JP2011033801A - Video display device and video display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suitably control illumination of a backlight source with respect to a time difference in scanning a plurality of display pixels which are collectively illuminated by the backlight. <P>SOLUTION: A video characteristic information detecting unit 201 outputs video characteristic information detected based on an inputted video signal to a lighting value setting unit 202. The lighting value setting unit 202 determines lighting value information based on the inputted video characteristic information and outputs the information to a lighting value level detecting unit 203, a backlight control unit 204 and the like. The lighting value level detecting unit 203 determines whether or not the inputted lighting value information is equal to or lower than a predetermined value. When the inputted lighting value information is determined as equal to or lower than the predetermined value, the backlight control unit 204 outputs backlight control information by pulses within a predetermined time to the backlight 102 to turn on or off the light on the basis of the input lighting value information. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an image display apparatus and an image display method for displaying an image by illuminating a liquid crystal panel with a backlight light source.

In recent years, television receivers using a liquid crystal display (hereinafter referred to as LCD) have been widely used.
In addition, as the amount of data transferred for video content is improved and the resolution is increased, the performance and size of the video display unit are expected to increase. The development of various technologies to meet this expectation and the improvement of the video display unit performance Many technologies have been developed for overcoming the problems associated with the increase in size and size.

  In particular, the “motion” in moving image display on the LCD is caused by the response characteristics of the liquid crystal itself that delays the response to the control signal in the LCD and the charge retention characteristics of the liquid crystal element for holding specific data for a predetermined time. Many techniques for overcoming the problem related to “blurring” have been disclosed.

  For example, according to Patent Document 1, a method of controlling a backlight light source so as to intermittently light within a vertical period, which detects a feature amount of an image signal in a vertical period to be displayed, and based on the detected feature amount. Thus, a method for variably controlling the lighting time of the backlight is disclosed.

JP 2004-062134 A (FIG. 4, paragraphs 0044-0046)

  However, according to the technique of Patent Document 1, a predetermined number of light sources among a plurality of light sources arranged in parallel with the scanning lines are used as light emitting areas, and the light emitting areas are subjected to signal scanning on the scanning lines within one frame. It was a method of controlling to turn on sequentially. That is, conventionally, the lighting of the backlight is controlled so as to sequentially illuminate a predetermined number of scanning lines as a whole screen. However, among the plurality of scanning lines illuminated by the respective light emitting regions, the first and the last are scanned. The scanning time difference that occurs with respect to the scanned display pixels was not taken into account. In particular, the shorter the lighting time of the backlight in order to improve so-called “moving image blur”, the closer to impulsive lighting, the more noticeable the problem that the difference in video due to the above time difference becomes easier to visually recognize. .

  Accordingly, since each display pixel having such a time difference is illuminated at the same timing, it is preferable for the time difference due to scanning between a plurality of display pixels that are collectively illuminated by the backlight. The illumination of the backlight source could not be controlled.

  Therefore, in order to solve the above-described problems, the present invention can suitably control the illumination of the backlight light source with respect to the time difference due to scanning between a plurality of display pixels that are collectively illuminated by the backlight. It is an object to provide a display device and a video display method.

  In order to solve the above-described problems, the present invention adjusts the lighting means for illuminating a light-transmissive image display panel for displaying an image by lighting the backlight, and the lighting amount of the backlight illuminated by the illuminating means. And setting means for setting the control information expressed by changing the time or level of the pulse width of the control information in accordance with the lighting amount, and the setting means includes the lighting information. When the amount is equal to or less than a predetermined amount, the control information that maintains the time of the pulse width when the lighting amount is the predetermined amount is set.

  Further, in order to solve the above-described problems, the present invention provides control information for illuminating a light-transmissive image display panel that displays an image by turning on a backlight and adjusting a lighting amount of the illuminating backlight. Setting the control information expressed by changing the time or level of the pulse width of the control information according to the lighting amount, and when the lighting amount is a predetermined amount or less, the lighting amount is The control information that maintains the time of the pulse width at a predetermined amount is set.

  ADVANTAGE OF THE INVENTION According to this invention, the illumination of a backlight light source can be controlled suitably with respect to the time difference by the scanning between the some display pixels illuminated collectively with a backlight.

The block diagram which shows the structure of the television receiver which is a video display apparatus which concerns on embodiment of this invention. The block diagram which shows the system configuration | structure by each block which performs the process which controls a backlight based on the input video signal. The flowchart for demonstrating the operation | movement of the process which controls lighting or light extinction of a backlight by the backlight control information according to the lighting value of a backlight. The conceptual diagram for demonstrating the operation | movement which controls sequentially lighting or light extinction of a backlight according to the scanning of the video signal to the liquid crystal panel in the display which concerns on this embodiment. The conceptual diagram of the response characteristic of the liquid crystal in the specific display pixel of a liquid crystal panel. 5 is a conceptual diagram for explaining a specific example of sequential control of lighting of the backlight shown in FIG. 4 and a state in which a time difference is caused by scanning between specific display pixels in a specific region of the liquid crystal panel. FIG. The figure which shows the specific example of the backlight control information which a backlight control part outputs. The conceptual diagram for demonstrating the state in which the backlight control information of a single pulse or several pulses within predetermined time is output in the state with the time difference by the scanning which concerns on the response of the liquid crystal of a specific display pixel. The conceptual diagram of the aspect of the backlight control information according to the value of the lighting value information regarding the lighting amount of the backlight.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of a television receiver 10 which is a video display device according to an embodiment of the present invention. In the present embodiment, a television receiver is taken as an example of a video display device to which the configuration according to the present invention is applied. However, a video monitor, a personal computer, and a portable mobile phone having the same structure as the present embodiment. A form such as a terminal may be used.

  The television receiver 10 according to this embodiment includes a broadcast wave processing unit 20, an external device IF unit 31, a signal processing control unit 40, an operation unit 51, a light receiving unit 52, a display 61, a speaker 62, and the like. . The display 61 is composed of a liquid crystal panel 101, a backlight 102, and the like.

  The television receiver 10 acquires video data from the broadcast wave processing unit 20, the external device IF unit 31, etc., performs predetermined processing on the acquired video data, and outputs it to the liquid crystal panel 101 of the display 61. It controls lighting of the light 102.

  The broadcast wave processing unit 20 acquires a digital broadcast wave or analog broadcast wave signal received by the antenna AT, performs channel selection and demodulation / decoding processing on a specific channel for the acquired signal, and performs video and audio of the program. Data and data for creating an electronic program guide (hereinafter also referred to as EPG) are output to the signal processing control unit 40.

  The external device IF unit 31 is connected to a device external to the device through a connection unit conforming to various standards such as the USB standard and the IEEE 1394 standard, and creates video / audio data and EPG of content provided from the connected external device. For example, data is acquired and output to the signal processing control unit 40. The external device IF unit 31 is connected to a recording medium such as an external HDD or a memory card through a connection unit conforming to the USB standard, the IEEE 1394 standard, etc., and video / audio data of content is connected to the connected recording medium. Is output or input.

  The operation unit 51 receives operation input information for operating the apparatus and outputs the information to the signal processing control unit 40. Similarly, the light receiving unit 52 receives (receives) operation input information from the remote controller RC and outputs the received information to the signal processing control unit 40.

  Based on the operation input information from the operation unit 51 and the light receiving unit 52, the signal processing control unit 40 applies MPEG code to video / audio data input from the broadcast wave processing unit 20, the external device IF unit 31, and the like. The video signal is output to the display 61 by performing various processes such as a decoding / decoding calculation process, a video signal / audio signal separation process, a specific data extraction process from input data, or a decompression process of compressed data Then, an audio signal is output to the speaker 62. The signal processing control unit 40 includes a CPU, and controls the execution of a plurality of processes using each module provided in the signal processing control unit 40 itself and each module connected to the signal processing control unit 40 itself. To do.

  In the present embodiment, the signal processing control unit 40 detects the characteristics of the input video signal, performs predetermined processing on the input video signal based on the detected characteristics, and is provided in the display 61. Output to panel 101. Further, the signal processing control unit 40 controls lighting of the backlight 102 provided in the display 61 based on the characteristics of the input video signal.

  The display 61 is a display module that displays a video signal input from the signal processing control unit 40, and is a thin display such as an LCD (Liquid Crystal Display). The display 61 displays the video signal input from the signal processing control unit 40 on the liquid crystal panel 101, which is a light transmission type video display panel for displaying video, and the control signal from the signal processing control unit 40. In response to this, the illumination of the backlight 102 is turned on or off. In the following description, a liquid crystal display is applied as an example of the display 61, but the present invention is not limited to this.

The liquid crystal panel 101 is a video display panel in which a plurality of display pixels that display video signals input from the signal processing control unit 40 are arranged in a predetermined number of matrixes.
The backlight 102 is a light source for illuminating the liquid crystal panel 101 from the back surface of the liquid crystal panel 101, and includes a direct cold cathode tube, a direct or side illumination LED, an EL (Electro-Luminescence), and the like. The light source used. In the present embodiment, the backlight 102 is an LED light source using a direct type or a side irradiation type, and is turned on or off according to control information from the signal processing control unit 40.

The speaker 62 outputs the audio signal input from the signal processing control unit 40.
With such a configuration, the television receiver 10 according to the embodiment of the present invention controls the backlight 102 for the display 61 based on the characteristics of the input video signal, and performs predetermined processing. Output video signal. These processes are mainly executed by the signal processing control unit 40 controlling the backlight 102 provided in the display unit 61.

  Next, with reference to FIG. 2, each block that is provided in the signal processing control unit 40 and the display 61 described in FIG. 1 and that performs processing for controlling the backlight 102 based on the input video signal will be described. .

FIG. 2 is a block diagram showing a system configuration of each block that executes processing for controlling the backlight 102 based on the input video signal.
The signal processing control unit 40 includes a video feature information detection unit 201, a lighting value setting unit 202, a lighting value level detection unit 203, a backlight control unit 204, a correction coefficient calculation unit 205, a video signal delay unit 211, and a video signal correction unit 212. It has.

  The video feature information detection unit 201 divides the input video signal into a plurality of regions in a predetermined signal unit (for example, a predetermined number of scanning lines), and the average luminance or maximum of the video signal for each of the divided regions. Video feature information that is a feature value of a video signal based on luminance, minimum luminance, and the like is detected. Then, the video feature information detection unit 201 outputs the detected video feature information for each area to the lighting value setting unit 202. The video feature information detection unit 201 is not an embodiment in which the video feature information is detected after the input video signal is divided into a plurality of areas, but the video signal that has been divided into a plurality of areas in advance is input. In this embodiment, the video feature information may be detected.

  The lighting value setting unit 202 is information for lighting the backlight 102 with a predetermined lighting amount for each region based on the video feature information for each of the plurality of regions input from the video feature information detection unit 201. Determine lighting value information. Then, the lighting value setting unit 202 outputs the determined lighting value information to the lighting value level detection unit 203, the backlight control unit 204, and the correction coefficient calculation unit 205.

  The lighting value level detection unit 203 compares the lighting value information input from the lighting value setting unit 202 with a predetermined value stored in advance in a storage unit (not shown) such as a RAM, and based on the determination result. The level detection information that is the detected information is output to the backlight control unit 204. For example, when the level detection information is defined as binary information, if the lighting value information is greater than a predetermined value, the level detection information is output as “0”, and if the lighting value information is less than the predetermined value, the level detection information The detection information is output as “1”. The form of the level detection information is not limited to such a form as binary information.

  The backlight control unit 204 controls the backlight 102 to light the backlight 102 based on the lighting value information input from the lighting value setting unit 202 and the level detection information input from the lighting value level detection unit 203. Information is output to the backlight 102. Note that the backlight control unit 204 switches and outputs backlight control information in various modes such as a single pulse, a plurality of pulses with a predetermined period, a pulse output within a predetermined time, and the like according to the level detection information.

  The correction coefficient calculation unit 205 calculates video signal correction information for correcting the video signal based on the lighting value information input from the lighting value setting unit 202, and uses the calculated video signal correction information as the video signal correction unit. To 212. For example, when the lighting value information is information based on the luminance of a specific area of the video signal, the video signal correction information is obtained by correcting the parameter for setting the orientation of each liquid crystal element of the liquid crystal panel 101. This is information for correcting the brightness by itself. More specifically, the correction coefficient calculation unit 205 outputs information for correcting the luminance of the video signal itself in accordance with the luminance change of the backlight 102 according to the information output from the lighting value setting unit 202. As described above, by correcting the luminance of the video signal itself, it is possible to display the correct video as the entire display together with the luminance of the backlight 102.

  The video signal delay unit 211 outputs the input video signal to the video signal correction unit 212 after a predetermined delay time previously stored in a storage unit (not shown) such as a RAM. In the embodiment, the predetermined delay time that the video signal delay unit 211 delays the video signal is information stored in advance in a storage unit (not shown) such as a RAM, but the lighting value setting unit 202 is turned on. An embodiment in which the video signal delay unit 211 detects that the value information is output or the backlight control unit 204 outputs a backlight control signal and the like, and the video signal is output may be possible. The video signal delay unit 211 may be appropriately provided as necessary, and is not an essential component in the present invention.

  The video signal correction unit 212 performs a predetermined correction on the video signal input from the video signal delay unit 211 based on the video signal correction information output from the correction coefficient calculation unit 205, and the corrected video signal Is output to the liquid crystal panel 101.

With such a system configuration, the signal processing control unit 40 according to the embodiment of the present invention executes processing for controlling the backlight 102 based on the input video signal.
Next, referring to FIG. 3, the operation of the process for controlling the lighting or extinguishing of the backlight 102 by the backlight control information corresponding to the lighting value of the backlight 102 executed by each block described in FIG. 2 is performed. explain.

  FIG. 3 is a flowchart for explaining the operation of the process for controlling the lighting or extinguishing of the backlight 102 based on the backlight control information corresponding to the lighting value of the backlight 102.

  First, the video feature information detection unit 201 divides an input video signal into a plurality of regions in predetermined signal units, detects video feature information based on the divided video signal, and detects the detected video feature information. Is output to the lighting value setting unit 202 (S301). Next, the lighting value setting unit 202 determines lighting value information based on the video feature information for each region input from the video feature information detection unit 201, and uses the determined lighting value information as the lighting value level detection unit. 203, the backlight control unit 204, and the correction coefficient calculation unit 205 (S302). Then, the lighting value level detection unit 203 determines whether or not the lighting value information input from the lighting value setting unit 202 is a predetermined value or less, and outputs the level detection information to the backlight control unit 204. (S303).

  As a result of this determination, if the input lighting value information is equal to or less than the predetermined value (Yes in S303), the backlight control unit 204 performs predetermined processing based on the level detection information input from the lighting value level detection unit 203. The backlight control information based on the pulse within the time is output to the backlight 102, and the backlight 102 is turned on or off by the backlight control information input from the backlight control unit 204 (S304). Further, the video signal correction unit 212 outputs to the liquid crystal panel 101 a video signal obtained by correcting the video signal input from the video signal delay unit 211 based on the video signal correction information output from the correction coefficient calculation unit 205. (S305).

  On the other hand, as a result of determining whether or not the input lighting value information is equal to or less than the predetermined value, if the input lighting value information is not equal to or less than the predetermined value (No in S303), the backlight control unit 204 displays the lighting value level. Based on the level detection information input from the detection unit 203, backlight control information based on a single pulse or a plurality of pulses having a predetermined cycle is output to the backlight 102. The backlight 102 is input from the backlight control unit 204. It is turned on or off according to the backlight control information (S306). Further, the video signal correction unit 212 outputs to the liquid crystal panel 101 a video signal obtained by correcting the video signal input from the video signal delay unit 211 based on the video signal correction information output from the correction coefficient calculation unit 205. (S305).

  That is, the process of controlling the lighting or extinguishing of the backlight 102 by the backlight control information corresponding to the lighting value of the backlight 102 by such an operation is executed by each block described in FIG.

  Next, with reference to FIG. 4, an operation of sequentially controlling turning on / off of the backlight 102 in accordance with the scanning of the video signal to the liquid crystal panel 101 in the display 61 according to the present embodiment will be described.

  FIG. 4 is a conceptual diagram for explaining an operation of sequentially controlling turning on / off of the backlight 102 in accordance with the scanning of the video signal to the liquid crystal panel 101 in the display device 61 according to the present embodiment.

  The video signal is output to the liquid crystal panel 101 by scanning the video signal from the upper part to the lower part of the screen along a predetermined number of scanning lines arranged substantially parallel to the horizontal direction. Hereinafter, a specific example of turning on / off the backlight 102 in accordance with the output of such a specific video signal will be described.

  In FIG. 4, the left diagram to which the symbol (V *) is attached shows the scanning state of the video signal to the liquid crystal panel 101, and the right diagram to which the symbol (L *) is attached is The backlight 102 is turned on or off. Further, since the backlight 102 is divided into six regions Zn1 to Zn6 that are substantially parallel to the scanning line, each of these regions can be controlled to be turned on or off individually.

  Each of the regions Zn1 to Zn6 is turned on by turning on an LED light source arranged to illuminate the liquid crystal panel 101 in a vertical direction and illuminate each region divided substantially in parallel with the scanning line. That is, in the control of turning on or off the backlight 102 of the display device 61 according to this embodiment, so-called “area control” is possible.

  First, FIG. 4 (Va) shows a state where no video signal is output to the liquid crystal panel 101, and FIG. 4 (La) shows a state where the backlight 102 is not lit. Then, when scanning of the video signal from the upper part of the liquid crystal panel 101 is started, the region Zn1 above the backlight 102 is controlled to be lit as shown by the shaded portion in FIG. 4 (Lb). Thereafter, as shown by the shaded portion in FIG. 4 (Vb), when scanning of the video signal is completed with respect to a predetermined amount (predetermined number) from the upper part of the liquid crystal panel 101, next, the region Zn2 of the backlight 102 is obtained. Is controlled to light up.

  Further, the respective regions Zn3, Zn4, and Zn5 of the backlight 102 are controlled to light up in accordance with the scanning of the video signal on the liquid crystal panel 101. Then, as shown in FIG. 4 (Lc), control is performed so that the region Zn5 of the backlight 102 is turned on, and an image from the upper part of the liquid crystal panel 101 to a specific region as shown in FIG. 4 (Vc). The signal scanning is completed. Further, the region Zn6 of the backlight 102 shown in FIG. 4 (Ld) is controlled to be turned on, and the scanning of the entire screen of the liquid crystal panel 101 shown in FIG. 4 (Vd) is completed.

In this way, the display 61 according to the present embodiment sequentially controls lighting of the backlight 102 in accordance with the scanning of the video signal to the liquid crystal panel 101.
Next, the response characteristics of the liquid crystal in a specific display pixel of the liquid crystal panel 101 with respect to the input video signal will be described with reference to FIG.
FIG. 5 is a conceptual diagram of liquid crystal response characteristics in a specific display pixel of the liquid crystal panel 101.
As shown in the conceptual diagram of FIG. 5, when a predetermined video signal is output as a control signal to a specific display pixel of the liquid crystal panel 101 over time, the liquid crystal of the display pixel rises and falls. Responsive to the control signal with a transient response Therefore, when the backlight 102 is lit during the rising or falling transient response period in this way, an erroneous video corresponding to the transient response characteristic is output from the display unit 61.

  In other words, in order to output a normal video based on the control signal, it is necessary to control the backlight 102 to be lit at a timing excluding the liquid crystal transient response period.

  Next, a specific example of sequential control of lighting of the backlight 102 illustrated in FIG. 4 and a state in which a time difference due to scanning between specific display pixels in a specific region of the liquid crystal panel 101 will be described with reference to FIG. .

  FIG. 6 is a conceptual diagram for explaining a specific example of sequential control of lighting of the backlight 102 shown in FIG. 4 and a state in which a time difference is caused by scanning between specific display pixels in a specific region of the liquid crystal panel 101. is there.

  For example, in order to display a high-definition video signal on the liquid crystal panel 101, the total number of scanning lines is 1125 and the number of effective scanning lines is 1080. Therefore, in the following, an embodiment in which the number of scanning lines of the liquid crystal panel 101 in this embodiment is 1080 and lighting of the backlight 102 is controlled by being divided into six regions Zn1 to Zn6 will be described.

In the present embodiment, the scanning of the video signal to the liquid crystal panel 101 is sequentially performed one by one downward from the first scanning line at the top of the liquid crystal panel 101.
As shown in FIG. 6A, when each of the six regions Zn1 to Zn6 of the backlight 102 is divided substantially evenly, the number of scanning lines of the liquid crystal panel 101 corresponding to each region is 1080 / 6 = 180. For example, the area Zn1 above the backlight 102 corresponds to the first to 180 lines above the scanning lines of the liquid crystal panel 101. That is, it is possible to illuminate 180 lines above the scanning lines of the liquid crystal panel 101 by the light source arranged in the region Zn1 of the backlight 102. Similarly, the area of the backlight 102 after the area Zn2 is also illuminated by approximately 180 scanning lines of the liquid crystal panel 101 one by one.

  However, as shown in FIG. 6B, the liquid crystal response of the display pixel that is scanned first among the first scanning lines (line 1) at the top of the liquid crystal panel 101, and the 180th line from the top of the liquid crystal panel 101. A time difference Tdly due to scanning occurs with respect to the response of the liquid crystal of the display pixel scanned last among the scanning lines (line 180). Therefore, in the plurality of display pixels in the specific video region, the response of the liquid crystal excluding the transient response period of the specific display pixel and the transient response period of other display pixels different from the specific display pixel. The period during which is stable may be limited.

  That is, when there are a plurality of scanning lines in the area of the liquid crystal panel 101 corresponding to the specific light source area of the backlight 102, a time difference due to scanning of the video signal occurs between specific display pixels in this area. Therefore, it is important to control the illumination of the backlight 102 in consideration of this time difference.

Next, a specific example of the backlight control information output from the backlight control unit 204 will be described with reference to FIG.
FIG. 7 is a diagram illustrating a specific example of backlight control information output from the backlight control unit 204.
Specifically, the backlight control unit 204 outputs backlight control information based on one or a plurality of pulse waves having variable levels to the backlight 102.
That is, as described above, when the lighting value information regarding the lighting amount of the backlight 102 input from the lighting value setting unit 202 is not less than or equal to a predetermined value, the backlight control unit 204 displays the information shown in FIG. Single-pulse backlight control information as shown in FIG. 7 or multiple-pulse backlight control information with a predetermined cycle Tcl as shown in FIG. 7B is output.

  In the single-pulse backlight control information as shown in FIG. 7A, the brightness of lighting by the backlight 102 changes in accordance with the pulse width (time) of the backlight control information. Specifically, according to the single-pulse backlight control information, the brightness of the lighting of the backlight 102 is darker when the pulse width (time) of the backlight control information is shorter, and the pulse width (time) is longer. It will light up brightly. Further, the brightness of lighting by the backlight 102 may be changed by changing the level of the backlight control information.

  In the backlight control information of a plurality of pulses having a predetermined cycle Tcl as shown in FIG. 7B, the lighting by the backlight 102 is changed according to the pulse width (time) of each pulse of the backlight control information. The brightness changes. Moreover, even if each pulse width (time) of this backlight control information is constant, the brightness of lighting by the backlight 102 changes according to the number of pulses. Further, the brightness of lighting by the backlight 102 may be changed by changing the level of the backlight control information.

  In addition, it is preferable that the backlight control information of a plurality of pulses having a predetermined period is applied to relatively bright lighting with respect to the single-pulse backlight control information, but is not particularly limited.

  On the other hand, when the lighting value information input from the lighting value setting unit 202 is equal to or less than the predetermined value, the backlight control unit 204 performs backlight control of a plurality of pulses within a predetermined time as shown in FIG. Information or single-pulse backlight control information within a predetermined time with the level changed as shown in FIG. 7D is output.

  In the backlight control information of a plurality of pulses within a predetermined time as shown in FIG. 7C, the lighting of the backlight 102 is changed according to the pulse width (time) of each pulse of the backlight control information. The brightness changes. Moreover, even if each pulse width (time) of this backlight control information is constant, the brightness of lighting by the backlight 102 changes according to the number of pulses.

  That is, with respect to the backlight control information of a plurality of pulses within a predetermined time, the backlight 102 is lit darkly when the pulse width (time) of the backlight control information is shortened or the number of pulses is reduced. If each pulse width (time) becomes longer or the number of pulses increases, it lights up brightly.

Further, the brightness of lighting by the backlight 102 may be changed by changing the level of the backlight control information.
The predetermined time Ttm from the leading edge of the plurality of pulses of the backlight control information to the trailing edge of the final pulse is not dependent on the pulse width (time) or the number of pulses. It is controlled to become. Accordingly, the backlight control information of a plurality of pulses within a predetermined time as shown in FIG. 7C does not become a time longer than the predetermined time Ttm, so that the lighting of the backlight 102 is controlled at a predetermined brightness or less. It will be.

  Further, when the lighting value information becomes smaller than the predetermined value, the control is performed so that each pulse width (time) of the backlight control information is further shortened or the number of pulses is decreased while the predetermined time Ttm is maintained. The

  In addition, in the single-pulse backlight control information within a predetermined time with the level changed as shown in FIG. 7D, the backlight is changed according to the pulse level and pulse width (time) of the backlight control information. The brightness of lighting by 102 changes.

  That is, the backlight 102 is lit darker when the level of the backlight control information becomes smaller or the pulse width (time) becomes shorter with respect to the single-pulse backlight control information within a predetermined time when the level is changed. Lights up brightly when the pulse width increases or the pulse width (time) increases.

  If the lighting value information is further smaller than the predetermined value, the level of the backlight control information is reduced. However, the predetermined time Ttm from the rise to the fall of this pulse is controlled to be the predetermined time.

  Further, since the backlight control information of the pulses within the predetermined time shown in FIGS. 7C and 7D is controlled so that the pulses are within the predetermined time Ttm, the predetermined period shown in FIG. Compared with the multiple-pulse backlight control information, the period during which the backlight 102 is continuously turned off can be lengthened, and is equivalent to a technique for reducing the afterimage feeling of a video by inserting a black video into the output video. An effect can be obtained.

  In addition, in the backlight control information of pulses within a predetermined time, a certain period during which pulses other than the predetermined time Ttm are not output is ensured, and the constant period during which this pulse is not output is made to correspond to the transient response period of the liquid crystal, It is possible to control so that the backlight 102 is turned on at a timing excluding the transient response period of the liquid crystal.

  The predetermined time Ttm shown in FIGS. 7C and 7D is the pulse width (time) corresponding to the predetermined value of the lighting value information in the pulse width (time) of the single pulse shown in FIG. ).

The predetermined value to be compared with the input lighting value information is determined according to the divided quantity obtained by dividing the backlight 102 into a plurality of areas in the vertical direction.
Further, the number of pulses of the backlight control information of a plurality of pulses having a predetermined period or a plurality of pulses within a predetermined time is not limited to four in the present embodiment.
That is, when the lighting value information regarding the lighting amount of the backlight 102 is equal to or less than a predetermined value, each of the backlight control information of a plurality of pulses within the predetermined time is maintained while maintaining the pulse width (time) corresponding to the predetermined value. The brightness of lighting by the backlight 102 is changed by changing the pulse width (time) or changing the level in the single-pulse backlight control information within a predetermined time when the level is changed.

  Next, with reference to FIG. 8, in a state where there is a time difference due to scanning related to the liquid crystal response of the display pixel between specific display pixels of the liquid crystal panel 101, the single pulse or the predetermined time shown in FIG. A state in which backlight control information of a plurality of pulses is output will be described.

  FIG. 8 is a concept for explaining a state in which backlight control information of a single pulse or a plurality of pulses within a predetermined time is output in a state where there is a time difference due to scanning related to the liquid crystal response of a specific display pixel. FIG.

  In the following, the state in which the single-pulse backlight control information shown in FIG. 7A corresponding to lighting value information equal to or less than a predetermined value is output, and the predetermined time shown in FIG. Two examples of a state in which backlight control information of a plurality of pulses is output will be described.

Note that the backlight control information of a plurality of pulses having a predetermined period shown in FIG. 7B is applied to relatively bright lighting, and thus the description thereof is omitted here.
As shown in FIG. 8A, in a state where there is a time difference due to scanning between specific display pixels, a single pulse having a short width (time) corresponding to lighting value information equal to or less than a predetermined value is received from the backlight control unit 204. When the backlight control information is output, a timing at which the illumination of the backlight 102 with respect to a specific display pixel is not appropriate occurs. Specifically, in the conceptual diagram shown in FIG. 8A, since the illumination for the display pixel of line 1 is in the transient response period of the liquid crystal, the illumination 801 (ineffective for the display pixel of line 1) (Hatched area) has occurred.

  On the other hand, as shown in FIG. 8B, even when there is a time difference due to scanning between specific display pixels, the backlight control unit 204 outputs a plurality of pulses of backlight control information within a predetermined time. Timing occurs when the illumination of the backlight 102 with respect to a specific display pixel becomes inappropriate. Specifically, in the conceptual diagram shown in FIG. 8B, illuminations 802 and 803 (shaded portions) that are invalid with respect to the display pixel of the line 1 are generated, but are invalid in FIG. 8A. The amount of illumination during the transient response period of the liquid crystal is smaller than the illumination 801 (hatched portion), and is not biased to either the first or last line of scanning.

That is, it is preferable that the backlight control information is output at a timing suitable for scanning that is approximately in the middle of the time difference.
Specifically, a single pulse backlight control is performed before a point RP (arrow part) at which the control signal switches in line 90 (or line 91), which is substantially between line 1 and line 180, as a reference point. This is the timing at which information is output.

  For example, if a specific video pixel by the first scan in a specific area is used as a reference point, the timing to the characteristics of the specific pixel in the last scan does not match, and the liquid crystal transient response period of the last scanned video pixel The possibility that the backlight 102 is turned on increases. Conversely, the same applies to a case where a specific video pixel obtained by the last scan in a specific region is used as a reference point.

That is, there is a possibility that the quality of the image of a specific image pixel due to the first or last scan in a specific region is undesirably deteriorated.
In addition, the transition point of each liquid crystal rises with respect to the display pixels in the subsequent scans at the timing when the pulse ends at the reference point when the control signal is switched at the first scan in a specific region. The backlight control information is output during the period. Conversely, the point at which the response of the liquid crystal in the specific region starts to stabilize is set as the reference point, and at the timing when the pulse starts at this reference point, the display pixels from the previous scan are displayed for each pixel. Backlight control information is output during the transient response period of the fall of the liquid crystal.

It is well known that the characteristics of the transient response of the liquid crystal rise and fall vary with the ambient temperature.
That is, considering various points such as the relationship between the time at which a control signal indicating a specific value is output and the time difference due to scanning in a specific region, and the response characteristics of the liquid crystal in which the transient response period changes with temperature, It is inevitable that the output timing of the backlight control information is matched to the scanning that is approximately in the middle of the time difference.

  FIG. 8B illustrates the relationship between the response of the liquid crystal due to an operation on a specific display pixel and the backlight control information of a plurality of pulses output within a predetermined time. It goes without saying that the same can be explained not by the backlight control information of FIG. 7 but also by the single-pulse backlight control information within a predetermined time with the level changed as shown in FIG.

  In other words, in order to turn on the backlight 102 smaller than a predetermined lighting value (darker than a predetermined brightness), it is possible to reduce the amount of invalid lighting by controlling with the backlight control information of pulses within a predetermined time. . In other words, by providing a predetermined lighting time for the lighting of the backlight 102, it is possible to reduce the difference from the video to be displayed even in the video display at the line position where the lighting timing is shifted. It is.

Next, the aspect of the backlight control information according to the value of the lighting value information regarding the lighting amount of the backlight 102 will be described with reference to FIG.
FIG. 9 is a conceptual diagram of an aspect of backlight control information according to the value of lighting value information regarding the lighting amount of the backlight 102.
That is, as the lighting value information is changed from a large value to a small value, the single-pulse backlight control information shown in FIG. 7A is applied, and the pulse width (time) of the backlight control information is reduced. Specifically, according to the value of the lighting value information, the pulse width of the backlight control information becomes small as shown in FIGS. 9A to 9B.

  Then, when the lighting value information is equal to or less than a predetermined value for switching the backlight control information, the backlight control information of a plurality of pulses within a predetermined time shown in FIG. 7C, or shown in FIG. Switching to single-pulse backlight control information within a predetermined time when the level is changed.

  In the backlight control information of a plurality of pulses within a predetermined time shown in FIG. 7C, when the lighting value information becomes a smaller value, each of the plurality of pulses within the predetermined time is maintained while the predetermined time is maintained. The pulse width (time) is further reduced.

  In the single-pulse backlight control information within a predetermined time with the level changed as shown in FIG. 7D, when the lighting value information becomes a smaller value, the level is further reduced while maintaining the predetermined time.

  Specifically, when the lighting value information is a predetermined value for switching the backlight control information, the backlight control information shown in FIG. 9C1 or FIG. 9C2 is obtained. When the lighting value information is further reduced, the backlight control information shown in FIG. 9 (d1) or FIG. 9 (d2) is changed.

  As described above, according to the present embodiment, the lighting value of the backlight 102 is less than or equal to the predetermined value in the process of controlling lighting or extinguishing of the predetermined area of the backlight 102 based on the input video signal. In the case of (becomes darker than the predetermined brightness), the backlight control information by pulses within a predetermined time is output, so that the time difference due to scanning between a plurality of display pixels illuminated collectively by the backlight 102 is reduced. The illumination of the backlight light source can be preferably controlled.

  The present invention is not limited to the above-described embodiments, and various changes and modifications can be made without departing from the scope of the present invention.

  DESCRIPTION OF SYMBOLS 10 ... Television receiver, 20 ... Broadcast wave process part, 31 ... External apparatus IF part, 40 ... Signal processing control part, 51 ... Operation part, 52 ... Light-receiving part, 61 ... Display, 62 ... Speaker, 101 ... Liquid crystal Panel, 102 ... Backlight, 201 ... Video feature information detection unit, 202 ... Lighting value setting unit, 203 ... Lighting value level detection unit, 204 ... Backlight control unit, 205 ... Correction coefficient calculation unit, 211 ... Video signal delay unit 212, video signal correction units.

Claims (8)

Illumination means for illuminating a light transmissive image display panel for displaying an image by turning on a backlight;
Control information for adjusting the lighting amount of the backlight illuminated by the illumination means, the control information expressed by changing the time or level of the pulse width of the control information according to the lighting amount. Setting means for setting,
The video display apparatus, wherein the setting means sets the control information that maintains the time of the pulse width when the lighting amount is the predetermined amount when the lighting amount is a predetermined amount or less.   The setting means serves as a reference for maintaining the pulse width time for the control information including a single pulse wave corresponding to the lighting amount or a plurality of pulse waves having a predetermined period corresponding to the lighting amount. The video display device according to claim 1, wherein the control information is set by switching to the control information before the timing at which the video signal related to the display pixel is switched.   3. The video display device according to claim 2, wherein the setting unit sets the lighting amount in accordance with information relating to luminance of a specific area of a video signal displayed on the video display panel.   3. The video display apparatus according to claim 2, wherein the setting means sets the control information at a timing that reduces a lighting amount to illuminate during a transient response period of the video display panel.   The setting means includes a plurality of light emitting areas associated with the plurality of light emitting areas that are individually illuminated to divide the video display panel in the vertical direction. The video display device according to claim 2, wherein the control information for adjusting a lighting amount is set.   6. The video display apparatus according to claim 5, wherein the predetermined amount is determined according to a quantity of a plurality of areas formed by dividing the video display panel.   The video display device according to claim 2, wherein the video display panel is a liquid crystal panel. Illuminates a light-transmissive image display panel that displays images by turning on the backlight,
Control information for adjusting the lighting amount of the backlight to illuminate, and setting the control information expressed by changing the time or level of the pulse width of the control information according to the lighting amount,
Furthermore, when the lighting amount is equal to or less than a predetermined amount, the control information that maintains the pulse width time when the lighting amount is the predetermined amount is set.

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