JP2017037124A - Image display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image display device which has suppressed occurrence of flicker-like variation.SOLUTION: An image display device 1 includes: an extraction part 251 for taking out a plurality of temporally adjacent frames from a video signal inputted in an input part (corresponding to "synchronization separation part 21" of the embodiment), and for extracting the movement of a subject which is recorded in the frame, based on the plurality of taken out frames; a division part 252 for dividing the region of the frames into a dynamic region in which the subject moves and a still region in which the subject does not move, based on the result of the extraction by the extraction part 251; and an image display control part 30 for, in the case where an image based on the video signal is displayed on an image display module 10, making the light emission time in the dynamic region shorter than the light emission time in the still region and for making the light emission luminance in the dynamic region higher than the light emission luminance in the still region. The image display control part 30 makes the light emission time centers in the frame in the dynamic region and the still region coincide with each other.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an image display device that displays a video based on a video signal.

  A liquid crystal display or an organic EL (Electroluminescence) display displays the same image for one frame period, and is a hold-type display for an impulse-type display device such as a cathode ray tube display. In the hold-type display device, it is known that when an object displayed on the display moves on the screen, a person looks at the object following, so that the image looks blurred due to the integration effect of the eyes.

  In order to prevent such blurring of images, a method for increasing the display frame rate and a method for shortening the light emission time aperture have been proposed. In a normal hold-type display, light emission is sustained over the entire frame period. On the other hand, in the method of shortening the light emission time aperture, as shown in FIG. 9, a non-light emission period is inserted by emitting light only during a part of one frame period. As a result, the technique of shortening the light emission time aperture suppresses the influence of blurring of the video caused by the person following the object and improves the quality of the moving image.

  However, in the method of shortening the light emission time aperture, it is necessary to increase the instantaneous luminance during the light emission period in order to keep the brightness of the display. For example, when the light emission period is shortened by half compared to the normal time, the instantaneous luminance is set to double that of the normal time. Here, the normal time is a case where light is emitted over the entire one frame period. In an organic EL display, it is said that the luminance is substantially proportional to the amount of current and the lifetime is proportional to the power of 1.7. For this reason, in the method of shortening the light emission time aperture, if the instantaneous luminance is set higher than the normal time, the lifetime may be accelerated.

  Therefore, as shown in FIG. 10, an adaptive time aperture control technique has been proposed in which a frame is divided into a moving area and a stationary area, and the light emission time aperture of the display is shortened adaptively (see Patent Document 1).

JP 2004-144928 A

  In the adaptive time aperture control technique described above, the light emission time aperture is changed in units of frames. That is, even if the video level is the same for a plurality of consecutive frames, frames having different light emission time apertures are continuous. In this case, the moving integral value of the luminance frame period unit fluctuates, and flicker-like fluctuations can be seen.

  Flicker-like fluctuation will be described with reference to FIG. The horizontal axis in FIG. 11 is time. The upper diagram (a) of FIG. 11 shows the time variation of the emission luminance, and the lower diagram (b) shows the integrated value of the emission luminance from time t- (one frame) to time t. FIG. 11 shows an example in which a frame with a light emission time aperture of 100% is followed by two frames with a light emission time aperture of 25%, and a frame with a light emission time aperture of 100%. In order to make the luminance when the light emission time aperture is 100% and the luminance when the light emission time aperture is 25%, assuming that the luminance of the light emission time aperture 100% is 100, the light emission time aperture is 25%. The brightness is 400.

  In the case of FIG. 11, when the emission time aperture is changed from 100% to the emission time aperture is 25%, the integrated value obtained by integrating the emission for one frame has an increase with a peak at 100 + 75 = 175. . This appears as flicker-like fluctuations. Further, when the light emission time aperture is changed from 25% to 100%, the integrated value obtained by integrating the light emission for one frame has a decrease with a peak at 100−75 = 25. This appears as flicker-like fluctuations. As a result, in the adaptive time aperture control technique, every time the light emission time aperture changes, a flicker-like change appears and image quality degradation occurs.

  An object of the present invention is to provide an image display apparatus that suppresses occurrence of flicker-like fluctuations.

  The image display device extracts an image display module, an input unit to which a video signal is input, a plurality of frames that are temporally moved from the video signal input to the input unit, and based on the plurality of extracted frames, Based on the extraction unit that extracts the movement of the subject recorded in the frame, the result of extraction by the extraction unit, the region of the frame is assumed to be a movement region where the subject is moving, and the subject is free of movement. And when the image display module displays an image based on a video signal, the light emission time of the dynamic region is shorter than the light emission time of the static region and the light emission of the dynamic region An image display control unit configured to make the luminance higher than the light emission luminance of the stationary region. In this case, the image display control unit matches the light emission time centers in the frames of the moving area and the stationary area.

  In addition, when the predetermined area of the plurality of frames shifts from a stationary area to a moving area that exists over a plurality of consecutive frames, the image display control unit is configured to perform a plurality of operations between the moving area and the stationary area. For the predetermined region of the frame, it is preferable to shorten the light emission time stepwise and increase the light emission luminance stepwise.

  In addition, when the predetermined area of the plurality of frames shifts from the moving area to a stationary area that exists over a plurality of consecutive frames, the image display control unit is configured to perform a plurality of operations between the moving area and the stationary area. For the predetermined region of the frame, it is preferable that the light emission time is increased stepwise and the light emission luminance is decreased stepwise.

  In addition, the image display device extracts an image display module, an input unit to which a video signal is input, and a plurality of frames that move back and forth in time from the video signal input to the input unit, and is based on the extracted frames An extraction unit that extracts the movement of the subject recorded in the frame, a moving region in which the subject is supposed to move, and a subject that is not moving based on the extraction result of the extraction unit And when the image display module displays an image based on a video signal, the light emission time of the moving region is shorter than the light emission time of the still region, and the moving region An image display control unit that makes the emission luminance of the display area higher than that of the stationary region. In this case, when the predetermined area of the plurality of frames shifts from the stationary area to a moving area that exists over a plurality of consecutive frames, the image display control unit may change the plurality of frames between the moving area and the stationary area. The predetermined region is caused to emit light a plurality of times within one frame period, and the temporal center of gravity of the plurality of times of light emission within the frame is made to coincide with the light emission time center within the frame of the static region.

  In addition, the image display device extracts an image display module, an input unit to which a video signal is input, and a plurality of frames that move back and forth in time from the video signal input to the input unit, and is based on the extracted frames An extraction unit that extracts the movement of the subject recorded in the frame, a moving region in which the subject is supposed to move, and a subject that is not moving based on the extraction result of the extraction unit And when the image display module displays an image based on a video signal, the light emission time of the moving region is shorter than the light emission time of the still region, and the moving region An image display control unit that makes the emission luminance of the display area higher than that of the stationary region. In this case, when the predetermined area of the plurality of frames shifts from the moving area to a stationary area that exists over a plurality of continuous frames, the image display control unit is configured to change the plurality of frames between the moving area and the stationary area. The predetermined region is caused to emit light a plurality of times within one frame period, and the temporal center of gravity of the plurality of times of light emission within the frame is made to coincide with the light emission time center within the frame of the static region.

  According to the present invention, it is possible to provide an image display device that suppresses occurrence of flicker-like fluctuations.

It is a block diagram for demonstrating one Embodiment of an image display apparatus. It is a figure for demonstrating the structure of a pixel. It is a figure for demonstrating the example which made the light emission time center in the flame | frame of a moving area | region and a stationary area correspond. It is a 1st figure for demonstrating the light emission waveform and the light emission integral value of 1 frame regarding the flame | frame which a motion area | region continues. It is a 2nd figure for demonstrating the light emission waveform and the light emission integral value of 1 frame regarding the flame | frame in which a motion area | region continues. It is a 3rd figure for demonstrating the light emission waveform and the light emission integral value of 1 frame regarding the flame | frame with which a moving area | region continues. It is a 4th figure for demonstrating the light emission waveform and the light emission integral value of 1 frame regarding the flame | frame with which a moving area | region continues. It is a 5th figure for demonstrating the light emission waveform and the light emission integral value of 1 frame regarding the flame | frame with which a moving area | region continues. It is a 1st figure for demonstrating related technology. It is a 2nd figure for demonstrating related technology. It is a 3rd figure for demonstrating related technology.

  Hereinafter, an embodiment of the present invention will be described. FIG. 1 is a block diagram for explaining an embodiment of an image display 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. Data signal line drive circuit 11 to be described later, selection signal line drive circuit 12 to be described later, control pulse generator for data signal 23, control pulse generator for selection signal 24, light emission time control pulse generator 26, and light emission time control signal line drive The circuit 27 is a component of the image display control unit 30.

  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 converter 22 converts the digital signal for transmission into a digital signal for displaying a video 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. Further, the extraction unit may extract a plurality of frames from a plurality of temporally continuous frames.

  As an 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).

  Further, the motion detection unit 25 divides, for each frame, a moving area where the subject is moving and a still area where the subject is not moving based on the extraction result of the amount of movement of the subject. To do. 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%. More specifically, when the light emission time control pulse generator 26 displays an image on the display panel 13, the moving time region in which the motion is detected by the motion detector 25 is 1 in comparison with the stationary region in which no motion is detected. Based on the synchronization signal, a pulse signal (light emission time control pulse) for controlling the light emission time of the organic EL element 14 is generated so as to shorten the light emission time of the organic EL element 14 per frame, and the light emission time control is performed. The signal line driving circuit 27 is supplied.

  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.
A characteristic configuration of the light emission time control signal line drive circuit 27 will be described later.

  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.

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.

  The data converter 22 converts the digital signal supplied to the data signal line drive circuit 11 in accordance with the data magnification described above, thereby increasing the light emission luminance of the organic EL element 14.

Next, a characteristic configuration of the image display device 1 will be described.
Here, the image display control unit 30 includes a data signal line drive circuit 11, a selection signal line drive circuit 12, a data conversion unit 22, a data signal control pulse generation unit 23, a selection signal control pulse generation unit 24, and a light emission time control. This is realized by the pulse generator 26 and the light emission time control signal line drive circuit 27.

The image display control unit 30 matches the light emission time centers in the frames of the moving area and the stationary area. That is, the image display control unit 30 matches the centers of the light emission times of the respective areas in the moving area and the stationary area in one frame. The “match” includes substantially matching.
For the still region, the control unit 30 causes the light emission time control pulse generation unit 26 to generate the light emission time control pulse, and when the light emission time control pulse is received by the light emission time control signal line drive circuit 27, as shown in FIG. As in the “static region”, the organic EL element 14 emits light over the entire one frame period. The stationary region is not limited to the example in which the organic EL element 14 emits light over the entire one frame period. When the one frame period is 100%, for example, 80% of the one frame period, The organic EL element 14 may emit light.
On the other hand, for the moving area, the image display control unit 30 does not cause the organic EL element 14 to emit light at the beginning of one frame period like the “moving area” shown in FIG. When the issuance time control signal line drive circuit 27 receives the light emission time control pulse signal so that the light emission time centers coincide, the organic EL element 14 is caused to emit light. That is, for the moving region, the image display control unit 30 matches the light emission time center in the frame of the organic EL element 14 (the light emission time center in the frame of the dynamic region) with the light emission time center in the framer of the stationary region. Or, approximately match.

FIG. 3 is a diagram for explaining an example in which the light emission time centers in the frames of the moving area and the stationary area are matched (first embodiment). Here, the upper diagram of FIG. 3 shows the emission waveform, and the lower diagram of FIG. 3 shows the integrated emission value of one frame obtained by integrating the emission of one frame. Also, the horizontal axis in FIG. 3 represents time, the vertical axis in the upper diagram represents luminance, and the vertical axis in the lower diagram represents an integrated value of luminance.
Each of the times t1 to t2, t2 to t3, t3 to t4, and t4 to t5 represents one frame period. Times t1 to t2 and t4 to t5 are stationary regions, and times t2 to t3 and t3 to t4 are moving regions.

In the case of the stationary region, the organic EL element 14 emits light over the entire one frame period, so that the image display control unit 30 sets the luminance to 100 at the time t1 to t2 and t4 to t5. To emit light.
On the other hand, in the case of the moving region (time t2 to t3 and t3 to t4), assuming that the light emission time is 25% of the stationary region, the image display control unit 30 sets the luminance to 400 at the center of one frame period. The organic EL element 14 is caused to emit light with the value to be used.

  In such a case, the light emission integral value of one frame is as shown in the lower diagram of FIG. That is, when the light emission luminance changes from 100 to 0 (immediately after the change from the stationary region to the dynamic region), the light emission integral value of one frame decreases to 100-37.5 = 62.5. Thereafter, when light is emitted at a value of 400 at the center of one frame period, the integrated emission value of one frame increases to 100 + 37.5 = 137.5. After that, when the light emission luminance becomes 0 (when the light emission in the moving region is finished), the light emission integral value of one frame decreases to 100.

Next, when the moving region continues, the light emission integral value of one frame is maintained at 100.
Next, when the stationary region follows the moving region (when the emission luminance is changed from 0 to 100 and then the value at which the emission luminance is 100 is maintained), the emission integrated value of one frame is 100 + 37.5. After rising to 137.5, descending to 100-37.5 = 62.5, and then rising to 100 and maintaining.

  As described above, the image display control unit 30 matches or substantially matches the light emission time center in the frame and the center time of one frame for the moving region. That is, the image display control unit 30 matches the light emission time centers in the frames of the moving area and the stationary area. Since the light emission integral value of one frame falls and rises in a short period (within one frame period), the luminance change cancels out, and it becomes difficult for the user to perceive it as flicker-like fluctuation. Therefore, the image display device 1 can suppress deterioration in image quality. Further, since the absolute value of the fluctuation of the light emission integral value is small in the image display device 1, it is possible to suppress the deterioration of the image quality compared to the case shown in FIG.

In addition, when the predetermined area of the plurality of frames shifts from the stationary area to the moving area that exists over a plurality of consecutive frames, the image display control unit 30 is configured to display the plurality of frames between the moving area and the stationary area. For a predetermined region, it is preferable to shorten the light emission time stepwise and increase the light emission luminance stepwise.
In addition, when the predetermined area of the plurality of frames shifts from the moving area to the stationary area that exists over a plurality of consecutive frames, the image display control unit 30 is configured to display the plurality of frames between the moving area and the stationary area. For a predetermined region, it is preferable to increase the light emission time stepwise and decrease the light emission luminance stepwise.
Even in the transition period in which the light emission time is changed stepwise, the light emission time centers in the frame are made to coincide or substantially coincide.

  The predetermined area is the same area (area corresponding to the scanning line) for a plurality of frames, and is an arbitrary area.

  For example, when the moving area continues over a plurality of frames after the stationary area, the image display control unit 30 normally performs the first frame or the moving areas of the plurality of frames in which the moving area exists. The light emission luminance is made lower than that of the frame having the moving region. Here, when the moving area continues over a plurality of frames (n frames) after the stationary area, the image display control unit 30 has the moving area, the first frame, or N (N <N) The light emission luminance of the nth frame is made lower than that of the frame having the normal moving area (the nth frame). Note that when the light emission luminance is set lower than that of the frame having the normal moving area, the image display control unit 30 makes the light emission time longer than that of the frame having the normal moving area.

For a plurality of frames having a moving area (from the first frame to the Nth frame), the light emission luminance is lower than that of a frame having a normal moving area, and the light emission time is longer than that of a frame having a normal moving area. In this case, the image display control unit 30 shortens the light emission time stepwise for the frame and increases the light emission luminance stepwise for the frame in the moving region of the first to Nth frames. In the transition period in which the light emission time in this case is changed stepwise, the light emission time centers in the frame are made coincident or substantially coincident.
Note that the transition period in which the light emission time is shortened stepwise and the light emission luminance is stepwise increased is not limited to the moving region, but is set to extend from the stationary region to the moving region (from the moving region to the stationary region). May be. Even in this case, in the transition period in which the light emission time is changed stepwise, the light emission time centers in the frame are made to coincide or substantially coincide.

  Next, a second embodiment will be described. FIG. 4 is a first diagram for explaining a light emission waveform and a light emission integral value of one frame with respect to a frame in which a moving region is continuous. Specifically, FIG. 4 is a first diagram for explaining a light emission waveform and a light emission integral value of one frame when a moving region exists in three frames after a static region.

  One frame period from time t1 to t2 indicates a frame F1 in a still area. One frame period from time t2 to t3 indicates the frame F2 in the moving area. One frame period from time t3 to t4 indicates the frame F3 in the moving area. One frame period from time t4 to t5 indicates the frame F4 in the moving area.

The image display control unit 30 lowers the light emission luminance and extends the light emission time for the frame F2 compared to the frames F3 and F4 (frames having a normal moving area). Here, also in the frame F2, the light emission time centers in the frame are matched or substantially matched.
That is, when a transition is made from a stationary region with a light emission time of 100% to a moving region with a light emission time of 25%, the image display control unit 30 sets the light emission time for frame F2, for example, 50%, and the light emission time for frames F3 and F4. Is 25%. In this case, assuming that the luminance of the frame F1 is 100, the luminance of the frame F2 is 200, and the luminance of the frames F3 and F4 is 400.

  In such a case, the emission integrated value of one frame decreases from 100 at time t1 to t2 to 100−25 = 75 at time t2 to t3, further increases to 100 + 25 = 125, and then returns to 100. Further, the light emission integral value of one frame falls to 100−25 = 75 at time t3 to t4, further rises to 100 + 25 = 125, and then returns to 100. From time t4 to t5, the light emission integral value of one frame is maintained at 100.

  As a result, the change in the light emission integral value for one frame is smaller than that in the case shown in FIG. 3, so that flicker-like fluctuations are not easily perceived by the user. Therefore, the image display device 1 can further suppress deterioration in image quality.

  Next, a third embodiment will be described. FIG. 5 is a second diagram for explaining a light emission waveform and a light emission integral value of one frame with respect to a frame in which a moving region is continuous. Specifically, FIG. 5 is a second diagram for explaining a light emission waveform and a light emission integral value of one frame when a moving region exists in three frames after a still region.

  One frame period from time t1 to t2 indicates a frame F1 in a still area. One frame period from time t2 to t3 indicates the frame F2 in the moving area. One frame period from time t3 to t4 indicates the frame F3 in the moving area. One frame period from time t4 to t5 indicates the frame F4 in the moving area.

The image display control unit 30 lowers the light emission luminance and extends the light emission time for the frames F2 and F3, compared to the frame F4 (a frame having a normal moving area). Here, also in the frames F2 and F3, the light emission time centers in the frames are matched or substantially matched.
That is, when the light emission time shifts from the 100% stationary region to the motion region where the light emission time is 25%, the image display control unit 30 gradually shortens the light emission time for the frames F2 and F3 and emits light. The brightness is increased step by step. For example, the light emission time of the frame F2 is 75%, the light emission time of the frame F3 is 50%, and the light emission time of the frame F4 is 25%. In this case, assuming that the luminance of the frame F1 is 100, the luminance of the frame F2 is 133, the luminance of the frame F3 is 200, and the luminance of the frame F4 is 400.

  In such a case, the emission integrated value of one frame decreases from 100 at time t1 to t2 to 100-12.5 = 87.5 at time t2 to t3, and further to 100 + 12.5 = 112.5. After rising, return to 100. Further, the light emission integral value of one frame falls at 100-16.7 = 83.3 at time t3 to t4, further rises to 100 + 16.7 = 16.7, and then returns to 100. Further, the light emission integral value of one frame falls to 100−25 = 75 from time t4 to t5, further rises to 100 + 25 = 125, and then returns to 100.

  As a result, the peak of the light emission integral value of one frame is suppressed compared to the case shown in FIG. 4, and flicker-like fluctuations are hardly perceived by the user. Therefore, the image display device 1 can further suppress deterioration in image quality.

  The number of frames for changing the light emission time and the light emission luminance in stages is not limited to 1 or 2 as shown in FIGS. 4 and 5, but can be set as appropriate according to the number of frames in the continuous moving area. Good.

  4 and 5, the example in which the light emission time and the light emission luminance are changed stepwise when moving from the static region to the moving region has been described. However, according to the present invention, when a predetermined area of a plurality of frames shifts from a moving area to a stationary area that exists over a plurality of consecutive frames, the predetermined area of the plurality of frames between the moving area and the stationary area is determined. For these areas, the light emission time may be increased stepwise and the light emission luminance may be decreased stepwise.

In addition, when the predetermined area of a plurality of frames shifts from a stationary area to a moving area that exists over a plurality of consecutive frames, the image display control unit 30 performs a plurality of frames between the moving area and the stationary area. In one frame period, it is preferable that the predetermined region is caused to emit light a plurality of times, and the temporal center of gravity of the plurality of times of light emission within the frame is matched with the light emission time center within the frame of the still region.
In addition, when the predetermined area of a plurality of frames shifts from a moving area to a stationary area that exists over a plurality of consecutive frames, the image display control unit 30 performs a plurality of frames between the moving area and the stationary area. In one frame period, it is preferable that the predetermined region is caused to emit light a plurality of times, and the temporal center of gravity of the plurality of times of light emission within the frame is matched with the light emission time center within the frame of the still region.
Note that “matching” includes substantially matching.

  Next, an example (fourth example) in the case where the above-described moving region is caused to emit light a plurality of times will be described. FIG. 6 is a third diagram for explaining a light emission waveform and a light emission integral value of one frame with respect to a frame in which a moving region is continuous. Specifically, FIG. 6 is a third diagram for explaining a light emission waveform and a light emission integral value of one frame when there is a moving region in three frames after the static region.

  One frame period from time t1 to t2 indicates a frame F1 in a still area. One frame period from time t2 to t3 indicates the frame F2 in the moving area. One frame period from time t3 to t4 indicates the frame F3 in the moving area. One frame period from time t4 to t5 indicates the frame F4 in the moving area.

  For the first frame of the plurality of frames in which the moving area continues, the image display control unit 30 causes the moving area to emit light a plurality of times. Here, when light is emitted a plurality of times within one frame, the temporal center of gravity of the light emission within the frame is made coincident or substantially coincident with the light emission temporal center in the frame of the still region. In the example illustrated in FIG. 6, the image display control unit 30 causes the organic EL element to emit light three times with respect to the moving region of the frame F2. That is, the image display control unit 30 distributes light emission within one frame period with respect to the moving region of the frame F2.

  More specifically, when the frames F1 to F4 (moving areas) having a light emission time of 25% follow the frames F1 (stationary areas) having a light emission time of 100%, the image display control unit 30 performs the frame F2 For the moving region, light emission is performed a plurality of times with a total light emission time of 25%. In the example shown in FIG. 6, light emission with a light emission time of 12.5% is performed at the center of one frame period, and light emission with a light emission time of 6.25% is performed before and after that.

In such a case, the light emission integral value of one frame is as shown in the lower diagram of FIG. That is, when the light emission luminance changes from 100 to 0 (after changing from the stationary region to the moving region), the light emission integral value of one frame decreases to 100−25 = 75. Thereafter, when light is emitted a plurality of times, the light emission integral value of one frame rises to 100 + 25 = 125. After that, when the light emission luminance becomes 0 (when the light emission in the moving region is finished), the light emission integral value of one frame decreases to 100.
Next, when the moving region (frame F3) continues, the emission integrated value of one frame decreases to 100−25 = 75, then increases to 100 + 25 = 125, and then decreases to 100 and is maintained.

  As a result, the change in the light emission integral value for one frame is smaller than in the case illustrated in FIG. 3, so that flicker-like fluctuations are not easily perceived by the user. Therefore, the image display device 1 can further suppress deterioration in image quality.

Note that when the moving region of the frame is caused to emit light a plurality of times, the number of times of light emission is not limited to three as shown in FIG.
For example, as in the fifth embodiment shown in FIG. 7, the light emission time at the center time of one frame may be 12.5%, and the fine light emission time may be dispersed before and after that. In this case, the average luminance of the plurality of times of light emission is as indicated by a broken line A, and the light emission time center in the frame of the stationary region and the time center of gravity of the plurality of times of light emission in the frame are matched or substantially matched.

  In such a case, the light emission integral value of one frame is as shown in the lower diagram of FIG. That is, in the frame F2, the integrated light emission value of one frame drops to 100-18.75 = 81.25, then rises to 100 + 18.75 = 118.75, and then drops to 100. In the frame F3, the light emission integral value of one frame decreases to 100-18.4 = 81.6, then increases to 100 + 18.4 = 1118.4, and then decreases to 100 and is maintained.

  Thereby, since the change of the light emission integral value of one frame becomes smooth, the flicker-like fluctuation is hardly perceived by the user. Therefore, the image display device 1 can further suppress deterioration in image quality.

  Further, for example, as in the sixth embodiment shown in FIG. 8, the fine light emission time may be dispersed throughout one frame while the total light emission time of one frame is 25%. In this case, the average luminance of the plurality of times of light emission is as indicated by a broken line B, and the light emission time center in the frame of the still region and the time center of gravity of the plurality of times of light emission in the frame are matched or substantially matched.

  In such a case, the light emission integral value of one frame is as shown in the lower diagram of FIG. That is, in the frame F2, the light emission integral value of one frame decreases to 100-12.5 = 87.5, then increases to 100 + 12.5 = 112.5, and then decreases to 100. In the frame F3, the light emission integral value of one frame decreases to 100−28.125 = 71.875, then increases to 100 + 28.125 = 128.125, and then decreases to 100 and is maintained.

  As a result, the change in the light emission integral value of one frame becomes smooth, and flicker-like fluctuations are hardly perceived by the user. Therefore, the image display device 1 can suppress deterioration in image quality.

  In addition, when performing light emission a plurality of times within one frame, the number of frames for performing light emission a plurality of times is not limited to one as shown in FIGS. A plurality of sheets may be set in a timely manner.

Further, in FIGS. 6 to 8, the example in which light emission is performed a plurality of times within one frame when moving from the static region to the moving region has been described. However, according to the present invention, the predetermined region of the plurality of frames between the moving region and the stationary region can be changed even when the predetermined region of the plurality of frames shifts to a stationary region that exists over a plurality of continuous frames from the moving region. The region may emit light a plurality of times within one frame period. Also in this case, the temporal centroid of the multiple times of light emission in the frame and the light emission time center in the frame of the stationary region are matched or substantially matched.
In addition, when performing a plurality of times of light emission within a single frame period for a predetermined area of a plurality of frames between the moving area and the stationary area, the plurality of times of light emission is not limited to the moving area, but from the stationary area to the moving area. You may install so that it may straddle (from a moving area to a stationary area). Also in this case, the temporal centroid of the multiple times of light emission in the frame and the light emission time center in the frame of the stationary region are matched or substantially matched.

  As described above, the image display device 1 emits light with the light emission time centers in the frames of the moving region and the stationary region being matched or substantially matched (Example 1). As for the moving region, the light emission integral value of one frame falls and rises in a short period (within one frame period), so that the change in luminance cancels out and it is difficult for the user to perceive it as flicker-like fluctuation. it can. Therefore, the image display device 1 can suppress deterioration in image quality.

In addition, when the predetermined area of the plurality of frames shifts from the stationary area to the moving area that exists over a plurality of consecutive frames, the image display device 1 determines the predetermined number of the plurality of frames between the moving area and the stationary area. With respect to the region, the light emission time is shortened stepwise and the light emission luminance is increased stepwise (Examples 2 and 3). Here, in the transition period in which the light emission time is changed stepwise, the light emission time centers in the frame are made to coincide or substantially coincide.
Thereby, since the fall and rise of the light emission integral value of one frame within one frame period are reduced, it can be made difficult to be perceived by the user as flicker-like fluctuations. Therefore, the image display device 1 can further suppress deterioration in image quality.

In addition, when the predetermined area of the plurality of frames shifts from the moving area to a stationary area that exists over a plurality of consecutive frames, the image display device 1 has a plurality of frames between the moving area and the stationary area. For the predetermined area, the light emission time is increased stepwise and the light emission luminance is decreased stepwise. Here, in the transition period in which the light emission time is changed stepwise, the light emission time centers in the frame are made to coincide or substantially coincide.
Thereby, since the fall and rise of the light emission integral value of one frame within one frame period are reduced, it can be made difficult to be perceived by the user as flicker-like fluctuations. Therefore, the image display device 1 can further suppress deterioration in image quality.

  In addition, when the predetermined area of the plurality of frames shifts from the stationary area to the moving area that exists over a plurality of continuous frames, the image display device 1 In one frame period, a predetermined region is caused to emit light a plurality of times. Further, when the predetermined area of the plurality of frames shifts from the moving area to a stationary area that exists over a plurality of continuous frames, the image display device 1 In one frame period, a predetermined region is caused to emit light a plurality of times. In this case, the image display device 1 matches or substantially matches the temporal center of gravity of a plurality of times of light emission in the frame with the light emission time center in the frame of the still region (Examples 4 to 6). Thereby, since the change of the light emission integral value of one frame becomes smooth, the flicker-like fluctuation is hardly perceived by the user. Therefore, the image display device 1 can further suppress deterioration in image quality.

DESCRIPTION OF SYMBOLS 1 Image display apparatus 10 Image display module 21 Synchronization separation part 252 Division part 251 Extraction part 30 Image display control part

Claims (5)

An image display module;
An input unit for inputting a video signal;
An extraction unit that extracts a plurality of frames that move back and forth in time from the video signal input to the input unit, and extracts a motion of a subject recorded in the frame based on the plurality of 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;
When displaying an image based on a video signal on the image display module, the light emission time of the moving region is shorter than the light emission time of the still region, and the light emission luminance of the moving region is higher than the light emission luminance of the still region. An image display control unit for
The image display control unit is an image display device that matches a light emission time center in a frame between the moving area and the stationary area. When the predetermined area of the plurality of frames shifts from a stationary area to a moving area that exists over a plurality of consecutive frames, the image display control unit is configured to display a plurality of frames between the moving area and the stationary area. The image display apparatus according to claim 1, wherein the light emission time is shortened stepwise and the light emission luminance is increased stepwise for the predetermined region. When the predetermined region of the plurality of frames shifts from the moving region to a stationary region existing over a plurality of consecutive frames, the image display control unit is configured to display a plurality of frames between the moving region and the stationary region. The image display device according to claim 1, wherein the light emission time is increased stepwise and the light emission luminance is decreased stepwise for the predetermined region. An image display module;
An input unit for inputting a video signal;
An extraction unit that extracts a plurality of frames that move back and forth in time from the video signal input to the input unit, and extracts a motion of a subject recorded in the frame based on the plurality of 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;
When displaying an image based on a video signal on the image display module, the light emission time of the moving region is shorter than the light emission time of the still region, and the light emission luminance of the moving region is higher than the light emission luminance of the still region. An image display control unit for
When the predetermined area of the plurality of frames shifts from a stationary area to a moving area that exists over a plurality of consecutive frames, the image display control unit performs a plurality of frames between the moving area and the stationary area. An image display device that causes the predetermined region to emit light a plurality of times within one frame period, and matches a temporal center of gravity of the plurality of times of light emission within the frame with a light emission time center within the frame of the stationary region. An image display module;
An input unit for inputting a video signal;
An extraction unit that extracts a plurality of frames that move back and forth in time from the video signal input to the input unit, and extracts a motion of a subject recorded in the frame based on the plurality of 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;
When displaying an image based on a video signal on the image display module, the light emission time of the moving region is shorter than the light emission time of the still region, and the light emission luminance of the moving region is higher than the light emission luminance of the still region. An image display control unit for
When the predetermined area of the plurality of frames shifts from the moving area to a stationary area that exists over a plurality of consecutive frames, the image display control unit is configured to detect a plurality of frames between the moving area and the stationary area. An image display device that causes the predetermined region to emit light a plurality of times within one frame period, and matches a temporal center of gravity of the plurality of times of light emission within the frame with a light emission time center within the frame of the stationary region.

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