal scan period that is set by the frame length setting circuit 401. To prevent this, all of the frame data of the distributed images, generated based on one frame of the video signal which was input, is stored once in the frame memory 403. Then the frame cycle conversion circuit 402 reads the frame data of the distributed image from the frame memory 403, and outputs it.
The present inventors confirmed by experiments that interference of the moving image can be decreased if the ratio of the brightness of the main image, with respect to the brightness of the sub-image, is 1.2 or more. Hence it is preferable that the length of the horizontal scan period in the frame of the main image is 1.2 times or more than the length of the horizontal scan period in the frame of the sub-image. Then the interference of the moving image can be further decreased by the brightness sharing. In theory, it is sufficient if the length of the horizontal scan period in the frame of the main image is 1.2 times or more than the length of the horizontal scan period in the frame of the sub-image, and no special upper limit is required. However in practical terms, the horizontal scan period in the frame of the main image is set to be shorter than five times the horizontal scan period in the frame of the sub-image.
In this example, the length of the respective horizontal scan periods is set so as to correspond to the ratio of brightness between the main image and sub-image, but the method for setting the horizontal scan period is not limited to this. Any setting method can be used only if the horizontal scan period in the frame of the main image is set to be longer than the horizontal scan period in the frame of the sub-image. If the horizontal scan period in the frame of the main image is longer than the horizontal scan period in the frame of the sub-image, the main image can be brighter compared with the case of the horizontal scan period in the frame of the main image and the horizontal scan period in the frame of the sub-image that have the same length.
In this example, the frame data is output according to the Vsync and Hsync, but the output of the frame data may be controlled by DE (Display Enable).
This example describes the case when the modulation method is the pulse width modulation method, but the modulation method may also be the pulse amplitude modulation method or may be a method for modulating both the pulse width and the pulse amplitude. In concrete terms, in the case of the pulse amplitude modulation method, the gradation value can be increased by increasing the pulse amplitude, but the maximum value of the pulse amplitude is limited by the absolute rating. According to the configuration of this example, even if the pulse amplitude modulation method or a method for modulating both the pulse width and pulse amplitude, is used, the brightness to be obtained can be increased by increasing the pulse width using the time sharing, hence the above mentioned effect can be implemented.
In this example, a case when only brightness is different, between the main image and sub-image, was described, but the frequency component may be changed between the main image and sub-image, using a low pass filter (LPF) or a high pass filter (HPF). For example, interference of a double image can be further decreased by decreasing the high frequency component of the sub-image.
In Example 1, an image display apparatus, which drives at double speed (in the case of N=1), was described. In this example, a case of generating the frame data of a plurality of sub-images is described. In concrete terms, a case of N=3 is described as an example. Description of functions and a configuration the same as Example 1 are omitted.
First in the brightness sharing block in
The switch circuit 208 selects to output the frame data of the main image first, then selects to output the frame data of the sub-image continuously for three times (the sequence is not limited to this, only if the frame data of all the distributed images generated based on the input image data S202 are output).
The main/sub-identification signal S211 becomes H at the same time with the rise of the Vsync to indicate the start of the main image, and becomes L at the same time with the rise thereof to indicate the start of the sub-image. In other words, the main/sub-identification signal S211 becomes L in the frame period of the three sub-images.
The reduction rate of the main image may be set (obtained) so that the frame data of the main image is directly generated based on the input image data S202 using this reduction rate. The reduction rates of the three sub-images may be different from one another.
The configuration of the time sharing block is the same as Example 1. Each signal generated in the brightness sharing block and dividing number S203 are input into the time sharing block, and the horizontal scan period in the frame of each distributed image is set (synchronization signal is changed), just like Example 1, and the frame data of each distributed image and changed synchronization signals are output.
According to the configuration of this example, the generation of interference of the moving image and drop in brightness of the image can be controlled, regardless the dividing number.
According to the image display apparatus and the method for controlling the image display apparatus of the present embodiment, the respective horizontal scan periods are set so that the horizontal scan period in the frame of the main image is longer than the horizontal scan period in the frame of the sub-image. Since this allows displaying a bright image as the main image, the generation of interference in the moving image and drop in brightness of the image can be controlled.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2009-208013, filed on Sep. 9, 2009, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
---|---|---|---|
2009-208013 | Sep 2009 | JP | national |