JP2016012068A - Image display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image display device capable of suppressing the shortening of a service life and suppressing a blur when displaying a moving image.SOLUTION: An image display device 1 includes an image display module 10, an input part (synchronous separation part 21) to which a video signal is inputted, an extraction part 251 which takes out two frames from the video signal inputted by the synchronous separation part 21 and extracts the motion of an object recorded on the frames on the basis of the two taken out frames, a division part 252 which divides the areas of the frames into a moving area where it is determined that there is a motion in the object and a still area where it is determined that there is no motion in the object on the basis of the result of the extraction by the extraction part 251, and a control part (light emission time control pulse generation part 26) which makes the light emission time of the moving area shorter than the light emission time of the still area and gradually shortens the light emission time from the still area to the moving area, to display the frames on the image display module 10.

Description

  The present invention relates to an image display device that displays an image.

  In the hold-type image display device, when an image with a fast moving subject is displayed, an event occurs in which the subject is displayed in a blurred manner. In order to eliminate the motion blur of the subject, there is a type in which the conventional image display device stops the light emission in the middle of one frame and increases the light emission intensity (see Patent Document 1).

JP 2004-144928 A

  In the image display device described in Patent Document 1, when displaying a moving image, control is performed to stop the light emission in the middle of one frame and increase the light emission intensity. When the image display device is an organic EL (Electroluminescence) display device, when the emission intensity is increased, the life characteristics of the organic EL are deteriorated.

  An object of the present invention is to provide an image display apparatus that suppresses blurring when displaying a moving image while suppressing a reduction in lifetime.

  The image display device of the present invention extracts an image display module, an input unit to which a video signal is input, and two frames moving back and forth in time from the video signal input by the input unit. Based on the extraction unit that extracts the movement of the subject recorded in the frame, and based on the extraction result by the extraction unit, the region of the frame is divided into a moving region in which the subject has movement, and the subject has movement. A dividing unit that divides the moving region into a stationary region, and makes the light emission time of the moving region shorter than the light emitting time of the stationary region, and in the region adjacent to the moving region in the stationary region, A control unit that causes the image display module to display a frame so that the light emission time is gradually shortened as it approaches.

  The dividing unit obtains a ratio of the number of pixels in which the subject moves for each horizontal line constituting the frame based on a result of extraction by the extraction unit, and moves the horizontal line exceeding the threshold among the ratios for each horizontal line. It is preferable that a horizontal line that is equal to or smaller than a threshold value in the ratio of each horizontal line is set as the still area.

  The control unit, for the moving region and the region of the stationary region where the light emission time is shortened, causes the light emission luminance to be higher when the light emission time is shorter, and the frame is added to the image display module. It is preferable to display.

The image display module is preferably an active matrix organic EL display module.

  According to the present invention, it is possible to provide an image display device that suppresses the shortening of the lifetime and suppresses blurring when displaying a moving image.

1 is a block diagram for explaining an embodiment of an image forming apparatus. It is a figure for demonstrating the structure of a pixel. It is a figure for demonstrating degradation of an image quality. It is a figure for demonstrating operation | movement of an image display apparatus.

  Hereinafter, an embodiment of the present invention will be described. FIG. 1 is a block diagram for explaining an embodiment of an image forming apparatus. FIG. 2 is a diagram for explaining a configuration of a pixel.

  As shown in FIG. 1, the image display device 1 includes an image display module 10, a synchronization separation unit 21, a data conversion unit 22, a data signal control pulse generation unit 23, and a selection signal control pulse generation unit 24. A motion detector 25, a light emission time control pulse generator 26, and a light emission time control signal line drive circuit 27. The synchronization separation unit 21 corresponds to an embodiment of the “input unit” of the present invention. The selection signal control pulse generator 24 and the light emission time control pulse generator 26 correspond to an embodiment of a “controller” of the present invention.

  The image display module 10 is a hold-type image display module. As a more specific example, the image display module 10 is an active matrix organic EL display module. Hereinafter, an active matrix organic EL display module will be described as an example of the image display module 10.

  The image display module 10 includes a data signal line drive circuit 11, a selection signal line drive circuit 12, and a display panel 13.

  The data signal line drive circuit 11 is connected to a plurality of data signal lines (not shown in FIG. 1; see the reference numeral “DL” in FIG. 2) arranged in the vertical direction. The data signal line driving circuit 11 supplies a data signal to each of the plurality of data signal lines based on the image signal and the pulse signal.

  The selection signal line driving circuit 12 is connected to a plurality of selection signal lines (not shown in FIG. 1; see the reference numeral “SL” in FIG. 2) arranged in the horizontal direction. The selection signal line driving circuit 12 supplies a selection signal to each of the plurality of selection signal lines based on the pulse signal.

  The display panel 13 includes a plurality of pixels. As shown in FIG. 2, one pixel includes a switching transistor Tr1, a drive transistor Tr2, a light emission time control transistor Tr3, a storage capacitor C, and an organic EL element 14.

  The gate electrode G of the switching transistor Tr1 is connected to the selection signal line SL. The drain electrode D of the switching transistor Tr1 is connected to the data signal line DL. The source electrode S of the switching transistor Tr1 is connected to the gate electrode G of the drive transistor Tr2 and the storage capacitor C.

  The drain electrode D of the drive transistor Tr2 is connected to the power supply Vdd and the storage capacitor C. The source electrode S of the drive transistor Tr2 is connected to the drain electrode D of the light emission time control transistor Tr3. The source electrode S of the light emission time control transistor Tr3 is connected to the organic EL element. The gate electrode G of the light emission time control transistor Tr 3 is connected to the light emission time control signal line 15.

The synchronization separation unit 21 shown in FIG. 1 separates the input video signal into an image signal and a synchronization signal.
When the input image signal is an analog signal, the data converter 22 converts the input image signal into a digital signal that can display an image on the display panel 13. Alternatively, when the input image signal is a digital signal, the data conversion unit 22 converts the input image signal into a digital signal that can display an image on the display panel 13.

The data signal control pulse generator 23 generates a pulse signal (data signal control pulse) for displaying an image on the display panel 13 based on the synchronization signal, and supplies the pulse signal to the data signal line drive circuit 11.
The selection signal control pulse generator 24 generates a pulse signal (selection signal control pulse) for displaying an image on the display panel 13 based on the synchronization signal, and supplies the pulse signal to the selection signal line drive circuit 12.

  The motion detection unit 25 detects the motion of the subject from a plurality of frames based on the video signal. That is, the extraction unit 251 constituting the motion detection unit 25 takes out two frames that are temporally forward and backward from the video signal (the image signal separated by the synchronization separation unit) input to the synchronization separation unit 21 and extracts the two frames. Based on one frame, the movement of the subject recorded in the frame is extracted. Here, the extraction unit 251 preferably includes a buffer memory (not shown) for storing frames. In addition, when extracting the two frames, the extraction unit may extract two temporally continuous frames, and among the three temporally continuous frames, the front end and the rear end are separated by one frame. And two frames may be taken out.

  For example, the extraction unit 251 acquires the amount of motion of the subject of each pixel between frames from two frames that constitute the image signal that are temporally mixed. As a specific example, the extraction unit 251 extracts a block of 16 pixels × 16 pixels from a frame and performs block matching between frames to acquire the amount of motion of the subject. For example, the extraction unit 251 represents the magnitude of the movement of the subject by Vn (x, y). Here, x satisfies the relationship of 0 <x ≦ Nx (Nx: the number of pixels in the horizontal direction). Moreover, y satisfies the relationship of 0 <y ≦ Ny (Ny: number of pixels in the vertical direction).

  In addition, the motion detection unit 25 divides the frame into a moving region where the subject is moving and a still region where the subject is not moving based on the extraction result of the amount of movement of the subject. That is, the dividing unit 252 constituting the motion detecting unit 25 obtains the ratio of the number of pixels that the subject moves for each horizontal line (selection signal line SL) constituting the frame based on the extraction result by the extracting unit 251. Then, the dividing unit 252 sets a horizontal line that exceeds the threshold among the ratio of each horizontal line (selection signal line SL) as a moving area. In addition, the dividing unit 252 sets a horizontal line that is equal to or less than the threshold among the ratios for each horizontal line (selection signal line SL) as a still region.

  More specifically, the dividing unit 252 generates a histogram Hn (l) of the subject motion amount for each horizontal line (selection signal line SL) based on the subject motion magnitude Vn extracted by the extraction unit 251. create. Here, l represents the number (line number) of the horizontal line (selection signal line SL).

  More specifically, the dividing unit 252 first obtains the number of pixels in which the subject motion magnitude Vn exceeds the first threshold value Vth1 with respect to the subject motion magnitude Vn when the line number is y = 1. Here, as an example, the first threshold value Vth is 4 pixels / frame. Therefore, the dividing unit 252 obtains the number of pixels having a subject motion exceeding 4 pixels per frame for each horizontal line. Next, the dividing unit 252 obtains a value W obtained by dividing the obtained number of pixels by the number of pixels Nx (the number of pixels in the horizontal direction) constituting one horizontal line. Based on finding the value W for each horizontal line, a histogram Hn (l) is created. Next, the dividing unit 252 sets, for the histogram Hn (l), a horizontal line that exceeds the second threshold value Hth as a moving region. That is, the dividing unit 252 sets a horizontal line having a value W exceeding the second threshold value Hth as a moving area. On the other hand, the dividing unit 252 sets, for the histogram Hn (l), a horizontal line that is equal to or less than the second threshold value Hth as a still region. The dividing unit 252 sets a horizontal line having a value W equal to or smaller than the second threshold value Hth as a still region.

  The light emission time control pulse generation unit 26, when displaying a video image signal on the image display module 10 based on the synchronization signal, is a horizontal line that is set as a static region for a horizontal line that is set as a moving region by the motion detection unit 25. Rather, the light emission time of one frame is shortened. As an example, if the light emission time of one frame in the still region is 100%, the light emission time control pulse generator 26 sets the light emission time of one frame in the moving region to 25%.

Here, the deterioration of the image quality will be described. FIG. 3 is a diagram for explaining deterioration of image quality. FIG. 3A shows a case where the line of sight is not moved. FIG. 3B shows a case where the line of sight is moved.
It is assumed that display is performed by controlling only the light emission time of the stationary region to 100% (light emission intensity is set to 100%) and the light emission time of the moving region to 25% (light emission intensity is set to 400%). To do.
As shown in FIG. 3A, in the above assumption, when the line of sight is not moved, both the stationary region and the moving region appear to have the same brightness.
However, as shown in FIG. 3B, in the above assumption, when the line of sight is moved so as to move to a different area, the boundary between the stationary area and the moving area may appear black. That is, the human eye sees an integrated light of a predetermined time. For this reason, if the line of sight is moved in a region where the light emission time is different, the human eye tries to integrate light for one frame, so that the display is the same as when the light emission time is shortened for the static region. The boundary with the moving area looks black, and the image quality deteriorates.

  In order to prevent the space between the stationary region and the moving region from appearing black in this way, the light emission time control pulse generator 26 sets the light emitting time from the stationary region to the moving region for the stationary region adjacent to the moving region. Try to shorten it gradually. That is, the light emission time control pulse generator 26 gradually shortens the light emission time in the region adjacent to the moving region in the stationary region as it approaches the moving region.

  As a specific example, when there are 1080 horizontal lines, line numbers 500 to 700 are moving areas, and line numbers other than 500 to 700 are stationary areas, 430 to 499 and 770 From 701 to 701, the light emission time is shortened by 2% step by step so that the light emission time approaches 25% as the moving region is approached. That is, the light emission time control pulse generator 26 controls the region adjacent to the moving region in the stationary region so that the light emitting time is shortened by 2% for each line as the moving region is approached. In such an example, the light emission time of the 499th horizontal line is 25.5%, the light emission time of the 498th horizontal line is 26.01%, and the light emission time of the 497th horizontal line is 26.53%. Thus, the emission time of the 431st horizontal line is 98.02%, and the emission time of the 430th horizontal line is 99.98%. The light emission time of the 701 horizontal line is 25.5%, the light emission time of the 702 horizontal line is 26.01%, the light emission time of the 703 horizontal line is 26.53%, The light emission time of the horizontal line is 98.02%, and the light emission time of the 770th horizontal line is 99.98%.

  Note that even if the light emission time for each line is shortened by an arbitrary value of less than 2%, the deterioration of the image quality can be improved. However, if it is set to 2%, the processing load of the light emission time control pulse generator 26 is reduced, and further the deterioration of the image quality can be improved. Further, even when the light emission time is shortened to an arbitrary value of 2% or more for each line, it is possible to improve image quality degradation.

  When the light emission time control pulse generation unit 26 displays an image on the display panel 13, an organic EL element per frame is compared with a motion region in which motion is detected by the motion detection unit 25 compared to a still region in which motion is not detected. In order to shorten the light emission time 14, a pulse signal (light emission time control pulse) for controlling the light emission time of the organic EL element 14 is generated based on the synchronization signal, and is sent to the light emission time control signal line drive circuit 27. Supply.

  As an example, the light emission time control signal line drive circuit 27 is connected to a plurality of light emission time control signal lines 15 along the horizontal direction. Each light emission time control signal line 15 is connected to a plurality of light emission time control transistors Tr3 existing in a region along the horizontal direction where the light emission time control signal line 15 is arranged.

  When the light emission time control signal line drive circuit 27 receives the light emission time control pulse, the light emission time control signal line drive circuit 27 outputs a light emission time control signal to the pixel that displays the moving region in which the motion is detected by the motion detector 25. As described above, the light emission time control signal line 15 is connected to the plurality of light emission time control transistors Tr3 along the horizontal direction. For this reason, when a light emission time control signal is supplied to the light emission time control signal line 15, all the light emission time control transistors Tr3 connected to the light emission time control signal line 15 (light emission time control transistors Tr3 along the horizontal direction). ) Is supplied with a light emission time control signal. Upon receiving the light emission time control signal, the light emission time control transistor Tr3 controls the power on / off based on the light emission time control signal. That is, the light emission time control transistor Tr3 shortens the light emission time of the organic EL element 14 per frame for the frame in which the motion is detected based on the light emission time control signal.

  In addition, the selection signal control pulse generation unit 24 increases the light emission luminance of the moving region in which the motion is detected by the motion detecting unit 25 as compared to the still region in which no motion is detected. That is, only when the light emission time is shortened as described above, the user perceives the video corresponding to the moving area darker than the video corresponding to the still area. For this reason, the selection signal control pulse generator 24 makes the emission luminance of the moving region higher than that of the stationary region in order to prevent the user from feeling dark. Here, the selection signal control pulse generator 24 causes the light emission luminance to be higher in the region where the light emission time is shortened when the light emission time is shorter. Therefore, the light emission brightness is set higher in the still region where the light emission time is shortened than in the still region where the light emission time is not changed.

  As an example, when there are 1080 horizontal lines, line numbers 500 to 700 are moving areas, and line numbers other than 500 to 700 are stationary areas, these correspond to horizontal lines 500 to 700. Increase the luminance of the moving area. Furthermore, when the light emission time for each line is shortened by 2% as the moving region is approached, the stationary region from 430 to 499 and from 770 to 701 in the region adjacent to the moving region in the stationary region. As the region approaches the moving region, the light emission luminance is gradually increased.

The selection signal control pulse generator 24 obtains a coefficient (data magnification) according to the light emission time, and controls the light emission luminance according to the data magnification. Here, the data magnification is obtained from the following equation (1).
Data magnification = 100 / (light emission time [%]) (1)

  As an example, if the light emission time of the moving region is 25%, the data magnification is 4. Therefore, the selection signal control pulse generator 24 causes the organic EL element 14 to emit light by increasing the light emission luminance of the moving region by four times as compared with the case where the light emission luminance is not changed.

  As an example, there are 1080 horizontal lines, line numbers 500 to 700 are moving areas, line numbers other than 500 to 700 are stationary areas, and the light emission time of the 499th horizontal line is 25.5. When the light emission time of the 432rd horizontal line is 96.1%, the data magnification of the 499th horizontal line is 3.9215, and the data magnification of the 432th horizontal line is 1.0405. . When the light emission time of the 701 horizontal line is 25.5%, the data magnification of the 701 horizontal line is 3.9215. When the light emission time of the 768th horizontal line is 96.01%, the data magnification of the 768th horizontal line is 1.0405. Therefore, the selection signal control pulse generator 24 causes the organic EL element 14 to emit light by increasing the light emission luminance of the 499th and 701th horizontal lines by 3.9215 times compared to the case where the light emission luminance is not changed. In addition, the selection signal control pulse generator 24 causes the organic EL element 14 to emit light by increasing the light emission luminance of the 432rd and 768th horizontal lines by 1.0405 times compared to the case where the light emission luminance is not changed.

  The selection signal control pulse generator 24 outputs a selection signal pulse in order to adjust the amount of charge to the storage capacitor C in accordance with the data magnification. Thereby, since the amount of charge to the storage capacitor C increases, the light emission luminance of the organic EL element 14 increases.

Next, the operation of the image display device 1 will be described. FIG. 4 is a diagram for explaining the operation of the image display apparatus 1.
First, as shown in (1) of FIG. 4, it is assumed that an image in which a person is kicking a soccer ball is input to the image display device 1. In this case, the motion detection unit 25 detects motion in a region corresponding to the soccer ball and a region corresponding to the shadow of the soccer ball (see (2) in FIG. 4).

  When the light emission time control pulse generator 26 displays an image on the display panel 13, the motion is detected for the horizontal line corresponding to the motion region where the motion is detected by the motion detector 25, that is, the soccer ball and the shadow region. The light emission time per frame is made shorter than the horizontal line corresponding to the still area that is not. The light emission time control pulse generator 26 also gradually shortens the light emission time so that the region R adjacent to the moving region in the stationary region approaches the light emitting time of the moving region as it approaches the moving region (see FIG. 4 (3)). In this case, the selection signal control pulse generator 24 causes the organic EL element 14 to emit light at a normal light emission luminance in a region where the light emission time does not change. In addition, the selection signal control pulse generation unit 24 causes the organic EL element 14 to emit light so that the light emission luminance becomes higher than usual in the region where the light emission time is shortened as the light emission time is shortened.

  As described above, the image display apparatus 1 extracts two consecutive frames from the video signal input by the synchronization separation unit 21, and extracts the motion of the subject recorded in the frames based on the two extracted frames. And a division that divides the entire area of the frame into a moving area where the subject is moving and a still area where the subject is not moving based on the extraction result by the extracting unit 251 252 and a light emission time control for causing the image display module 10 to display a frame by making the light emission time of the moving region shorter than the light emission time of the stationary region and gradually reducing the light emission time from the stationary region to the moving region. And a pulse generation unit 26.

  Thereby, since the image display apparatus 1 shortens the light emission time for the moving area, it is possible to suppress the occurrence of blurring when displaying a moving image. Also, the image display device 1 gradually shortens the light emission time for the region adjacent to the moving region in the stationary region, so that the area between the stationary region and the moving region is displayed in black. Can be suppressed.

  Further, the dividing unit 252 obtains the ratio of the number of pixels that the subject moves for each horizontal line constituting the frame based on the extraction result by the extracting unit 251, and moves the horizontal line that exceeds the threshold among the ratios for each horizontal line. A horizontal line that is equal to or less than a threshold value in the ratio of each horizontal line is defined as a still area. Thereby, the image display apparatus 1 can obtain a moving area and a stationary area from the input video signal (the image signal separated by the synchronization separation unit 21).

  The selection signal control pulse generator 24 causes the image display module 10 to display the frame so that the emission luminance is higher when the emission time is shorter in the region where the emission time is shorter. Thereby, since the image display apparatus 1 increases the light emission luminance for only a part of one frame, it is possible to suppress the life of the display panel 13 from being shortened.

The present embodiment can be modified as follows.
When there are a plurality of groups of moving areas composed of moving areas with continuous line numbers in one frame, for example, as shown in FIG. When there is a corresponding moving region group and a moving region group corresponding to a shadow, compared to the case where there is one moving region group per frame, the region adjacent to the moving region in the stationary region You may lengthen the light emission time changed for every line.
For example, when there is one moving region group in one frame, the light emission time control pulse generation unit 26 changes the light emission time by 2% for each line in a region adjacent to the moving region in the stationary region. . On the other hand, when there are a plurality of moving region groups in one frame, the light emission time control pulse generator 26 changes the light emission time by 5% for each line in the region adjacent to the moving region in the stationary region.
As a result, the image display device 1 can prevent substantially the entire region of the frame from being controlled to change the light emission time.

In addition, when a moving region exists near the center of one frame, the light emission time control pulse generator 26 finely changes the light emission time for each line in a region adjacent to the moving region in the stationary region ( As an example, 2%) can be set. On the other hand, when there is a moving region near the upper end or near the lower end of one frame, the light emission time control pulse generator 26 changes the light emission time for each line for the region adjacent to the moving region in the stationary region. It can be set large (for example, 5%). It is considered that the user can easily recognize an image near the center of the frame as compared with an image near the upper end or near the lower end.
For this reason, the image display apparatus 1 can reduce the processing load of the light emission time control pulse generation unit 26 and the selection signal control pulse generation unit 24 by further improving the image quality in the vicinity of the central portion that is easily recognized.

In addition, the light emission time control pulse generation unit 26 can change the change in the light emission time for each line in the region adjacent to the moving region in the stationary region according to the input content. For example, in content that is considered to have a small moving area in the entire video, the light emission time is changed by a large value (for example, 5%) for each line in an area adjacent to the moving area in the still area. On the other hand, for content that is considered to have many moving areas in the entire video, the light emission time is changed by a small value (for example, 2%) for each line in an area adjacent to the moving area in the still area.
It can be considered that there is little need to improve image quality for content that is considered to have a small moving area. Thereby, the image display apparatus 1 can perform control suitable for the content.

  Further, the light emission time control pulse generator 26 does not have to perform control to shorten the light emission time when the number of horizontal lines serving as a moving region is less than a predetermined number. When the number of horizontal lines serving as the moving area is small, the user may not be able to recognize the movement of the subject because the subject corresponding to the moving area is small. Thereby, the image display apparatus 1 can reduce the processing burden of the light emission time control pulse generator 26 and the selection signal control pulse generator 24.

DESCRIPTION OF SYMBOLS 1 Image display apparatus 10 Image display module 21 Synchronization separation part (input part)
251 Extraction unit 252 Division unit 24 Selection signal control pulse generation unit (control unit)
26 Light emission time control pulse generator (control unit)

Claims (4)

An image display module;
An input unit for inputting a video signal;
An extraction unit that extracts two frames that are temporally moved forward and backward from the video signal input by the input unit, and extracts a movement of a subject recorded in the frame based on the two extracted frames;
A dividing unit that divides a region of the frame into a moving region in which the subject is moving and a stationary region in which the subject is not moving based on a result of extraction by the extracting unit;
The light emission time of the moving area is made shorter than the light emission time of the stationary area, and the light emitting time is gradually shortened as the moving area is approached in the area adjacent to the moving area of the stationary area. A control unit for displaying the image on the image display module;
An image display device comprising: The dividing unit is
Based on the result of extraction by the extraction unit, obtain the ratio of the number of pixels that the subject moves for each horizontal line constituting the frame,
A horizontal line that exceeds a threshold value in the ratio for each horizontal line is defined as the moving area,
The image display apparatus according to claim 1, wherein a horizontal line that is equal to or less than a threshold value among the ratio of each horizontal line is set as the still area. The control unit, for the moving region and the region of the stationary region where the light emission time is shortened, causes the light emission luminance to be higher when the light emission time is shorter, and the frame is added to the image display module. The image display device according to claim 1, wherein the image display device is displayed. The image display device according to claim 1, wherein the image display module is an active matrix organic EL display module.

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