JP3958254B2 - Liquid crystal display device and liquid crystal display method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for displaying an image on a liquid crystal display device and a liquid crystal display device using the method.
[0002]
[Prior art]
In recent years, the performance of liquid crystal display devices has been improved, and it has begun to spread to the television field where cathode ray tubes (hereinafter referred to as CRT) have been mainstream.
[0003]
However, the liquid crystal display device has a problem that when a moving image is displayed, the image is blurred. This problem occurs because the time axis characteristics of the image display method are different between the liquid crystal display device and the CRT. The cause of this problem will be briefly described below.
[0004]
A liquid crystal display device using a transistor as a display / non-display selection switch for each pixel is a display device that employs a display method (hereinafter, hold-type display) in which a displayed image is held for one frame period. On the other hand, the CRT is a display device that employs a display method (hereinafter referred to as impulse type display) in which each pixel is darkened after being lit for a certain time.
[0005]
In the hold-type display, the same image is displayed after each frame of the moving image is displayed until the next frame is displayed. From the time frame A in the moving image is displayed until the next frame A + 1 is displayed (between frames), the same image as frame A is displayed. When the moving object M is shown in the moving image, the moving object M is stationary until the frame A + 1 is displayed after the frame A is displayed on the screen. When the frame A + 1 is displayed, the moving object M moves discontinuously.
[0006]
On the other hand, when the observer is paying attention to the moving object M and observes the moving object M (when the eye movement of the observer is a follower movement), the observer moves the eyeball continuously and smoothly unconsciously. Try to follow the moving object M.
[0007]
Then, a difference arises between the motion of the moving body M on the screen and the motion of the moving body M assumed by the observer. Due to this difference, an image shifted according to the speed of the moving object M is presented on the retina of the observer. Since the observer perceives a shifted image in which the shifted images are superimposed, the viewer feels that the moving image is blurred.
[0008]
The faster the moving image moves, the greater the deviation of the image presented on the viewer's retina, and the viewer will receive a more blurred impression.
[0009]
Such “blur” does not occur in the case of the impulse display. This is because in the case of the impulse-type display, black is displayed between the frames of the moving image (for example, between the above-described frame A and frame A + 1).
[0010]
Since black is displayed between the frames, even when the observer moves the eyeball and smoothly follows the moving object, the observer cannot see the image except for the moment when the image is displayed. Since the observer recognizes one frame of the moving image as an independent image, the image presented on the retina is not shifted.
[0011]
In order to solve the above-described problem in a display device that performs hold-type display, a method of displaying “black” by some means after displaying a frame has been proposed (for example, Patent Document 1).
[0012]
[Patent Document 1]
JP-A-11-109921
[0013]
[Problems to be solved by the invention]
In Patent Document 1, the above-described problem is addressed by intentionally setting the liquid crystal screen between frames to “black”. However, the contrast is halved by the black display. The power consumption of the backlight that is lit even during the black display period is wasted.
[0014]
As another method, a method of blinking the backlight has been proposed. However, the backlight emission timing is not desired after the response of the liquid crystal is completed. If a liquid crystal material with a relatively low response speed is used, the scanning time is shortened or the light emission period is shortened. Improvement is required. However, the former has a problem that the load on the circuit becomes large, and the latter has a problem that sufficient luminance cannot be obtained.
[0015]
The present invention has been made in view of the above problems. An object of the present invention is to provide a liquid crystal display device and a liquid crystal display method capable of improving the image quality of a moving image displayed on a liquid crystal display.
[0016]
[Means for Solving the Problems]
In order to solve the above problems, a liquid crystal display device of the present invention includes (A) an input unit that sequentially inputs each frame of an input video as an input frame, and (B) a delay obtained by delaying the input frame by one frame period of the input video. A delay frame generation unit for generating a frame; and (C) conversion data representing the relationship between the gradation data of the input frame and the gradation data of the delay frame and the gradation data of two display frames to be actually displayed. A converted data storage unit, (D) a display frame generating unit that generates a first display frame and a second display frame using the input frame, the delay frame, and the converted data; A frame memory for storing the first display frame and the second display frame; and (F) the first display frame and the second display frame are stored in the frame memory. And (G) a liquid crystal display unit for displaying the first display frame and the second display frame output from the display control unit. And comprising.
[0017]
Note that one frame period of an input video is a time interval from the input of a certain input frame to the input of the next input frame.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
A liquid crystal display device according to a first embodiment of the present invention will be described below with reference to the drawings.
[0019]
(Outline) The liquid crystal display device of the present embodiment generates two display frames per frame from each frame (input frame) of an image in a video signal, and displays the generated display frames on a liquid crystal screen. is there. The image in the video signal may be either a still image or a moving image.
[0020]
The present liquid crystal device generates two display frames having different luminances based on pixel information of the input frame N and the previous input frame N-1. These two display frames are alternately displayed on the liquid crystal screen within one frame period. Note that one frame period is the time from when a certain input frame is input until the next input frame is input, that is, the time interval between input frames.
[0021]
When these two display frames are generated, the value obtained by integrating the change in gradation (display gradation) based on the response of the liquid crystal when they are actually displayed on the liquid crystal display device over one frame period is The input frame N is set to be the same as the integral value of the display gradation when the input frame N is displayed for one frame period.
[0022]
With such a display method, the present liquid crystal device can suppress blurring of an image that is easily perceived by a viewer when displaying a moving image without reducing luminance or contrast.
[0023]
(Schematic Configuration) FIG. 1 shows a configuration diagram of the liquid crystal display device of this embodiment. The liquid crystal display device of the present embodiment generates an input unit 100 that sequentially inputs an input frame of an input video signal, a frame memory 101 that holds the input frame for one frame period, and a first display frame and a second display frame. The conversion table 102 is provided.
[0024]
A display frame generation unit 103 that generates a first display frame and a second display frame by referring to the conversion table 102 using an input frame and a delay frame obtained by delaying the input frame by one frame period in the frame memory 101; A frame memory 104 that holds the first display frame and the second display frame for one frame period.
[0025]
Further, the display control unit 105 that alternately outputs the first display frame and the second display frame read from the display frame memory 104 at a refresh rate twice as high as the input video signal, and the display control unit 105 And a liquid crystal display unit 106 for displaying a display frame.
[0026]
In this embodiment, it is assumed that the refresh rate of the input video signal is 60 Hz.
[0027]
Hereinafter, each part will be described.
[0028]
(Input unit 100) The input unit 100 sequentially inputs input frames.
[0029]
(Frame Memory 101) The frame memory 101 holds an input frame in a frame unit for one frame period, and outputs it as a delay frame to the display frame generation unit 103.
[0030]
(Conversion Table 102) The conversion table 102 is a ROM (Read Only Memory) that stores a gradation data conversion LUT (Look Up Table) used when generating the first and second display frames. The conversion table 102 stores two types, a first display frame generation LUT 111 and a second display frame generation LUT 112.
[0031]
FIG. 2 is an example of the first display frame generation LUT 111 in the conversion table 102. The first display frame generation LUT 111 of this embodiment is a matrix-like LUT, the column direction corresponds to the gradation data of the pixels of the input frame, and the row direction corresponds to the gradation data of the pixels of the delay frame.
[0032]
The gradation data of each pixel of the first display frame is obtained by referring to the first display frame generation LUT 111 using the gradation data of the pixel of the input frame and the gradation data of the pixel of the delay frame as address information. .
[0033]
FIG. 2 shows an example of a method for referring to the first display frame generation LUT 111. When the gradation data of a certain pixel is 120 for the input frame and 15 for the delay frame, the first display frame generation LUT 111 has 120 columns of gradation data of the input frame and gradation data of the delay frame. “180” corresponding to the intersection with 15 columns is the gradation data in the first display frame of the pixel.
[0034]
In this embodiment, the conversion table 102 uses a ROM, but other storage media such as a RAM (Random Access Memory) may be used. In addition, the conversion LUT stored in the ROM is held in a matrix form, and the display frame gradation data corresponding to the input address signal (that is, the frame gradation data) is read. If possible, it may be held one-dimensionally, for example. In addition, the LUT does not need to store the converted gradation data for all the gradation data. For example, the LUT holds discrete converted gradation data every four gradations for the gradation data of the input frame and the delay frame. In addition, the truncated gradation data can be supplemented by linear interpolation or the like. By doing so, it is possible to reduce the size of the LUT.
[0035]
(Display Frame Generation Unit 103) The display frame generation unit 103 generates a first display frame and a second display frame with reference to the conversion table 102 using an input frame and a delay frame.
[0036]
The display frame generation unit 103 is realized as a gate array that inputs gradation data of an input frame and gradation data of a delay frame. In the gate array, the gradation data of the input frame and the delayed frame gradation data are output to the first display frame generation LUT 111 and the second display frame generation LUT 112 of the conversion table 102 as address signals for each RGB sub-pixel. .
[0037]
For example, when each sub-pixel of the input frame is represented by 8-bit gradation data, this address signal is a 16-bit signal that is a combination of the 8-bit input frame and the 8-bit delay frame. Based on this address signal, the gradation data of each pixel in each display frame is read from the first display frame generation LUT 111 and the second display frame generation LUT 112 as described above.
[0038]
The grayscale data in the first display frame and the second display frame read from the first display frame generation LUT 111 and the second display frame generation LUT 112 is output to the frame memory 104 via the gate array.
[0039]
(Frame Memory 104) The frame memory 104 stores the first display frame and the second display frame generated by the display frame generation unit 103.
[0040]
The display frame read from the display control unit 105 may be deleted from the frame memory 104.
[0041]
(Display Control Unit 105) The display control unit 105 reads the first display frame and the second display frame from the frame memory 104, and alternately doubles the input video signal in the order of the first display frame and the second display frame. Is output to the liquid crystal display unit 106 at the refresh rate.
[0042]
The display control unit 105 starts outputting the second display frame when 0.5 frame period has elapsed since the output of the first display frame was started. Then, when the 0.5 frame period has elapsed since the start of output of the second display frame, output of the next first display frame is started. That is, the first display frame and the second display frame are called from the frame memory at a speed twice the timing of the input video signal.
[0043]
The display control unit 105 also outputs control signals such as a vertical synchronization signal and a horizontal synchronization signal for controlling the liquid crystal display unit 106.
[0044]
In this embodiment, since the refresh rate of the input video signal is 60 Hz, the display control unit 105 outputs a control signal so that the liquid crystal display unit 106 can display a display frame at a refresh rate of 120 Hz.
[0045]
(Liquid Crystal Display Unit 106) The liquid crystal display unit 106 sequentially displays each display frame on the liquid crystal screen based on the display frame and various control signals output from the display control unit 105.
[0046]
(LUT stored in conversion table 102) Hereinafter, the first display frame generation LUT and the second display frame generation LUT held in the ROM will be described.
[0047]
The liquid crystal display device according to the present embodiment divides one frame period for displaying one input frame into two, and alternately displays two display frames, a display frame with a high luminance and a display frame with a low luminance. Either the first display frame or the second display frame may be a display frame with high luminance. In the present embodiment, the first display frame is a display frame with high luminance, and the second display frame. Is a display frame with low luminance.
[0048]
Therefore, the first display frame generation LUT 111 is an LUT that holds gradation data with relatively high luminance for generating a display frame with high luminance. The second display frame generation LUT 112 has a display frame with low luminance. This is an LUT holding gradation data with relatively low luminance for generation.
[0049]
The gradation data held by these LUTs is roughly determined in advance (for example, at the time of manufacturing the liquid crystal display device) by the following two-stage algorithm.
(1) Derivation of gradation data of the first display frame and gradation data of the second display frame when the gradation data of the input frame and the gradation data of the delay frame are equal.
(2) Derivation of gradation data of the first display frame and gradation data of the second display frame when the gradation data of the input frame and the gradation data of the delay frame are not equal.
[0050]
First, in (1), diagonal components of the first display frame generation LUT 111 and the second display frame generation LUT 112 are obtained. Then, in (2), the remaining components are obtained. Details of each will be described below.
[0051]
(1) LUT derivation when the gradation data of the input frame is equal to the gradation data of the delay frame.
[0052]
“When the input frame grayscale data and the delayed frame grayscale data are equal” corresponds to a case where an image having no change, for example, a still image is displayed.
[0053]
In this case, in a liquid crystal display device that alternately displays a display frame with a high luminance and a display frame with a low luminance as in the liquid crystal display device of this embodiment, gradation data to be displayed by a method different from that of a conventional liquid crystal display device is used. It is necessary to decide.
[0054]
The integral value of one frame period based on the liquid crystal response of the gradation data (hereinafter referred to as display gradation) of the first display frame and the second display frame actually displayed on the screen is the same as that of the conventional hold type display device. It should just become. This is because if the integral value of the display gradation in one frame period is different from the conventional one, the person viewing the screen recognizes that the gamma characteristic of the video is different from the conventional one, but if the integral value is the same This is because it is recognized that the gamma characteristics are the same.
[0055]
In the present embodiment, considering the response characteristics of the liquid crystal, the first display frame and the second display frame are based on the integral value of one frame period of the gradation actually displayed on the screen (hereinafter referred to as display gradation). Determine key data.
[0056]
FIG. 3 shows the response waveform of each display device when the same still image video signal is input to each of the conventional hold type display device and the liquid crystal display device of this embodiment, that is, the time change of the display gradation. FIG.
[0057]
In FIG. 3, the vertical axis represents gradation and the horizontal axis represents time, and shows a response waveform in one frame period (1/60 seconds). The response waveform 301 is that of the liquid crystal display device of the present embodiment, and the response waveform 302 is that of a conventional hold type display device. Here, as a conventional hold display device, a system that displays the same image for one frame period is taken up.
[0058]
In the conventional hold-type display device, as shown by the response waveform 302 in FIG. 3, the display gradation is maintained equal to the gradation data of the input frame over one frame period.
[0059]
In the liquid crystal display device according to the present embodiment, for example, a first display frame having a high luminance is displayed in the first half of one frame period and a second display frame having a low luminance is displayed in the second half of one frame period, as in a response waveform 301 of FIG. indicate. When displaying the first and second display frames, the integral value of one frame period of the response waveform is the same as the integral value of one frame period of the response waveform at the time of display on the conventional hold type display device. Like that. Further, in order to display a high-luminance display frame on the first display frame and a low-luminance display frame on the second display frame, as shown in FIG. 3, the gradation at the start of display of the first display frame is displayed. (Initial gradation) is changed to be lower than the gradation data of the input frame.
[0060]
Any amount of change in the initial gradation may be used. However, when the gradation data of the input frame is 0, the change amount is set to 0 to display black, and both the first display frame and the second display frame are displayed. It is desirable to display 0 gradation. In order to achieve the same luminance as the conventional liquid crystal display device even when the gradation data of the input frame is the maximum gradation of the liquid crystal display device (for example, 255 for a liquid crystal display device of 256 gradations), It is desirable to set the change amount to 0 and display 255 gradations in both the first display frame and the second display frame.
[0061]
FIG. 5 is a diagram for explaining an example of a method for determining the amount of change in the initial gradation. The horizontal axis in FIG. 5 represents the gradation data of the input frame, and the vertical axis represents the absolute value of the change amount of the initial gradation with respect to the gradation data of the input frame. In FIG. 5, the change amount is changed linearly so that the change amount is 63 when the gradation data of the input frame is 127, and the change amount is 0 when the gradation data of the input frame is 0 and 255. I am letting. In this embodiment, the initial gradation is changed linearly as shown in FIG.
[0062]
Further, when displaying a still image, as shown in FIG. 3, the reached gradation after the gradation data of the second display frame is written needs to be the same as the initial gradation. This is because when the gradation data of the second display frame is not written and the same gradation as the initial gradation is not reached, a flicker with a refresh rate that is ½ times the input video signal is visually recognized. In this embodiment, since the input video signal is 60 Hz, 30 Hz flicker is visually recognized.
[0063]
In summary, the gradation data of the first display frame and the second display frame preferably satisfy the following conditions.
(A) The reached gradation after the gradation data is written in the second display frame is equal to the initial gradation.
(B) The integrated value of the response waveform when displaying the first display frame and the second display frame is equal to the integrated value of the response waveform of the conventional 60 Hz hold-type display liquid crystal display device.
[0064]
FIG. 6 shows a flowchart for deriving the gradation data of the first display frame and the gradation data of the second display frame. In accordance with this flowchart, the first display frame generation LUT 111 and the second display frame generation LUT 112 are generated in advance.
[0065]
In FIG. 6 and the following description, L_INIs the gradation data of the input frame, L_{IN IT}(L_IN) Is the amount of change ΔL (L represented by the vertical axis in FIG._IN) The changed initial gradation, L_1st(L_IN) Is the gradation data of the first display frame, L_2nd(L_IN) Is the gradation data of the second display frame.
[0066]
L_ENDIs the gradation data L of the second display frame_2nd(L_IN) Is the reached gradation after writing, and T (L_IN) Is L_INIs the integrated value of the response waveform in one frame period when the image is displayed on the conventional liquid crystal display device of the hold type display, and t_1stIs the integral value of the response waveform during the 1/2 frame period when the first display frame is displayed, and t_2ndIs the integral value of the response waveform during the 1/2 frame period when the second display frame is displayed, and L_MAXIs the maximum gradation of a liquid crystal display device (255 for a liquid crystal display device of 256 gradations). FIG. 7 illustrates the above relationship.
[0067]
Hereinafter, specific processing will be described with reference to the flowchart of FIG.
[0068]
(Step S601) L_INSet to 0. That is, the gradation data of the first display frame and the second display frame are sequentially calculated from the case where the gradation data of the input frame is 0.
[0069]
(Step S602) L_INIT(L_IN), L_INTo △ L (L_IN) Is subtracted. That is, the initial gradation is changed to a value lower by a certain amount ΔL than the gradation data of the input frame.
[0070]
(Step S603) L_1st(L_IN) L_INITSet to. The gradation data of the first display frame is made equal to the initial gradation. This step is L_1st(L_IN) Is the starting point of the loop processing. L_1st(L_IN) L_INITThe optimum value is obtained while increasing by one.
[0071]
(Step S604) L_2nd(L_IN) L_INITSet to. The gradation data of the second display frame is made equal to the initial gradation. This step is L_2nd(L_IN) Is the starting point of the loop processing. L_2nd(L_IN) L_INITThe optimum value is obtained while reducing the value one by one.
[0072]
(Step S605) L_INITTo L_ENDL_INITIs equal to. L_INITL at an interval of 1/120 second from the state displayed at_1st(L_IN) And L_2nd(L_IN) And the reached gradation L_ENDIs calculated using the response speed of the liquid crystal display unit 106 measured in advance.
[0073]
L_INITAnd L_ENDIf is not equal, the process of step S606 is performed. L if equal_2nd(L_IN) Is terminated, and the process of step S608 is performed.
[0074]
(Step S606) L_2nd(L_IN) Is equal to 0. This step is L_2nd(L_IN) For determining the end condition of the loop processing.
[0075]
If they are not equal, the process of step S607 is performed to repeat the loop process. L if equal_2nd(L_INSince the loop processing related to) is completed, the processing of step S609 is performed.
[0076]
(Step S607) L_2nd(L_IN) Loop processing is updated. Specifically, L_2nd(L_IN1) is subtracted from After the subtraction, step S605 is performed.
[0077]
(Step S608) In step S605, L_INITAnd L_ENDAre determined to be equal, first, L_INITThe gradation data L of the first display frame from the state of_1st(L_IN) And gradation data L of the second display frame_2nd(L_IN) The total integrated value of the response waveform t_1st+ T_2ndAsk for. Then L_INThe integrated value T (L_IN) And t_1st+ T_2ndAre equal.
[0078]
T (L_IN) And t_1st+ T_2ndIf is equal, the process of step S612 is performed. If they are not equal, the process of step S609 is performed.
[0079]
(Step S609) L_1st(L_IN) Is L_MAXIs equal to. This step is L_1st(L_IN) For determining the end condition of the loop processing.
[0080]
If equal, the loop has been completed, and the process of step S611 is performed. If they are not equal, the process of step S610 is performed.
[0081]
(Step S610) L_1st(L_IN) Loop processing is updated. Specifically, L_2nd(L_IN1 is added to). After the addition, the process of step S604 is performed.
[0082]
(Step S611) ΔL (L_IN) Subtract 1 from L_INIT(L_IN1 is added to). After the calculation, the process of step S603 is performed.
[0083]
(Step S612) L_INIs L_MAXTo determine if they are equal. This step corresponds to the loop end determination starting from step S601.
[0084]
If not equal, the process of step S613 is performed, and if equal, the process is terminated.
[0085]
(Step S613) L_INAdd 1 to. After the addition, the process of step S602 is performed.
[0086]
Based on the flowchart of FIG. 6 described above, L_IN= 0 to L_MAXWrite gradation data L of the first display frame in each case up to_1st(L_IN), Writing gradation data L of the second display frame_2nd(L_IN) And initial gradation L_INIT(L_IN) As described above, the writing gradation L of the first display frame obtained here is obtained._{1s t}(L_IN) And the second display frame writing gradation L_2nd(L_IN) Is a diagonal component of each LUT stored in the conversion table 102 (when the gradation data of the input frame and the gradation data of the delay frame are equal). The initial gradation L_INIT(L_IN) Is used in the process (2) described later.
[0087]
In FIG. 6, the equal sign (=) is used to express “equal” at the time of conditional branching, but in the present embodiment, it is not required to be “strictly equal”. It is assumed that they are almost equal, i.e., within a certain error range. This is because the gradation data is a discrete value, and even if the gradation data is equal, not all related parameters are necessarily exactly the same.
[0088]
L in step S611_INIT(L_IN) Is added. This process is intended to reliably maintain the gamma characteristic in a still image in which the disturbance of the gamma characteristic is very easily visually recognized as compared with a moving image. When the integrated value of the response waveform is different from that of the one frame period in the conventional 60 Hz hold type display, the gamma characteristics are disturbed.
[0089]
In the present embodiment, L set in step S602._INIT(L_IN) If the gamma characteristic is disturbed,_INIT(L_IN) To suppress disturbances. Conversely, an appropriate ΔL (L_IN) To set L_INIT(L_IN) May not be changed.
[0090]
(2) Derivation of the LUT when the gradation data of the input frame and the gradation data of the delay frame are not equal.
[0091]
“The case where the gradation data of the input frame and the gradation data of the delay frame are not equal” corresponds to a case where an image having a change, for example, a moving image (a change) is displayed.
[0092]
FIG. 9 is an example of a response waveform for one frame period when the gradation data of the input frame and the gradation data of the delay frame are not equal. When the first display frame and the second display frame are written from the state of the initial gradation 904, the arrival gradation 905 is reached.
[0093]
When the gradation data of the input frame and the gradation data of the delay frame are not equal, a value L obtained by changing the arrival gradation 905 by “a certain gradation” from the gradation data 903 of the input frame_INIT(L_IN). This means that the reached gradation 905 is always set to the same value if the gradation data of the input frame is the same regardless of the gradation frame gradation data.
[0094]
In this way, it is possible to determine the LUT for obtaining the write gradation data of the first display frame and the write gradation data of the second display frame all together.
[0095]
If the reached gradation 905 cannot be uniquely determined from the gradation data of the current input frame, the gradation data of the first display frame and the gradation data of the second display frame for the next input frame are the next input. It becomes extremely difficult to determine only from the gradation data of the frame and the gradation data of the next delay frame (gradation data of the current input frame).
[0096]
For example, it is assumed that the gradation data of the input frame is the same value in a certain frame period A and a certain frame period B, but the arrival gradation 905 is different. In this case, the initial gray levels in the next frame periods A + 1 and B + 1 are different.
[0097]
Here, it is assumed that input frames having the same gradation data are input in the frame periods A + 1 and B + 1. Then, in order to display the first display frame and the second display frame so that the display gradation is not shifted in each frame period, different first display frames and second display frames suitable for the respective frame periods are used. It is necessary to prepare.
[0098]
Even if the same first display frame and second display frame are forcibly displayed in the frame periods A + 1 and B + 1, the integrated values of the response waveform and the response waveform become different values. Therefore, a display gradation shift (gamma characteristic disturbance) occurs.
[0099]
A means for referring to a change in gradation data from several frames before as a history is also conceivable. However, as the number of frames to be referenced increases, the gradation data of the first display frame and the second display frame are increased as the number of frames to be referred to increases. This causes a problem that the size of the LUT that holds the grayscale data increases.
[0100]
Therefore, as shown in FIG. 10, it is necessary that the reached gradation 1003 after writing the gradation data of the second display frame always has the same value regardless of the value of the initial gradation 1001. For this purpose, it is preferable that the reached gradation 1003 can be determined from the gradation data of the input frame.
[0101]
Then, the gradation data of the first display frame and the second display frame of the next input frame are the gradation data of the next input frame and the gradation data of the next delay frame (the gradation data of the current input frame). ).
[0102]
After satisfying the above conditions, as in (1) above, the integrated value of one frame period of the response waveform when the gradation data of the first display frame and the second display frame of FIG. 9 is written is input. The gradation data of the first display frame and the gradation data of the second display frame are determined so that the gradation data of the frame is equal to the integral value of the response waveform when displayed on the conventional liquid crystal display device.
[0103]
In summary, the gradation data of the first display frame and the gradation data of the second display frame preferably satisfy the following conditions.
(A) The reached gradation after the gradation data of the second display frame is written is the gradation data L of the current input frame._INThe initial gradation L obtained in (1) above for_INIT(L_IN)be equivalent to.
(B) The integrated value of the response waveform for one frame period when the gradation data of the first display frame and the gradation data of the second display frame are written, and the input frame to the conventional 60 Hz hold-type display liquid crystal display device. The integrated value of the response waveform when the gray scale data is written is equal.
[0104]
If the arrival gradation is not uniquely determined from the gradation data of the current input frame, the writing gradation data of the first display frame and the writing gradation data of the second display frame in the next frame period can be determined. Can not. Therefore, the condition (A) is essential.
[0105]
However, even if the gradation data of the first display frame and the gradation data of the second display frame are both set to 0 or 255, the predetermined gradation (the gradation data L of the current input frame) is written._INThe initial gradation L obtained in (1) above for_INIT(L_IN)) Cannot be reached, the gradation data of the first display frame and the gradation data of the second display frame are set to 0 gradation or 255 gradation.
[0106]
Although the condition (B) is described as “the integrated values of the response waveforms are equal”, the disturbance of the gamma characteristic at the time of moving image display is less likely to be visually recognized compared to the time of still image display. In this embodiment, after satisfying the condition (A), “the integrated value of one frame period of the response waveform when the gradation data of the first display frame and the gradation data of the second display frame are written; This is implemented under the condition that the absolute value difference with the integral value of the response waveform is the smallest when the gradation data of the current input frame is written as it is. It should be noted that not only “absolute value difference” but also “square of difference” may be used.
[0107]
L that satisfies both the above conditions (A) and (B)_1st, L_2ndAre the writing gradation data of the first display frame and the second display frame, respectively.
[0108]
FIG. 11 is a flowchart for deriving gradation data of the first display frame and the second display frame. Where L_DIs delay frame gradation data, L_1st(L_D, L_IN) Indicates that the delay frame grayscale data is L_D, Input frame gradation data is L_INWrite gradation data of the first display frame at the time of L_2nd(L_D, L_IN) Indicates that the delay frame grayscale data is L_D, Input frame gradation data is L_INWriting gradation data of the second display frame at time t (L_1st, L_2nd) Represents the integrated intensity of one frame period based on the display waveforms of the first display frame and the second display frame. The operation of the flowchart will be described below.
[0109]
(Step S1101) L_DIs set to 0. This step is for the delay frame gradation data L_DIs the starting point of the loop processing for
[0110]
(Step S1102) L_INIs set to 0. This step is the gradation data L of the input frame._INIs the starting point of the loop processing for
[0111]
(Step S1103) L_DAnd L_INIt is determined whether or not is equal. If not equal, the process of step S1104 is performed. If they are equal, the process of step S1118 is performed.
[0112]
In the case where they are equal, this corresponds to the case where there is no change in the gradation data of the input frame between the previous frame period and the current frame period.
[0113]
(Step S1104) Based on the initial gradation obtained in the case of (1) above, that is, when the gradation data of the input frame and the gradation data of the delay frame are equal, L_INIT(L_D), L_INIT(L_IN) Is set.
[0114]
(Step S1105) Write gradation data L of the first display frame_1st(L_D, L_IN) And writing gradation data L of the second display frame_2nd(L_D, L_IN) And 0.
[0115]
(Step S1106) Write gradation data L of the first display frame_1st(L_D, L_IN) And writing gradation data L of the second display frame_2nd(L_D, L_INReached gradation L when) is 0_ENDAsk for. And L_ENDIs L_INIT(L_INIf larger, the process of step S1117 is performed. L_ENDIs L_INIT(L_INIf not, the process of step S1107 is performed.
[0116]
In this embodiment, even if 0 gradation is written in both the first display frame and the second display frame, a predetermined initial gradation L_INIT(L_IN) Cannot be reached, both the first display frame and the second display frame are set to 0 gradation. The process of this step is a process for determining whether it is reachable
(Step S1107) Write gradation data L of the second display frame_2nd(L_D, L_IN) Is set to 0.
[0117]
(Step S1108) L_ENDIs L_INIT(L_IN).
[0118]
If they are equal, the process of S1114 is performed. If not equal, the process of step S1109 is performed.
[0119]
In this embodiment, both the first display frame and the second display frame are L._MAXEven if the gradation is written, the predetermined initial gradation L_INIT(L_IN) Cannot be reached in both the first display frame and the second display frame._MAXSet to. A series of steps S1109, S1111 and S1112 is a process for determining whether or not it is reachable.
[0120]
(Step S1109) Write gradation data L of the second display frame_2nd(L_D, L_IN) Is the maximum gradation L_MAXTo determine if they are equal.
[0121]
If not equal, the process of step S1110 is performed. If they are equal, the process of step S1111 is performed.
[0122]
(Step S1110) Write gradation data L of the second display frame_2nd(L_D, L_IN) Is incremented by 1 and the process of step S1108 is performed.
[0123]
(Step S1111) Write gradation data L of the first display frame_1st(L_D, L_IN) Is the maximum gradation L_MAXTo determine if they are equal.
[0124]
If not equal, the process of step S1113 is performed. If they are equal, the process of step S1112 is performed.
[0125]
(Step S1112) Write gradation data L of the first display frame_1st(L_D, L_IN) And writing gradation data L of the second display frame_2nd(L_D, L_IN) And L_MAXAnd the process of step S1118 is performed.
[0126]
(Step S1113) Write gradation data L of the first display frame_1st(L_D, L_IN) And 1 is added to perform the process of step S1107.
[0127]
(Step S1114) The liquid crystal response speed and L determined in advance._INIT(L_D) And L_1st(L_IN) And L_2nd(L_IN) Response waveform t_1st, T_2ndT (L_1st, L_2nd)
[0128]
(Step S1115) Write gradation data L of the first display frame_1st(L_D, L_IN) Is L_MAXTo determine if they are equal.
[0129]
If not equal, the process of step S1113 is performed. If they are equal, the process of step S1116 is performed.
[0130]
(Step S1116) L obtained so far_1stAnd L_2ndFor various combinations of t (L_1st, L_2nd) And T (L_INL) when the absolute value difference is minimum._1stAnd L_2ndAnd L_1st(L_D, L_IN), L_2nd(L_D, L_IN). Then, the process of step 1118 is performed.
[0131]
(Step S1117) L_1st(L_D, L_IN) And L_2nd(L_D, L_IN) Is set to zero. Then, the process of step S1118 is performed.
[0132]
(Step S1118) L_INIs L_MAXIt is judged whether it is smaller (less than). This step is L_INIt is a step which performs continuation determination of the loop process regarding.
[0133]
If not smaller, the process of step S1120 is performed. If it is smaller, the process of step S1119 is performed.
[0134]
(Step S1119) L_INThe process of step S1103 is performed by adding 1 to.
[0135]
(Step S1120) L_DIs L_MAXDetermine if smaller. This step is L_DIt is a step which performs continuation determination of the loop process regarding.
[0136]
If it is not smaller, the process is terminated. If it is smaller, the process of step S1121 is performed.
[0137]
(Step S1121) L_D1 is added to step S1102.
[0138]
Based on the flowchart of FIG._INAnd L_D0 to L_MAXWriting gradation data L of the first display frame in each case changed in the range of_1st(L_D, L_IN) And writing gradation data L of the second display frame_2nd(L_D, L_IN) And ask.
[0139]
L calculated here_1st(L_D, L_IN) Indicates that the row direction is L in the matrix of the first display frame generation LUT 111._D, Column direction is L_INIs held at the point. Similarly, L_2nd(L_D, L_IN) Is held in the second display frame generation LUT 112.
[0140]
L calculated here_1st(L_D, L_IN) And L obtained in (1)_1st(L_IN), The first display frame generation LUT 111 is completed. The same applies to the second display frame generation LUT 112, and the L obtained here is calculated._2nd(L_D, L_IN) And L obtained in (1)_2nd(L_IN), The second display frame generation LUT 112 is completed.
[0141]
As mentioned above, L_1st(L_IN), L_2nd(L_IN) Is L_D= L_INThis is the case (the gradation data of the input frame is equal to the gradation data of the delay frame). Therefore, in the LUT matrix, L_DAnd L_INAre held at equal points, i.e. diagonal components.
[0142]
The LUT of the gradation data generated through the processes (1) and (2) and held in a matrix form is used as an address signal._D, L_INL by referring to_1st(L_D, L_IN), L_2nd(L_D, L_IN) Can be determined.
[0143]
(Modification 1) In the present embodiment, the first display frame is a display frame with high luminance, and the second display frame is a display frame with low luminance. On the contrary, the first display frame may be a display frame with a low luminance, and the second display frame may be a display frame with a high luminance.
[0144]
In this case, as shown in FIG. 4, it is necessary to convert the initial gradation higher by a predetermined gradation with respect to the gradation data of the input frame. FIG. 8 is a flowchart for explaining processing for obtaining the first display frame generation LUT and the second display frame generation LUT for this modification.
[0145]
(Modification 2) In the present embodiment, the case where there are two display frames has been described. However, the display frame generation LUT may be obtained in the same manner even when there are three or more display frames.
[0146]
In the same manner as in the case of two sheets, processing is performed in the following two stages.
(1) Derivation of gradation data of a plurality of display frames when the gradation data of the input frame and the gradation data of the delay frame are equal.
(2) Derivation of gradation data of a plurality of display frames when the gradation data of the input frame and the gradation data of the delay frame are not equal.
[0147]
In the process (1), the diagonal component of the display frame generation LUT is obtained so as to satisfy the following two conditions.
(A) The reached gradation after the gradation data is written in the last display frame is equal to the initial gradation.
(B) The integrated value of one frame period of the input waveform of the response waveform when all the display frames are displayed during one frame period of the input video and when the input frame is displayed during one frame period of the input video. The absolute value difference or the square of the difference is minimized.
[0148]
In the process (2), the remaining components of the display frame generation LUT are obtained so as to satisfy the following two conditions.
(A) The reached gradation after the gradation data of the last display frame is written is the gradation data L of the current input frame._INThe initial gradation L obtained in (1) above for_INIT(L_IN)be equivalent to.
(B) The integrated value of one frame period of the input waveform of the response waveform when all the display frames are displayed during one frame period of the input video and when the input frame is displayed during one frame period of the input video. The absolute value difference or the square of the difference is minimized.
[0149]
The order of displaying the plurality of generated display frames is preferably set so that the luminance maximum of the display frames is only once in one frame period of the input video. If there is a maximum of a plurality of times in one frame period of the input video, the viewer may recognize blurring of the image when displaying a moving image.
[0150]
For example, the order in which the plurality of display frames are displayed may be set in order of increasing or decreasing luminance. Alternatively, the display frames may be displayed in order of increasing brightness in the first half, and the display frames may be displayed in order of decreasing brightness in the second half, with the display frame having the highest brightness in one frame period of the input video. good.
[0151]
(Effect of this embodiment) As described above, in the liquid crystal display device of this embodiment, a bright display frame and a dark display frame are generated at a rate twice the frame rate of the input frame, and within one frame period. it's shown. This makes it possible to improve the image quality of the displayed moving image, particularly with respect to a change in halftone gradation that is often included in normal natural moving images.
[0152]
Further, in the liquid crystal display device of this embodiment, when generating a display frame, the integrated value of the response waveform over one frame period is substantially equal to the integrated value of the response waveform in the conventional hold type liquid crystal display device. Since it is generated, it is possible to suppress a decrease in luminance and contrast.
[0153]
(Second Embodiment) The second embodiment of the present invention will be described below with reference to the drawings.
[0154]
FIG. 12 is a diagram illustrating the configuration of the liquid crystal display device of this embodiment. Although the basic configuration of this embodiment is the same as that of the first embodiment, the present embodiment includes a scene change detection unit 1201 and gradation data of the first display frame based on information from the scene change detection unit. The second embodiment differs from the first embodiment in that the gradation data of the second display frame is variable.
[0155]
Further, the conversion table 102 includes the initial gradation L described in the first embodiment in addition to the first display frame generation LUT 111 and the second display frame generation LUT 112._INIT(L_IN) Also holds.
[0156]
An input frame and a delay frame are input to the scene change detection unit 1201. The scene change detection unit 1201 detects whether the input frame is a scene change, and notifies the display frame generation unit 103 of the presence or absence of a scene change as a scene change detection signal.
[0157]
The scene detection method used in the present embodiment obtains an absolute value difference sum between an input video and a frame delayed by one frame period, and considers a scene change when the absolute value difference sum is larger than a threshold value. The threshold value may be constant, or may be changed (for example, lowered to a certain level) in accordance with the elapsed time since the occurrence of a scene change before.
[0158]
The display frame generation unit 103 refers to the first display frame generation LUT 111 and the second display frame generation LUT 112 using the gradation data of the input frame and the delay frame as address signals, as in the first embodiment. To generate a display frame.
[0159]
However, if there is a notification from the scene change detection unit 1201 that a scene change has been detected, the initial gradation L stored in the conversion table 102 is stored._INIT(L_IN). Then, the gradation data of the first display frame and the gradation data of the second display frame are converted into the initial gradation L._INIT(L_IN).
[0160]
The first display frame and the second display frame generated as described above are displayed on the liquid crystal display unit 106 via the display control unit 105 in the same operation as in the first embodiment.
[0161]
Similar to the liquid crystal display device of the first embodiment, the liquid crystal display device of this embodiment has an initial gray level L in which the reached gray level after writing the gray level data of the second display frame is determined by the gray level data of the input frame._INIT(L_IN), The writing gradation of the first display frame and the second display frame is determined.
[0162]
However, when driven for a long time, it is considered that the response characteristics of the liquid crystal change due to the influence of the ambient temperature and the like, and the above relationship gradually includes an error. That is, when the drive is continued for a long time, the gamma characteristic of the display image may be disturbed.
[0163]
Therefore, in this embodiment, when a scene change is detected, the initial gradation L is displayed on the first display frame and the second display frame._INIT(L_IN) To reset the accumulated error. By such an operation, it is possible to suppress the disturbance of the gamma characteristic of the display image that occurs when driven for a long time.
[0164]
In general, it is extremely difficult for viewers to recognize several frames of images after a scene change, so even if the display is performed as described above, the effect on the image quality of the images recognized by the viewers is a problem. Must not.
[0165]
Usually, the gradation data of the first display frame and the second display frame is set to the initial gradation L._INIT(L_IN1 frame period is sufficient for the period set to). However, when the response speed of the liquid crystal is slow, the response is not sufficiently completed in one frame period, and the reset effect may not be sufficiently obtained.
[0166]
In such a case, the gradation data of the first display frame and the second display frame is converted into the initial gradation L for the input frame where the scene change is detected over a period of a plurality of frames (usually 2 to 3 frames)._INIT(L_IN). That is, constant gradation data is always displayed during the reset period regardless of the input frame.
[0167]
(Effects of this Embodiment) As described above, the liquid crystal display device of this embodiment can suppress the disturbance of the gamma characteristic that occurs when driven for a long time.
[0168]
【The invention's effect】
According to the present invention, the image quality of a moving image displayed on a liquid crystal display can be improved.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a configuration of a liquid crystal display device according to a first embodiment.
FIG. 2 shows an example of data of a first display frame generation LUT 111 held in a conversion table 102;
FIG. 3 is a diagram for explaining response waveforms of the liquid crystal display device of the first embodiment.
FIG. 4 is a diagram for explaining response waveforms of a liquid crystal display device according to a modification of the first embodiment.
FIG. 5 is a diagram for explaining a relationship between gradation data of an input frame and a change amount of the liquid crystal display device according to the first embodiment.
FIG. 6 is a flowchart for describing processing for calculating a first display frame generation LUT 111 and a second display frame generation LUT 112 used in the liquid crystal display device of the first embodiment.
FIG. 7 shows the quantity (L_INAnd the like).
FIG. 8 is a flowchart for explaining processing for calculating a first display frame generation LUT 111 and a second display frame generation LUT 112 used in a liquid crystal display device according to a modification of the first embodiment.
FIG. 9 is a diagram for explaining response waveforms of a liquid crystal display device according to a modification of the first embodiment.
FIG. 10 is a diagram for explaining response waveforms of a liquid crystal display device according to a modification of the first embodiment.
FIG. 11 is a flowchart for describing processing for calculating a first display frame generation LUT 111 and a second display frame generation LUT 112 used in the liquid crystal display device of the first embodiment.
FIG. 12 is a diagram illustrating a configuration of a liquid crystal display device according to a second embodiment.
[Explanation of symbols]
100 input section
101 frame memory
102 conversion table
103 Display frame generator
104 frame memory
105 Display control unit
106 Liquid crystal display

Claims (8)

An input unit that sequentially inputs each frame of the input video as an input frame;
A delay frame generation unit that generates a delay frame obtained by delaying the input frame by one frame period of the input video;
A conversion data storage unit storing conversion data representing the relationship between the gradation data of the input frame and the gradation data of the delay frame and the gradation data of the two display frames to be actually displayed;
A display frame generation unit configured to generate a first display frame and a second display frame having a higher luminance than the first display frame using the input frame, the delay frame, and the converted data;
A display control unit that outputs the first display frame in the first half of one frame period of the input video and outputs the second display frame in the second half;
A liquid crystal display unit for displaying the first display frame and the second display frame output from the display control unit;
Equipped with a,
The conversion data stored in the conversion data storage unit is:
(A) the luminance of the second display frame is higher than the luminance of the first display frame;
(B) The gradation reached by the liquid crystal display unit after displaying the second display frame is a value uniquely determined from the gradation data of the input frame,
(C) Displaying the first display frame and the second display frame within one frame period of the input video with respect to a value obtained by integrating the change in display gradation in the liquid crystal display unit over one frame period of the input video. The difference between the absolute value difference or the square of the difference between the value when the input frame is displayed and the value when the input frame is displayed for one frame period of the input video is minimized.
Is the conversion data for conversion,
A liquid crystal display device characterized by the above . An input unit that sequentially inputs each frame of the input video as an input frame;
A delay frame generation unit that generates a delay frame obtained by delaying the input frame by one frame period of the input video;
A conversion data storage unit storing conversion data representing the relationship between the gradation data of the input frame and the gradation data of the delay frame and the gradation data of the two display frames to be actually displayed;
A display frame generation unit that generates a first display frame and a second display frame having a lower luminance than the first display frame using the input frame, the delay frame, and the converted data;
A display control unit that outputs the first display frame in the first half of one frame period of the input video and outputs the second display frame in the second half;
A liquid crystal display unit for displaying the first display frame and the second display frame output from the display control unit;
Equipped with a,
The conversion data stored in the conversion data storage unit is:
(A) the luminance of the second display frame is lower than the luminance of the first display frame;
(B) The gradation reached by the liquid crystal display unit after displaying the second display frame is a value uniquely determined from the gradation data of the input frame,
(C) Displaying the first display frame and the second display frame within one frame period of the input video with respect to a value obtained by integrating the change in display gradation in the liquid crystal display unit over one frame period of the input video. The difference between the absolute value difference or the square of the difference between the value when the input frame is displayed and the value when the input frame is displayed for one frame period of the input video is minimized.
Is the conversion data for conversion,
A liquid crystal display device characterized by the above . The conversion data stored in the conversion data storage unit is:
When the first display frame of the tone data and the second display frame maximum gradation is smaller than both of the gradation data of large liquid crystal display unit than 0, floors the arrival gradation of the input frame It is conversion data for converting to a value uniquely determined from the key data,
The liquid crystal display device according to claim 1 . A scene change detector for detecting a scene change in the input video;
The display frame generation unit
When a scene change is detected, both the gradation data of the first display frame and the gradation data of the second display frame are set to the reached gradation value.
The liquid crystal display device according to any one of claims 1 to 3. An input step of sequentially inputting each frame of the input video as an input frame;
A delay frame generation step of generating a delay frame obtained by delaying the input frame by one frame period of the input video;
Using the conversion data representing the relationship between the gradation data of the input frame and the gradation data of the delay frame and the gradation data of the two display frames to be actually displayed, the input frame, and the delay frame, the first A display frame generating step for generating a display frame and a second display frame having a higher luminance than the first display frame;
A display step of displaying the first display frame on the liquid crystal display unit in the first half of one frame period of the input video and displaying the second display frame on the liquid crystal display unit in the second half;
Equipped with a,
The converted data is
(A) the luminance of the second display frame is higher than the luminance of the first display frame;
(B) The gradation reached by the liquid crystal display unit after displaying the second display frame is a value uniquely determined from the gradation data of the input frame,
(C) Displaying the first display frame and the second display frame within one frame period of the input video with respect to a value obtained by integrating the change in display gradation in the liquid crystal display unit over one frame period of the input video. The difference between the absolute value difference or the square of the difference between the value when the input frame is displayed and the value when the input frame is displayed for one frame period of the input video is minimized.
Is the conversion data for conversion,
A liquid crystal display method characterized by the above . An input step of sequentially inputting each frame of the input video as an input frame;
A delay frame generation step of generating a delay frame obtained by delaying the input frame by one frame period of the input video;
Using the conversion data representing the relationship between the gradation data of the input frame and the gradation data of the delay frame and the gradation data of the two display frames to be actually displayed, the input frame, and the delay frame, the first Generating a display frame and a second display frame having a lower luminance than the first display frame;
A display step of displaying the first display frame on the liquid crystal display unit in the first half of one frame period of the input video and displaying the second display frame on the liquid crystal display unit in the second half;
Equipped with a,
The converted data is
(A) the luminance of the second display frame is lower than the luminance of the first display frame;
(B) The gradation reached by the liquid crystal display unit after displaying the second display frame is a value uniquely determined from the gradation data of the input frame,
(C) Displaying the first display frame and the second display frame within one frame period of the input video with respect to a value obtained by integrating the change in display gradation in the liquid crystal display unit over one frame period of the input video. The difference between the absolute value difference or the square of the difference between the value when the input frame is displayed and the value when the input frame is displayed for one frame period of the input video is minimized.
Is the conversion data for conversion,
A liquid crystal display method characterized by the above . The converted data is
When the first display frame of the tone data and the second display frame maximum gradation is smaller than both of the gradation data of large liquid crystal display unit than 0, floors the arrival gradation of the input frame It is conversion data for converting to a value uniquely determined from the key data,
The liquid crystal display method according to claim 5 . A scene change detection step for detecting a scene change in the input video;
In the display frame generation step,
When a scene change is detected, both the gradation data of the first display frame and the gradation data of the second display frame are set to the reached gradation value.
The liquid crystal display method according to any one of claims 5 to 7 .

Images