JP2014089279A - Video display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve a problem of a conventional graphic display device, in that a lower refresh rate results in a flickering screen whereas a higher refresh rate results in a less-flickering screen, an area with a longer light non-emission time in gradation expression divided into the light emission time of a light emitting display element and the light non-emission time of the light emitting display element results in the portion showing a flickering video, and, in particular, a lower gradation display prolongs continuous light non-emission time, making flicker of a video conspicuous.SOLUTION: In a video display device according to the invention, in order to shorten a continuous light non-emission time, a sub-frame is divided within one frame period composed of a plurality of sub-frames, thereby shortening a continuous light non-emission time. Additionally, when one sub-frame is divided, sub-sub-frames, which are sub-frames of each sub-frame, are arranged so that light non-emission times do not gather in one place, taking account of the light emission time and light non-emission time of a sub-sub-frame, which is a sub-frame of each sub-frame.

Description

  The present invention relates to a video display device in which light-emitting display elements such as LEDs and fluorescent display tubes are arranged as pixels to form a screen, and a control method thereof, in particular, by reducing the continuous non-emission time of video display control. It reduces flicker and makes it easier to see the video.

In a conventional video display device, a method of controlling gradation by controlling a light emission time of a display element is adopted for a display element in which light emitting display elements are arranged in a matrix. In this case, one frame is divided into a number of subframes and sub-subframes that are subframes to express gradation. In each sub-subframe period, gray levels are expressed in one frame period by dividing the light-emitting display element into the light emission time and the non-light emission time according to the lighting data.
In the conventional lighting control method, lighting data for one subframe of the display area is periodically written in the memory and displayed. That is, refresh is performed every subframe.

Japanese Patent No. 348984 (FIG. 1) JP 2010-54989 A (FIG. 12)

  In the conventional video apparatus, when the refresh rate (the number of times the screen is rewritten per unit time) is low, the screen appears to flicker. Conversely, when the refresh rate is high, the flicker is reduced. Further, when the non-light emitting time region is long in the gradation expression divided into the light emitting time and the non-light emitting time of the light emitting display element, the portion appears to flicker. In particular, in the case of low gradation display, there is a problem that the continuous non-light emission time becomes long and the flicker of the image becomes conspicuous.

  The present invention has been made to solve the above-mentioned problems, and by reducing the continuous non-light emission time, it is possible to reduce the flicker of the video and to display an image that is easy to view and excellent in re-shooting. An object of the present invention is to provide a video display device and a control method thereof.

The video display device according to the present invention is arranged so that light emitting display elements serving as pixels constitute a screen, and the light emitting display elements are subjected to time division light emission to control gradation and refresh the screen.
Dividing one frame of the screen into a plurality of sub-frames, dividing the lighting data for determining the light-emission time of the light-emitting display element to control gradation of the sub-frame, and distributing the light-emission time in the sub-frame Then, gradation control for assigning the lighting data to each pixel of the sub-frame is performed.

  According to the present invention, by reducing the continuous non-light emission time, the flickering of the screen can be reduced and a more easily viewable image can be displayed. In addition, the displayed video can be taken more beautifully with a photo or video camera.

1 is a configuration diagram of a video display apparatus according to Embodiment 1 of the present invention. It is an example of a structure of the display element driver which concerns on Embodiment 1 of this invention. It is a block diagram of the scan control which concerns on Embodiment 1 of this invention. It is a figure which shows an example of the conventional gradation control. It is an example of the gradation control which concerns on Embodiment 1 of this invention. It is an example of the gradation control by Embodiment 2 of this invention. It is a figure which shows an example of the conventional gradation expression. It is a figure which shows the gradation expression by Embodiment 3 of this invention. It is a figure which shows the gradation expression by Embodiment 4 of this invention.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram showing a display unit of a video display apparatus according to Embodiment 1 of the present invention. The video display apparatus 1 is configured by arranging and connecting display panels 2 in a matrix form. Constitutes a display surface of the video display device by arranging and connecting a plurality of light emitting display elements 3 in a matrix.
The display panel 2 is provided with a plurality of display element drivers 4 for each light emitting display element 3 that take in pixel data from video data and form a drive signal for the light emitting display element. FIG. 2 shows an example of a driver IC which is a specific example of the display element driver 4.

  In FIG. 2, a shift register 01 stores pixel data input as serial data for one horizontal line (1H), and a latch circuit 02 performs serial / parallel conversion on the pixel data captured in the shift register 01 for one horizontal period. For a predetermined time. All constant current outputs are controlled by ON / OFF control of the data being latched. The 16-channel constant current sink driver 03 controls the output current (light emission pulse of the light emitting display element) by generating a reference current with an external resistor and amplifying the reference current.

  In the video display device according to the present invention, scan control is used to reduce power consumption and the number of parts. Scan control refers to control in which a plurality of light-emitting elements are connected to one output of a driver IC, and light-emitting elements that are turned on by a switch element are switched on and off. For example, in the case of four scans as shown in FIG. 3, four LED elements are connected to the cathode side for one output of the driver IC, and four LED elements are connected by the switch element connected to the anode side when the driver IC is driven. On / off control of the LED drive current (scan signal) is performed to selectively control lighting and extinguishing of the four LED elements.

  In the gradation control using the time-division light emitting method for controlling the gradation by controlling the light emission time of the light emitting display element as in the present invention, the gradation is displayed by dividing one frame into a number of subframes. In gradation control using such a time-division light emission method, the light emitting display element is divided into a light emission time and a non-light emission time according to a digital data signal during each period of each subframe, and within one frame period. Express gradation.

In the conventional time-division light emitting method shown in FIG. 4, each frame is represented by a number of subframes (symbol SF in the figure) corresponding to each bit of the digital data signal in order to express the gradation of the digital signal. ).
At this time, as shown in FIG. 4, the gradation expressed in one frame is the sum of the subframes, and the gradation when 4 bits (16 gradations) are allocated to one subframe is expressed.

In FIG. 4, each of the eight subframes (SF1 to SF8) is divided into four scan (four elements) gradation expression periods, and each one scan period is divided into four subsubframes (in FIG. 4). It is shown as symbol SSF, which is divided into four SSF1 to SSF4). Here, the sub-subframe means a subframe further than the subframe. Each sub-subframe (SSF1 to SSF4) is divided into a light emission time (LT1 to LT4) and a non-light emission time (UT1 to UT4). If SSF4 LT4 expresses the light emission time of gradation <1>, SSF3 LT3 emits gradation <2>, SSF2 LT2 emits gradation <4>, and SSF1 LT1 emits light of gradation <8>. Expressing time. Each light emission time doubles when the gradation is doubled. A maximum of 16 gradations in one subframe is expressed by a combination of the light emission times of SSF1 to SSF4.

At this time, the light emission times (LT1 to LT4) of the sub-subframes (SSF1 to SSF4) are expressed by 1: 2: 4: 8: 16: 32... In order to express the gradation of the digital signal. Binary codes can be used. In FIG. 4, although 16 gradations (4 bits) are represented, gradations 1: 2: 4: 8 correspond to light emission times LT4: LT3: LT2: LT1, and SSF1 corresponds to the most significant bit.
The light emission times (LT1 to LT4) in the period of (SSF1 to SSF4) of each sub-subframe are formed as shown in FIG. 4, and a maximum of 16 gradations are expressed in one subframe by combining the light emission times. For example, when expressing gradation 5 within one subfield, LT4 (gradation <1>) of SSF4 and LT2 (gradation <4>) of SSF2 emit light, and LT1 of SSF1 and LT3 of SSF3 do not emit light. Gradation is expressed by a combination of on / off of the light emission times of SSF1 to SSF4.

  As shown in this figure, the gradation of a desired image is expressed by combining all the light emission times (LT1 to LT4) in each subframe (SF1 to SF8) and each subsubframe (SSF1 to SSF4) of one frame. be able to. In addition, when one frame has only two states of light emission or non-light emission (that is, has no gradation), each subframe or sub-subframe is light emission or non-light emission. A configuration having gradation as well as two states may be used.

In general, one frame is divided into a number of subframes and subsubframes, and data is set in all bits of the divided subframes and subsubframes (data is assigned to each pixel) for display. Thus, gradation control with good display quality can be performed.
How much the data display (light emission of the light emitting display element) refreshed per unit time affects the image quality. In other words, as the number of refreshes increases, the flickering decreases and becomes easier to see, and the video looks smoother.

  In the video apparatus configured in this way, conventionally, for example, one frame period 8 is refreshed by setting data for one subframe (SF). In the present embodiment, one subframe SF1 to SF8 is divided into two parts, SF1A to SF8A and SF1B to SF8B, and lighting data is set so that lighting in one subframe period is dispersed and continuous non-light emitting time is reduced. I made it.

  For example, as shown in FIG. 4, the lighting control of 4 scans, 8 subframes, and 4 subsubframes is as shown in FIG. 5 in this embodiment, and sets subsubframes (SSF1 to SSF2) that are half the data of 1 subframe. Then, after the light emitting display element emits light for 4 scans and is refreshed, the data of the remaining sub-subframes (SSF3 to SSF4) are set. This lighting control can shorten the continuous non-light emitting time of the light emitting display element in one frame.

Embodiment 2. FIG.
FIG. 6 is a diagram showing light emission times (LT1 to LT4) and non-light emission times (UT1 to UT4) of sub-subframes (SSF1 to SSF4) according to Embodiment 2 of the present invention.
When the subframe (SF) is divided into SF_A and SF_B as shown in FIG. 5, the light emission time and the non-light emission time are biased to one subframe. For example, the light emission time of SF_A in FIG. 5 is 12 gradations of LT1 + LT2, the light emission time of SF_B is 3 gradations of LT3 + LT4, and the light emission time is biased to SF_A and the non-light emission time is biased to SF_B.
When the video is displayed, the non-light emission time is detected as image unevenness. Therefore, by arranging the sub-subframes so that the non-light-emission times are not biased as in the sub-subframes (SSF1 to SSF4) shown in FIG. Non-light emission time can be reduced. For example, as shown in FIG. 6, when the combination of LT1 with the longest light emission time and LT4 with the shortest light emission time is SF_A, and the combination of the remaining LT2 and LT3 is SF_B, the light emission time of SF_A is 9 gradations, SF_B. The light emission time is 6 gradations, and the deviation of the light emission time and the non-light emission time can be reduced.

Embodiment 3 FIG.
FIG. 8 is a diagram showing the gradation expression according to the third embodiment of the present invention. In the gradation control method according to the above embodiment, gradation expression is performed by combining the light emission time and the non-light emission time of four sub-subframes (SSF) in one subframe (SF). With this control method, the continuous non-emission time becomes longer than the emission time of 9 gradations or more when displaying gradations of 8 gradations or less. In the third embodiment, a light emission time for one gradation is further provided in addition to the four sub-subframes in one subframe (SF), and one gradation is used for low gradation display (gradation 1 to 8). Using a light emission time of a minute and a plurality of sub-subframes, low gradation display is performed by performing divided light emission using a gradation value of a minimum unit in one subframe.

For example, in the case of the arrangement of sub-subframes (SSF) as shown in FIG. 4 in one subframe (SF) period, light emission having a gradation value of 8 is SSF1 (sub-subframe 1; floor as shown in FIG. 7 in conventional control). Flash only during the adjustment time <8>). In the control of the third embodiment, as shown in FIG. 8, SSF4 (sub-subframe 4, gradation <1>), SSF3 (sub-subframe 3, gradation <2>), SSF2 (sub-subframe 2, gradation <4>). ) In addition to the light emission time, the light emission time region for one gradation provided in Embodiment 3 emits light so that the three sub-subframes (SSF) and the light emission time for one gradation are combined to provide a gradation value. 8 can be expressed. That is, the logical operation of the SSF2 gradation <4> (= 2 ² ), the SSF3 gradation <2> (= 2 ¹ ), SSF4 (= 2 ⁰ ), and one gradation (= 2 ⁰ ) Then (when converted in decimal notation, 2 ² +2 ¹ +2 ⁰ +2 ⁰ = 8), it can be seen that the gradation value 8 can be expressed. This control method can reduce the continuous non-emission time during low gradation display. The same effect can be obtained by combining the first and second embodiments with this control method.

Embodiment 4 FIG.
FIG. 9 is a diagram showing the gradation expression according to the fourth embodiment.
In the first to third embodiments, gradation expression is performed by controlling the light emission time, but in the fourth embodiment, the height of the light emission pulse (depending on the level of the voltage applied to the light emitting display element) is also controlled. The continuous non-emission time during low gradation display was reduced.

For example, in the case of the arrangement of the sub-subframe (SSF) as shown in FIG. 4 in one subframe (SF) period, light emission with a gradation value of 8 is only light emission of SSF1 (sub-subframe 1. gradation <8>) in the conventional control. Time emits light. In Embodiment 4, as shown in FIG. 9, the brightness equivalent to gradation <4> is obtained by changing the emission intensity of SSF1 (sub-subframe 1. gradation <8>), that is, by halving the voltage of the emission time. Then, the light emission time of the remaining SSF2 (sub-subframe 2. gradation <4>) is turned on to express the gradation <8> together (8 = 2 ³ = 2 ² +2 ² logic). the first ^{2 2} because it is equivalent to ² 3/2 (brightness half)) to. This control method can reduce the continuous non-emission time. Even when this control method is combined with the methods described in the first to third embodiments, the same effect can be obtained. It should be noted that the present invention can be freely combined with each other within the scope of the invention, and each embodiment can be appropriately modified or omitted.

ST1A to ST8A, ST1B to ST8B subframe, SSF1 to SSF4 subsubframe,
LT1 to LT4 Light emission time, UT1 to UT4 Non-light emission time, 1 Video display device, 2 Display panel, 3 Light emitting display element, 4 Display element driver.

Claims (4)

In a video display device in which light-emitting display elements serving as pixels are arranged to constitute a screen, and the light-emitting display elements are time-divisionally emitted to control gradation and refresh the screen.
One frame of the screen is divided into a plurality of subframes, lighting data for determining the light emission time of the light emitting display element is divided in order to control gradation of the subframe, and the light emission times in the subframes are dispersed. A video display device that performs gradation control for assigning the lighting data to each pixel of the subframe. Gradation control in which a sub-subframe is further provided in each of the plurality of sub-frames, and the sub-subframes are arranged so that non-light emission time regions are dispersed based on the light emission time or non-light emission time of the sub-subframe The video display device according to claim 1, wherein: Separately from the sub-subframe, a light emission time for one gradation is provided, and at the time of low gradation display, the light emission time for one gradation and a plurality of the sub-subframes are used to perform lighting. The video display device according to claim 2, wherein In low gradation display, the light emitting display element is turned on by controlling the light emission time of the light emitting display element to control the gradation and performing gradation control to change the light emission intensity of the light emitting display element. The video display device according to claim 2, wherein: