JP2013130744A - Image display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce an electric power consumption in displaying an image with a subtitle and appropriately control a light emission luminance of a backlight region corresponding to a display area of the subtitle.SOLUTION: An area active control part 3 and an LED control part 6 divide a backlight corresponding to a display region of a first image signal into a plurality of regions and execute a first brightness control in which a light emission luminance of an LED of the backlight corresponding to each of the divided regions is determined in accordance with the first image signal corresponding to each of the divided regions. The area active control part 3 and the LED control part 6 also execute a second brightness control when accepting a display instruction of a second image signal during the execution of the first brightness control, independently of the first brightness control. In the second brightness control, a light emission luminance of the LED of the backlight corresponding to a display region of the second image signal is controlled to have a value less than the maximum light emission luminance of the LED and more than 0 for a predetermined duration of time.

Description

  The present invention relates to a video display device that displays a video signal.

  In a conventional video display device including a liquid crystal panel and a backlight, the liquid crystal panel is illuminated with a backlight while displaying the video by modulating the transmittance of the liquid crystal panel according to the input video. Some of such video display devices always emit light with a backlight of 100%. However, such a video display device has a problem that power consumption increases.

  In recent years, a technique for controlling the light emission luminance of the backlight based on a feature amount of a video signal such as APL (Average Picture Level) has been developed. However, with this technique, when a subtitle is displayed or deleted in a video, the feature amount of the video signal changes due to the luminance of the subtitle area. This change affects the luminance of the backlight and causes a flicker phenomenon.

  For this reason, Patent Document 1 discloses a liquid crystal display in which the luminance of the backlight is not affected by the display and erasure of the subtitles by measuring the feature amount of the video signal excluding the subtitle display area. An apparatus is disclosed.

  In addition, when the APL is large, the video itself is bright, so that it is not necessary to further increase the light emission luminance of the backlight. For this reason, the liquid crystal display device of Patent Document 1 decreases the light emission luminance of the backlight as the APL increases in a region where the APL is extremely high. Thereby, reduction of power consumption is realized.

JP 2007-140383 A

  However, the above-described conventional technique of Patent Document 1 is a technique for controlling the light emission luminance of the backlight corresponding to the video display area other than the subtitle area, and the power consumption of the light emission luminance of the backlight corresponding to the subtitle area is reduced. It did not indicate a solution to the problem of how to properly control while reducing.

  For example, if the same brightness control is performed for the caption area and the video display area other than the caption area, the emission brightness of the backlight area corresponding to the caption area is the same as that of the video signal measured excluding the caption area. Depending on the feature quantity of the video signal, the light emission luminance of the backlight area corresponding to the caption area becomes too high, and there is a possibility that black floating occurs in the caption area.

  In view of the above circumstances, the present invention reduces the power consumption when displaying subtitles and the like together with the video, and can display the luminance of the backlight area corresponding to the display area appropriately. An object is to provide an apparatus.

  In order to solve the above problems, a first technical means of the present invention is a video display device for displaying a video signal, a display panel for displaying the first video signal and the second video signal, and the display A backlight using an LED as a light source for illuminating the panel, a control unit for controlling the light emission luminance of the LED of the backlight, and a display instruction receiving unit for receiving a display instruction for the second video signal, The control unit divides the backlight corresponding to the display area of the first video signal into a plurality of areas, and in accordance with the first video signal corresponding to each of the divided areas, While performing the first luminance control for determining the emission luminance of the LED of the corresponding backlight, the display instruction receiving unit issues a display instruction for the second video signal during the first luminance control. If accepted Independently of the first brightness control, the light emission brightness of the backlight LED corresponding to the display area of the second video signal is set to a value greater than 0 below a maximum light emission brightness of the LED for a predetermined time. A second brightness control is performed.

  According to a second technical means of the present invention, in the first technical means, the second luminance control includes the second video signal after the second video signal is displayed and the second video signal is erased. The light emission luminance of the backlight LED corresponding to the display area of the video signal is controlled so as to be gradually changed over time.

  According to a third technical means of the present invention, in the first technical means or the second technical means, the first luminance control includes: a luminance of an LED of a backlight corresponding to a display area of the first video signal; Control is performed based on the lighting rate of the backlight or the first video signal within a range in which the total value of the LED drive currents is equal to or less than a predetermined allowable current value.

  According to the present invention, the backlight corresponding to the display area of the first video signal is divided into a plurality of areas, and each of the divided areas corresponds to the first video signal corresponding to each divided area. The first luminance control is performed when the display instruction of the second video signal is received during the first luminance control while performing the first luminance control for determining the light emission luminance of the backlight LED. Independently, second luminance control is performed to control the emission luminance of the backlight LED corresponding to the display area of the second video signal to a value greater than 0 and less than the maximum emission luminance of the LED for a predetermined time. As a result, when subtitles and the like are displayed together with the video, it is possible to reduce the power consumption and appropriately control the light emission luminance of the backlight area corresponding to the display area.

It is a figure which shows the principal part structural example of the liquid crystal display device which concerns on embodiment of this invention. It is a figure which shows an example of the image | video processed by the process part with which a liquid crystal display device is provided. It is a figure explaining the setting method of the maximum light emission luminance of LED of LED backlight. It is a figure which shows LED of a LED backlight corresponding to a caption area and the caption area. It is a figure explaining the luminance control performed with respect to LED of LED backlight corresponding to a caption area.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram illustrating a configuration example of a main part of a liquid crystal display device 1 according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating an example of an image processed by a processing unit included in the liquid crystal display device 1. . As shown in FIG. 1, the liquid crystal display device 1 includes an image processing unit 2, an area active control unit 3, a panel control unit 4, an LCD (Liquid Crystal Display) panel 5, an LED (Light Emitting Diode) control unit 6, an LED back. A light 7 is provided.

  The image processing unit 2 receives a video / audio signal separated from a broadcast signal and a video / audio signal from an external device and performs video signal processing such as decoding the encoded video / audio signal. FIG. 2A shows an example of a video signal input to the image processing unit 2. The image processing unit 2 appropriately executes, for example, IP conversion, noise reduction, scaling processing, γ adjustment, white balance adjustment, and the like on the input video signal.

  In addition, the image processing unit 2 gives an instruction to display a video signal such as subtitles or OSD information, or an instruction to erase a video signal such as subtitles or OSD information, which is performed by a viewer using a remote controller (not shown). Accept.

  When the image processing unit 2 receives an instruction to display a video signal such as subtitles or OSD information, the image processing unit 2 displays a video signal on which a video signal such as subtitles or OSD information (for example, a sub screen, a clock, or a menu screen) is superimposed. The generated video signal is output to the area active control unit 3. At that time, the image processing unit 2 also outputs a control signal indicating the display position of the superimposed caption or OSD information.

  Further, when receiving an instruction to delete a video signal such as subtitles or OSD information, the image processing unit 2 outputs a video signal on which no video signal such as subtitles or OSD information is superimposed to the area active control unit 3. The image processing unit 2 corresponds to the display instruction receiving unit in the claims.

  The area active control unit 3 executes a local dimming process. Specifically, the area active control unit 3 divides an image displayed by the video signal into predetermined regions according to the video signal input by the image processing unit 2, and sets the maximum gradation value of the video signal for each divided region. Extract.

  Then, the area active control unit 3 increases the light emission luminance of the LED backlight 7 in the region where the maximum gradation value is large, and decreases the light emission luminance of the LED in the region where the maximum gradation value is small. The emission luminance is controlled according to the extracted maximum gradation value.

  Note that here, the emission luminance of the LED is controlled using the maximum gradation value of each divided area, but the emission luminance of the LED is determined using other feature amounts such as the gradation average value of each divided area. It is good also as controlling.

  Further, the area active control unit 3 increases the brightness of the LED backlight 7 and improves the contrast while keeping the total value of the drive currents for turning on the LEDs of the LED backlight 7 below a predetermined allowable current value. Take control.

  Specifically, the area active control unit 3 calculates the lighting rate of the LED backlight 7 corresponding to each divided region based on the maximum gradation value of the video signal extracted for each divided region. The lighting rate is the ratio of the maximum gradation value of the video signal in each divided area to the gradation value that the video signal can take.

  For example, the gradation value that the video signal can take is 256 gradations, there are eight divided areas, and the maximum gradation value of the video signal in the eight divided areas is 64, 224, 160, 32, 128, 192, 192. , 96, the lighting rates of the LED backlight 7 corresponding to each divided region are 25.0%, 87.8%, 62.7%, 12.5%, 50.2%, 75.3, respectively. %, 75.3%, and 37.6%.

  Moreover, the area active control part 3 calculates an average lighting rate. In the example described above, the average lighting rate is 53.3%. Then, the area active control unit 3 sets the maximum light emission luminance of the LED of the LED backlight 7 using the average lighting rate.

  FIG. 3 is a diagram for explaining a method for setting the maximum light emission luminance of the LED of the LED backlight 7. The horizontal axis of FIG. 3 is the average lighting rate of the LED backlight 7. The average lighting rate is 0% when all the LEDs in each area of the LED backlight 7 corresponding to each divided area are turned off, and all the LEDs in each area of the LED backlight 7 corresponding to each divided area are turned on. Then, it becomes 100%. The vertical axis | shaft of FIG. 3 shows the maximum light emission luminance of LED of the LED backlight 7 in each average lighting rate.

  In the power limit control, it is assumed that the total value of the drive current for lighting each LED of the LED backlight 7 is constant. In the range where the average lighting rate is larger than P, the larger the average lighting rate, the smaller the current that can be supplied to one divided region, so the maximum light emission luminance becomes smaller.

  In a region where the average lighting rate is large, the image is felt dazzling, but this dazzling is suppressed by decreasing the maximum light emission luminance. Further, when the average lighting rate is near P, the maximum light emission luminance is the highest. When the maximum emission luminance is increased, the color reproducibility of a light source such as the sun or light is improved.

  In the range where the average lighting rate is smaller than P, it is possible to increase the maximum light emission luminance. However, since the image in this range is a dark image, reducing the maximum light emission luminance reduces the black expression. Realize, suppress black float, and maintain display quality.

  The area active control unit 3 determines the final luminance of each divided region using the relationship shown in FIG. 3 and outputs the determined luminance data to the LED control unit 6. Specifically, the area active control unit 3 multiplies the luminance determined for each divided region according to the maximum gradation value by the local dimming process by the luminance increase rate, thereby obtaining the final luminance of each divided region. decide. Here, the luminance increase rate means a ratio a / b where the maximum emission luminance at a certain average lighting rate is a and the maximum emission luminance at 100% average lighting rate is b.

For example, if the maximum light emission luminance is 800 cd / m ² when the average lighting rate is 64.0% and the maximum light emission luminance when the average lighting rate is 100% is 533 cd / m ² , the luminance increase rate a / b is 1.5.

  In this case, the area active control unit 3 determines the final luminance of each divided region by multiplying the luminance determined for each divided region according to the maximum gradation value by the local dimming process by 1.5. . It is assumed that the relationship between the maximum luminance and the average lighting rate shown in FIG. 3 is stored in advance in a storage unit (not shown) included in the video display device 1.

  The area active control unit 3 outputs control data for controlling the LCD panel 5 to the panel control unit 4 for video display.

  Furthermore, the area active control unit 3 outputs a video signal in which a video signal such as caption or OSD information is superimposed from the image processing unit 2 and a control signal indicating a display position of the superimposed caption or OSD information. Based on these signals, the luminance of the LED backlight 7 corresponding to the area in which the video signal such as subtitles and OSD information is displayed is displayed, and video signals other than the video signals such as subtitles and OSD information are displayed. Control is performed independently of the process of controlling the light emission luminance of the LED of the LED backlight 7 corresponding to the region.

  FIG. 4 is a diagram showing the caption area 10 and the LED 12 of the LED backlight 7 corresponding to the caption area 10. FIG. 4A shows a caption area 10 in which captions are displayed and a normal video area 11. FIG. 4B shows the LED 12 of the LED backlight 7 corresponding to the caption area 10 and the LED 13 of the LED backlight 7 corresponding to the normal video area 11.

  Then, the first luminance control by the local dimming process and the power limit control is performed on the LED 13 of the LED backlight 7 corresponding to the normal video area 11, and the LED 12 of the LED backlight 7 corresponding to the caption area 10 is performed. In contrast, the following second luminance control is performed independently of the first luminance control.

  FIG. 5 is a diagram illustrating the brightness control performed on the LED 12 of the LED backlight 7 corresponding to the caption area 10. As shown in FIG. 5, the area active control unit 3 sets the luminance of the LED 12 to be smaller than 100% of the maximum light emission luminance of the LED 12 while the subtitle is displayed (time t1 to t2 and time t3 to t4). Control is performed so that the predetermined value LIMIT is greater than 0%.

  In addition, after the caption is displayed (time t2 to t3 and time t4 to), the area active control unit 3 performs control so that the luminance of the LED 12 gradually decreases as time elapses. Note that FIG. 5 shows a case where the luminance of the LED 12 decreases linearly with time, but it may be controlled so as to decrease along a curve such as a quadratic curve.

  As described above, the power consumption is reduced by controlling the light emission luminance of the LED 12 of the LED backlight 7 corresponding to the caption area 10 to be a predetermined value LIMIT that is less than the maximum light emission luminance of the LED 12 and larger than 0. In addition, it is possible to suppress the occurrence of black floating due to the caption area 10 becoming too bright. Here, the predetermined allowable current value at the time of performing the power limit control described above is set to such a value that the LED 12 of the LED backlight 7 corresponding to the caption area 10 can emit light with the luminance value LIMIT.

  In addition, it is possible to suppress a sudden change in the brightness of the video and subtitles. This point will be described with reference to FIG. 3, taking as an example a case where a bright subtitle is displayed on a dark background. In FIG. 3, it is assumed that the average lighting rate when subtitles are displayed is A, and the average lighting rate when subtitles are erased is B. If the luminance control of the present invention is not performed when the caption is erased, the maximum luminance changes by ΔL (= LB−LA) from LA to LB, so that the brightness of the video and the caption changes abruptly. , I feel uncomfortable.

  However, in the present invention, as shown in FIG. 5, after the caption is erased, the brightness of the video and the caption is reduced by gradually decreasing the brightness of the LED 12 of the LED backlight 7 corresponding to the caption area 10. A sudden change can be suppressed. In addition, when the caption is displayed next time, the sudden change in the brightness of the video and the caption is alleviated.

  When dark subtitles are displayed on a light background, if the local dimming process is performed, the brightness of the LED backlight LED corresponding to the subtitle area decreases, so the average lighting rate also decreases and the subtitles are erased. As a result, the average lighting rate increases. For example, in FIG. 3, it is assumed that the average lighting rate when subtitles are displayed is B, and the average lighting rate when subtitles are deleted is A. In such a case, after the subtitle is erased, the brightness of the LED and the subtitle corresponding to the subtitle area is gradually increased to suppress a sudden change in the brightness of the video and the subtitle.

  The panel control unit 4 controls display of images on the LCD panel 5 using the control data output from the area active control unit 3. FIG. 2B shows an example of a video signal output to the LCD panel 5. The LCD panel 5 is a display panel such as a liquid crystal panel, and is illuminated by the LED of the LED backlight 7 to display an image.

  The LED control unit 6 controls the light emission luminance of the LED of the LED backlight 7 using the luminance data output by the area active control unit 3. The area active control unit 3 and the LED control unit 6 correspond to the control unit in the claims. FIG. 2C shows an example of control of the LED emission luminance of the LED backlight 7.

  The LED backlight 7 is a backlight using LEDs as a light source for illuminating the LCD panel 5. FIG. 2D shows an example of an image obtained as a result of the LCD panel 5 being illuminated by the LED backlight 7. Although the brightness control of the LED of the LED backlight 7 is performed by PWM control, it may be controlled to have a desired value by current control or a combination thereof.

  Note that the present invention is not limited to the above-described embodiment, and various modifications and corrections are possible without departing from the spirit of the present invention.

  For example, in the above-described embodiment, the case where the luminance is controlled using the lighting rate of the LED backlight 7 has been described, but the same control is performed even if the APL (Average Picture Level) of the video signal is used. Can do.

  Since APL is the average value of the luminance of the entire video signal (including normal video signals and video signals such as captions and OSD information), the relationship between APL and the maximum luminance of the LED is the same as that shown in FIG. It is thought that it shows the tendency of. That is, when the APL of the video signal is low, the lighting rate of the LED backlight 7 is low, and when the APL of the video signal is high, the lighting rate of the LED backlight 7 is high. Therefore, similar control can be performed even when the horizontal axis in FIG. 3 is APL.

DESCRIPTION OF SYMBOLS 1 ... Liquid crystal display device, 2 ... Image processing part, 3 ... Area active control part, 4 ... Panel control part, 5 ... LCD (Liquid Crystal Display) panel, 6 ... LED (Light Emitting Diode) control part, 7 ... LED back Light: 10 ... Subtitle area, 11: Normal video area, 12 ... LED backlight LED corresponding to subtitle area, 13 ... LED backlight LED corresponding to normal video area

Claims (3)

A video display device for displaying a video signal,
A display panel for displaying the first video signal and the second video signal;
A backlight using LEDs as a light source for illuminating the display panel;
A control unit for controlling the light emission luminance of the LED of the backlight;
A display instruction receiving unit for receiving a display instruction for the second video signal;
With
The control unit divides a backlight corresponding to the display area of the first video signal into a plurality of areas, and the divided areas according to the first video signal corresponding to the divided areas. The display instruction receiving unit performs a display instruction for the second video signal while performing the first brightness control for determining the light emission brightness of the LED of the backlight corresponding to Independent of the first luminance control, the luminance of the backlight LED corresponding to the display area of the second video signal is less than the maximum luminance of the LED for a predetermined time. A video display device that performs second luminance control for controlling to a value larger than zero.   In the second luminance control, the luminance of the backlight LED corresponding to the display area of the second video signal after the second video signal is displayed and the second video signal is erased is controlled. 2. The video display device according to claim 1, wherein the video display device is controlled so as to be gradually changed as time elapses.   In the first luminance control, the light emission luminance of the backlight LED corresponding to the display area of the first video signal is set within a range where the total value of the drive currents of the LEDs is equal to or less than a predetermined allowable current value. The video display device according to claim 1, wherein the video display device is controlled based on a lighting rate of a backlight or the first video signal.