JP2013167846A - Display control device, display control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique to reduce influences on the definition of a displayed image and improve view angle characteristics.SOLUTION: There is provided a display control device including a display control unit that classifies an input pixel into a high-luminance pixel frame having higher luminance than the input pixel and plural low-luminance pixel frames having lower luminance than the input pixel, and causes each of the high-luminance pixel frame and plural low-luminance pixel frames to be displayed continuously in a display element.

Description

  The present disclosure relates to a display control device, a display control method, and a program.

  Patent Documents 1 and 2 disclose techniques for improving viewing angle characteristics of a liquid crystal display panel.

JP 2009-187033 A JP 2009-223345 A

  However, the technique disclosed in Patent Document 1 has a small effect of improving the viewing angle characteristics. On the other hand, with the technique disclosed in Patent Document 2, the resolution of the display image is reduced. For this reason, a technique capable of reducing the influence on the resolution of the display image and improving the viewing angle characteristic has been desired.

  According to the present disclosure, an input pixel is divided into a high-luminance pixel frame having a higher luminance than the input pixel and a low-luminance pixel frame having a lower luminance than the input pixel, and each of the high-luminance pixel frame and the low-luminance pixel frame is a plurality of frames. A display control device is provided that includes a display control unit that continuously displays on a display element one by one.

  According to the present disclosure, an input pixel is divided into a high-luminance pixel frame having a higher luminance than the input pixel and a low-luminance pixel frame having a lower luminance than the input pixel, and each of the high-luminance pixel frame and the low-luminance pixel frame is a plurality of frames. There is provided a display control method including continuously displaying on a display element one by one.

  According to the present disclosure, the computer divides an input pixel into a high-luminance pixel frame having a higher luminance than the input pixel and a low-luminance pixel frame having a lower luminance than the input pixel, and each of the high-luminance pixel frame and the low-luminance pixel frame. There is provided a program that realizes a display control function for continuously displaying a plurality of frames on a display element.

  According to the present disclosure, each of the high luminance pixel frame and the low luminance pixel frame can be continuously displayed on the display element by a plurality of frames.

  As described above, according to the present disclosure, the display control unit can more surely match the displayable luminance of the display element with the desired luminance, and can lengthen the time for these to match. Therefore, according to the present disclosure, the viewing angle characteristics can be improved. Furthermore, according to the present disclosure, since the input pixel can be displayed on one display element, the influence on the resolution can be reduced.

It is a block diagram which shows the structure of the display control apparatus which concerns on embodiment of this indication. It is a graph which shows the example of a drive of the liquid crystal display panel by a display control apparatus. It is explanatory drawing which shows the example of a drive of the liquid crystal display panel by a display control apparatus. It is a flowchart which shows the procedure of the process by a display control apparatus. It is explanatory drawing which shows the example of the look-up table referred by the display control apparatus. It is explanatory drawing which shows the example of a drive of the liquid crystal display panel by a display control apparatus. It is explanatory drawing which shows the example of a drive of the liquid crystal display panel by a display control apparatus. It is explanatory drawing which shows the example of a drive of the liquid crystal display panel by a display control apparatus. It is explanatory drawing which shows the example of a drive of the liquid crystal display panel by a display control apparatus. It is explanatory drawing which shows the drive example by the other drive method of a liquid crystal display panel. It is explanatory drawing which shows the drive example by the other drive method of a liquid crystal display panel. It is explanatory drawing which shows the drive example by the other drive method of a liquid crystal display panel.

  Hereinafter, preferred embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

The description will be made in the following order.
1. 1. Configuration of display control device 2. Configuration of display control unit 3. Consideration on driving method of liquid crystal display panel Processing Procedure by Display Control Device In the following description, “A to B” means “A or more and less than B”.

<1. Configuration of display control device>
First, based on FIG. 1, the structure of the display control apparatus 1 which concerns on this embodiment is demonstrated. The display control device 1 includes a data driver 30, a gate driver 40, a temperature sensor 50, and a display control unit 60. The display control device 1 is connected to a liquid crystal display panel 10 and a backlight 20, and the display control device 1, the liquid crystal display panel 10, and the backlight 20 constitute a liquid crystal display device.

  The display control unit 60 is realized by various hardware configurations such as a CPU, a ROM, a RAM, and the like. That is, a program for realizing each functional block of the display control unit 60 is recorded in the ROM, and the CPU reads and executes the program. Thereby, each functional block of the display control unit 60 is realized.

  The liquid crystal display panel 10 is, for example, an active matrix type liquid crystal display panel, but may be other types. As shown in FIG. 3, the liquid crystal display panel 10 includes a plurality of display elements 11 arranged in a matrix. Each display element 11 is either a red display element 11R that displays red, a green display element 11G that displays green, or a blue display element 11B that displays blue. In the vertical direction, display elements 11 of the same color are arranged. In the horizontal direction, the display elements 11 are arranged in the order of red, green, and blue.

  Each display element 11 generally includes a TFT (Thin Film Transistor), a pixel electrode, a common electrode, a liquid crystal layer, and a Cs electrode. The TFT and each electrode are provided on a substrate sandwiching the liquid crystal layer. The TFT has a source connected to the data bus line 31, a gate connected to the gate bus line 41, and a drain connected to the pixel electrode. The liquid crystal layer is disposed between the pixel electrode and the common electrode. By supplying a data driving voltage and a gate driving voltage from the data driver 30 and the gate driver 40, respectively, a voltage (hereinafter also referred to as a response voltage) is generated between the pixel electrode and the common electrode. The orientation of the layer changes. The Cs electrode is for holding the charge of the pixel electrode. The luminance of each display element 11 is controlled by the absolute value of the response voltage. That is, the greater the absolute value of the response voltage, the greater the luminance.

  Even when the data driving voltage and the gate driving voltage are applied to the display element 11, the response voltage does not immediately become the target voltage (for example, the data driving voltage), but gradually increases to the target voltage as time elapses. Get closer. The time from when the drive voltage is applied to the display element until the response voltage matches the target voltage, that is, the response time depends on the characteristics of the liquid crystal display panel 10 and the temperature of the display element 11 (specifically, the temperature of the liquid crystal layer). ) And so on. In this embodiment, paying attention to the response time of the display element 11, pixel frames having the same luminance are continuously displayed on the display element 11. Details will be described later.

  The backlight 20 illuminates the liquid crystal display panel 10 from behind. In the present embodiment, the backlight 20 is turned on in the second half of a continuous pixel frame. Details will be described later. The data driver 30 supplies a drive voltage, that is, a data drive voltage, to the display element 11 through the data bus line 31. The gate driver 40 supplies a driving voltage, that is, a gate driving voltage to the display element 11 through the gate bus line 41. The temperature sensor 50 is provided on the substrate of the liquid crystal display panel 10 and measures the temperature of the substrate. Then, the temperature sensor 50 outputs measurement value information regarding the measurement value to the display control unit 60. As will be described later, the liquid crystal layer temperature is a parameter for determining the number of bright and dark frames and the backlight lighting width. Therefore, it is preferable to directly measure the liquid crystal layer temperature, but it is not easy to directly measure the liquid crystal layer temperature. Therefore, in this embodiment, the temperature of the substrate adjacent to the liquid crystal layer is measured. Note that the measurement value information is corrected by the display control unit 60 to be a value that substantially matches the liquid crystal layer temperature.

  The display control unit 60 includes an image processing unit 61, a storage unit 62, a timing control unit 63, and a backlight control unit 64. The image processing unit 61 acquires an input image. On the other hand, the image processing unit 61 calculates the liquid crystal layer temperature by multiplying the measurement value information by a correction coefficient (for example, offset and gain).

  Since the temperature sensor 50 measures the substrate temperature, the measured value does not exactly match the liquid crystal layer temperature. However, since there is a certain relationship between the substrate temperature and the liquid crystal layer temperature, it is possible to predict the liquid crystal layer temperature from the substrate temperature. Therefore, in the present embodiment, the liquid crystal layer temperature is calculated by multiplying the measurement value information, that is, the substrate temperature, by the correction coefficient.

  Then, the image processing unit 61 divides each pixel constituting the input image, that is, the input pixel, into a high luminance pixel frame having a higher luminance than the input pixel and a low luminance pixel frame having a lower luminance than the input pixel. Then, the image processing unit 61 determines the number of high-luminance pixel frames and low-luminance pixel frames based on the liquid crystal layer temperature and a lookup table described later.

  Here, the number of high-luminance pixel frames and low-luminance pixel frames are both 2 or more. The total number of high-luminance pixel frames and low-luminance pixel frames is n1 (n1 is an integer of 4 or more). Although the value of n1 is arbitrary, it will be 4-8, for example. Hereinafter, of the high-luminance pixel frame and the low-luminance pixel frame, the pixel frame displayed on the display element 11 at the k-th (k is an integer of 1 to n1) is also referred to as “frame k”. Further, the high luminance pixel frame is also simply referred to as “bright”, and the low luminance pixel frame is also simply referred to as “dark”. The arithmetic average value of the luminance of the high luminance pixel frame and the luminance of the low luminance pixel frame matches the luminance of the input pixel. The difference between the luminance of the high luminance pixel frame and the luminance of the low luminance pixel frame is preferably as large as possible. This is because the larger the difference, the greater the effect of improving the viewing angle characteristics. When the luminance of the input pixel becomes the maximum value (maximum value that can be displayed by the liquid crystal display panel 10), the luminance of the high luminance pixel frame and the luminance of the low luminance pixel frame are both equal to the maximum value.

  Further, the image processing unit 61 determines the display time of one pixel frame. The display time of one pixel frame is a value obtained by dividing the frame interval of an input image (the time from when a certain input image is given until the next input image is given) by n1. For example, when the frame interval of the input image is 1/60 (sec), the display time of one pixel frame is 1 / (60 × n1) (sec).

  Then, the image processing unit 61 determines the display order of the high luminance pixel frame and the low luminance pixel frame for each display element 11. Here, the image processing unit 61 sets the display order so that each of the high-luminance pixel frame and the low-luminance pixel frame is continuously displayed on the display element 11 by a plurality of frames. Hereinafter, the time during which the high luminance pixel frame is displayed on the display element 11 is referred to as high luminance pixel frame display time, and the time during which the low luminance pixel frame is displayed on the display element 11 is also referred to as low luminance pixel frame display time.

  An example of the display order will be described with reference to FIG. FIG. 2 shows a correspondence relationship between the display order and the displayable luminance of the display element 11. The horizontal axis in FIG. 2 indicates time, and the vertical axis indicates the response voltage of the display element 11 as displayable luminance of the display element 11. Here, the displayable luminance indicates the luminance that can be displayed by the display element 11. That is, the display element 11 displays pixels with displayable luminance when illuminated by the backlight 20. According to FIG. 2, frames 1 to 4 are displayed at times 0 to t1, t1 to t2, t2 to t3, and t3 to t4, respectively. Th1 indicates the luminance of the high luminance pixel frame, and Th2 indicates the luminance of the low luminance pixel frame. The graph L1 shows the displayable luminance of the display element 11 at each time, that is, the response waveform of the display element 11.

  In the example shown in FIG. 2, the display order is “bright”, “bright”, “dark”, “dark”. Therefore, the high luminance pixel frame display time is from time 0 to t2, and the low luminance pixel frame display time is from time t2 to t4. Further, the response time of the display element 11 substantially matches the display time of one pixel frame. Therefore, the displayable luminance in the latter half of the high-luminance pixel frame display time, that is, the frame 2, coincides with the luminance Th1 of the high-luminance pixel frame. Similarly, the displayable brightness in the second half of the low-luminance pixel frame display time, that is, the frame 4, matches the brightness Th2 of the low-luminance pixel frame. Therefore, in the present embodiment, the displayable luminance of the display element 11 can be matched with the luminance of each pixel frame.

  As shown in FIG. 2, since the response time substantially matches the display time of one pixel frame, in the first half of the high-luminance pixel frame display time and the low-luminance pixel frame display time, that is, in frames 1 and 3, The displayable brightness does not match the brightness of each pixel frame. Therefore, the image processing unit 61 sets a lighting schedule for the backlight 20 so that the backlight 20 is lit in the latter half of the high luminance pixel frame display time and the low luminance pixel frame display time. The lighting schedule indicates the lighting start time and lighting end time of the backlight 20. The lighting start time is a time before the end time of each display time by the backlight lighting width, and the backlight lighting end time coincides with the end time of each display time. The backlight lighting width is defined in a look-up table described later, and becomes longer as the liquid crystal layer temperature is higher.

  In this example, the image processing unit 61 sets a lighting schedule so that the backlight 20 is turned on at frames 2 and 4. The backlight control unit 63 lights the backlight 20 according to the lighting schedule. That is, the backlight control unit 63 blinks the backlight 20. Thereby, this embodiment can display the brightness | luminance of a high-intensity pixel frame, and the brightness | luminance of a low-intensity pixel frame. Note that the image processing unit 61 may set the lighting schedule only for some display elements 11 of the liquid crystal display panel 10.

  Further, the image processing unit 61 displays the display order of the display elements 11 so that the number of display elements 11 that display the high-luminance pixel frame is equal to the number of display elements 11 that display the low-luminance pixel frame at each time point. Set. For example, the image processing unit 61 sets the display order of half of the display elements 11 constituting the liquid crystal display panel 10 to “bright”, “bright”, “dark”, “dark”, and the remaining half of the display elements 11 The display order for the display element 11 is “dark”, “dark”, “bright”, and “bright”. An example of this processing is shown in FIG. In this example, the display elements 11 in the first and third rows are driven in the display order of “dark”, “dark”, “bright”, and “bright”, and the display elements 11 in the second and fourth rows are driven. Drive in the display order of “bright”, “bright”, “dark”, “dark”. In the present embodiment, the luminance classification (high luminance or low luminance classification) is indicated by the presence or absence of hatching.

  The image processing unit 61 sets a display schedule regarding the display order and the display time of one pixel frame, and outputs the display schedule to the timing control unit 64. Further, the image processing unit 61 outputs the lighting schedule to the backlight control unit 63. On the other hand, the image processing unit 61 stores the display schedule and the lighting schedule in the storage unit 62.

  The storage unit 62 stores various information necessary for processing by the display control unit 60, such as a program, a correction coefficient, an input image counter, and a lookup table. The input image counter is incremented by 1 every time the image processing unit 61 acquires an input image. The lookup table records the liquid crystal layer temperature range, the number of bright and dark frames, and the backlight lighting width in association with each other. The image processing unit 61 determines the number of bright and dark frames and the backlight lighting width corresponding to the current liquid crystal layer temperature based on the lookup table. Then, the image processing unit 61 sets the above-described display schedule and lighting schedule based on the number of bright and dark frames and the backlight lighting width.

  FIG. 5 shows an example of a lookup table. This lookup table is used when the display time of one pixel frame is 1/480 (sec) (n1 = 8, frame interval of input image = 1/60 (sec)).

  In the lookup table shown in FIG. 5, the liquid crystal layer temperature range is set in increments of 10 degrees. However, the step size of the liquid crystal layer temperature range is arbitrarily adjusted according to the characteristics of the liquid crystal display panel 10. For example, as the temperature dependency of the liquid crystal display panel 10 is larger, the step size of the liquid crystal layer temperature range is preferably narrower. Further, as described above, since there is a certain relationship between the liquid crystal layer temperature and the substrate temperature, the substrate temperature range, the number of bright and dark frames, and the backlight lighting width may be associated with each other in the lookup table. . In this case, the image processing unit 61 can use the measurement value information as it is.

  The number of bright and dark frames indicates the number of high luminance pixel frames (bright) and the number of low luminance pixel frames (dark). In other words, the number of bright and dark frames indicates a ratio between the number of high-luminance pixel frames and the number of low-luminance pixel frames. When the temperature is low, the number of low-luminance pixel frames is larger, and when the temperature is high, these numbers are equal. Therefore, this look-up table corresponds to the liquid crystal display panel 10 whose response speed at the low temperature is slower than the response speed at the high temperature.

  That is, depending on the characteristics of the liquid crystal display panel 10, the response speed of the display element 11 at the time of falling (transition from high luminance to low luminance) and the response of the display element 11 at the time of rising (transition from low luminance to high luminance) There may be a difference in speed. Therefore, in the present embodiment, when the response speed at the time of falling is slower, the number of low-luminance pixel frames is made larger than that of high-luminance pixel frames. As a result, the display time of the low-luminance pixel frame becomes longer, and the displayable luminance of the display element 11 can reach the luminance of the low-luminance pixel frame more reliably. That is, the viewing angle improvement effect is increased. Similarly, when the response speed at the time of rising is slower, the number of bright and dark frames is set so that the number of high luminance pixel frames is larger than the number of low luminance pixel frames. That is, the number of bright and dark frames is determined according to the characteristics of the liquid crystal display panel 10. The response speed of the display element 11 depends on the liquid crystal layer temperature. As the liquid crystal layer temperature increases, the temperature dependence of the response speed decreases, so the number of low-luminance pixel frames and the number of high-luminance pixel frames may be the same. In addition, the value of the number of bright and dark frames varies depending on the value of n1. Specifically, the ratio between the number of high-luminance pixel frames and the number of low-luminance pixel frames does not change, and these numbers vary. As the value of n1 is larger, more accurate display control is possible.

  The backlight lighting width (backlight lighting time) is set for each of the high luminance pixel frame display time and the low luminance pixel frame display time. The response speed of the display element 11 depends on the temperature, and is faster at high temperatures and slower at low temperatures. For this reason, it takes time for the displayable luminance to reach the desired luminance at low temperatures. On the other hand, if the backlight 20 is turned on before the displayable luminance reaches the desired luminance, the effect of improving the viewing angle is reduced. Therefore, in this embodiment, the lighting width is shortened at low temperatures. On the other hand, since the displayable luminance reaches the desired luminance in a short time at a high temperature, the lighting width of the backlight 20 is increased in this embodiment. Thus, in this embodiment, since the backlight lighting width is changed according to the liquid crystal layer temperature, the viewing angle characteristics can be greatly improved. Of course, the backlight lighting width shown in FIG. 5 is an example, and is arbitrarily set according to the characteristics of the liquid crystal display panel 10.

  Examples of display schedules and lighting schedules set based on the lookup table shown in FIG. 5 are shown in FIGS. The meanings of the horizontal axis, the vertical axis, and the graph L1 in FIGS. 6 to 9 are the same as those in FIG. Also, the frame interval of the input image is assumed to be 1/60 (sec).

  When the liquid crystal layer temperature is less than 10 degrees, the image processing unit 61 sets the display schedule and lighting schedule shown in FIG. Specifically, the image processing unit 61 sets the frames 1 to 3 as high-luminance pixel frames, the frames 4 to 8 as low-luminance pixel frames, and sets the display time of one pixel frame to 1/480 (sec). Furthermore, the image processing unit 61 sets the start times of the frames 3 and 8 as lighting start times, and sets the end times of the frames 3 and 8 as lighting end times.

  Similarly, when the liquid crystal layer temperature is 10 to 20 degrees, the image processing unit 61 sets the display schedule and lighting schedule shown in FIG. Specifically, the image processing unit 61 sets the frames 1 to 3 as high-luminance pixel frames, the frames 4 to 8 as low-luminance pixel frames, and sets the display time of one pixel frame to 1/480 (sec). Further, the image processing unit 61 sets the start times of frames 2 and 7 as lighting start times, and sets the end times of frames 3 and 8 as lighting end times.

  Similarly, when the liquid crystal layer temperature is 20 to 30 degrees, the image processing unit 61 sets the display schedule and lighting schedule shown in FIG. Specifically, the image processing unit 61 sets the frames 1 to 4 as high luminance pixel frames, the frames 5 to 8 as low luminance pixel frames, and sets the display time of one pixel frame to 1/480 (sec). Further, the image processing unit 61 sets the intermediate times of the frames 2 and 6 as lighting start times, and sets the end times of the frames 4 and 8 as lighting end times, respectively.

  Similarly, the image processing unit 61 sets the display schedule and lighting schedule shown in FIG. 9 when the liquid crystal layer temperature is 30 degrees or higher. Specifically, the image processing unit 61 sets the frames 1 to 4 as high luminance pixel frames, the frames 5 to 8 as low luminance pixel frames, and sets the display time of one pixel frame to 1/480 (sec). Furthermore, the image processing unit 61 sets the start times of frames 2 and 6 as lighting start times, and sets the end times of frames 4 and 8 as lighting end times.

  Note that the image processing unit 61 sets the schedule shown in FIGS. 6 to 9 for half of the display elements 11 of all the display elements 11 of the liquid crystal display panel 10, and contrasts for the remaining half of the display elements 11. Set a schedule that reverses the order.

  The backlight controller 63 blinks the backlight 20 based on the lighting schedule. The timing control unit 64 controls the data driver 30 and the gate driver 40 based on the display schedule. The data driver 30 supplies a high luminance data drive voltage to the display element 11 that displays the high luminance pixel frame, and low luminance for the display element 11 that displays the low luminance pixel frame. Supply data drive voltage.

<3. Consideration about the driving method of the liquid crystal display panel ＞
As described above, the display control unit 60 causes the display element 11 to continuously display each of the high-luminance pixel frame and the low-luminance pixel frame by a plurality of frames. Furthermore, the display control unit 60 equalizes the number of display elements 11 that display a high-luminance pixel frame and the number of display elements 11 that display a low-luminance pixel frame at each time point (each pixel frame). Further, the display control unit 60 turns on the backlight 20 in the latter half of the high luminance pixel frame display time and the low luminance pixel frame display time. The reason why the display control unit 60 performs such processing will be described in comparison with various driving methods for the purpose of improving the viewing angle characteristics of the liquid crystal display panel.

  As one of driving methods of the liquid crystal display panel 10, a method of time-dividing input pixels has been proposed. This driving method also divides an input pixel into a high luminance pixel frame and a low luminance pixel frame. However, in this driving method, the display order is set so that the high luminance pixel frame and the low luminance pixel frame are alternately displayed for each pixel frame. An example of the display order is shown in FIG. The meanings of the horizontal axis, vertical axis, and graph L1 in FIG. 10 are the same as those shown in FIG. As shown in FIG. 10, the high-luminance pixel frame and the low-luminance pixel frame are repeatedly displayed for each frame. However, in this driving method, the displayable luminance of the display element 11 hardly matches the desired luminance (that is, the luminance of the high luminance pixel frame or the luminance of the low luminance pixel frame). In other words, the difference between the displayable luminance of the display element 11 and the desired luminance becomes very large. Further, in this driving method, when the response time is longer than the display time of one pixel frame, the displayable luminance cannot be matched with the desired luminance.

  Furthermore, in this driving method, as shown in FIG. 12, since all the display elements 11 display pixels of the same luminance division (high luminance or low luminance) at each time point, the user visually recognizes flicker. . Flicker is not completely eliminated even if the display time of one pixel frame is shortened.

  On the other hand, as a method for driving the liquid crystal display panel 10, a method of spatially dividing an input pixel has been proposed. In this driving method, a unit element including a plurality of display pixels 11 is set, and each display element 11 in the unit element is set as a high luminance display pixel or a low luminance display pixel. In this driving method, an input pixel is displayed using a unit element. FIG. 11 shows an example of this driving method. In this example, the unit element 12 is set by the upper and lower display elements 11. In this driving method, since one input pixel is displayed by the plurality of display elements 11, the resolution is lowered. For example, in the example shown in FIG. 11, since one input pixel is displayed by the two display elements 11, the resolution of the liquid crystal display panel 10 is reduced to ½.

  Therefore, the display control unit 60 causes the display element 11 to display each of the high-luminance pixel frame and the low-luminance pixel frame continuously in a plurality of frames. Thereby, the display control part 60 can match | combine displayable brightness | luminance and desired brightness | luminance more reliably, and can lengthen time for these to correspond. Further, the display control unit 60 equalizes the number of display elements 11 that display the high-luminance pixel frame and the number of display elements 11 that display the low-luminance pixel frame at each time point, so that the average luminance at each time point is substantially reduced. Match. Thereby, flicker is reduced. Further, the display control unit 60 turns on the backlight 20 in the latter half of the high luminance pixel frame display time and the low luminance pixel frame display time. Accordingly, the display control unit 60 can turn on the backlight 20 when the displayable luminance matches the desired luminance, so that the desired luminance can be displayed more reliably. Furthermore, since one unit element 11 displays one input pixel, the resolution of the liquid crystal display panel 10 is maintained.

<4. Procedure of processing by display control device>
Next, a processing procedure by the display control apparatus 1 will be described with reference to a flowchart shown in FIG. In step S10, the image processing unit 61 acquires an input image and increments the value of the input image counter by one. Next, the image processing unit 61 determines the display time of one pixel frame based on the frame interval of the input image.

  Next, the image processing unit 61 determines whether or not the value of the input image counter is n2 or more. If it is determined that the value of the input image counter is n2, the image processing unit 61 proceeds to step S20, and if it is determined that the value of the input image counter is less than n2, the process proceeds to step S70. That is, the image processing unit 61 resets the display schedule and the lighting schedule at regular intervals. The value of n2 is set according to the characteristics of the liquid crystal display panel and the time from the start of driving of the liquid crystal display panel 10. For example, since the temperature fluctuation of the liquid crystal layer is severe immediately after the liquid crystal display panel 10 is turned on, n2 is set to a small value. On the other hand, after about 30 minutes have elapsed since the liquid crystal display panel 10 was turned on, the liquid crystal layer temperature is saturated at a predetermined value, so the value of n2 is set to a large value. For example, the image processing unit 61 resets the schedule at intervals of several tens of seconds immediately after the liquid crystal display panel 10 is turned on, and after about 30 minutes from the power on of the liquid crystal display panel 10, the image processing unit 61 sets the schedule at intervals of several minutes. Just reset it.

  In step S <b> 20, the image processing unit 61 acquires measurement value information from the temperature sensor 50. In step S30, the image processing unit 61 calculates the liquid crystal layer temperature by multiplying the measurement value information by a correction coefficient. In step S40, the image processing unit 61 determines (selects) the number of bright and dark frames corresponding to the liquid crystal layer temperature based on the lookup table shown in FIG. In step S50, the image processing unit 61 determines (selects) the backlight lighting width corresponding to the liquid crystal layer temperature based on the lookup table shown in FIG.

  In step S60, the image processing unit 61 sets a display schedule and a lighting schedule based on the number of bright and dark frames and the backlight lighting width. The specific setting method is as described above. The image processing unit 61 stores these schedules in the storage unit 62.

  In step S <b> 70, the image processing unit 61 acquires a display schedule from the storage unit 62 and outputs the display schedule to the timing control unit 64. The timing control unit 64 controls the data driver 30 and the gate driver 40 based on the display schedule. On the other hand, the image processing unit 61 acquires a lighting schedule from the storage unit 62 and outputs it to the backlight control unit 63. The backlight controller 63 blinks the backlight 20 based on the lighting schedule. Thereafter, the image processing unit 61 ends the process.

  As described above, in the present embodiment, the display control device 1 divides the input pixel into the high-luminance pixel frame and the low-luminance pixel frame, and each of the high-luminance pixel frame and the low-luminance pixel frame is continuously displayed in a plurality of frames. 11 is displayed. Therefore, the display control device 1 can more reliably match the displayable luminance of the display element 11 with the desired luminance, and can lengthen the time for these to match. Therefore, the display control device 1 can improve the viewing angle characteristics. Furthermore, since the display control apparatus 1 can display one input pixel on one display element, the influence on the resolution can be reduced.

  Note that a VA (vertical alignment) type liquid crystal display panel tends to have inferior viewing angle characteristics than an IPS (in-plane switching) type liquid crystal display panel. Therefore, when this embodiment is applied to a VA type liquid crystal display panel, it is expected that the viewing angle characteristic is greatly improved.

  Further, the display control device 1 makes the number of display elements 11 that display a high-luminance pixel frame equal to the number of display elements 11 that display a low-luminance pixel frame at each time point, so that flicker can be reduced.

  Further, the display control device 1 adjusts the ratio between the number of high-luminance pixel frames and the number of low-luminance pixel frames based on the temperature of the display element 11, specifically, the liquid crystal layer temperature. Therefore, the display control device 1 can more reliably match the displayable luminance of the display element 11 with the desired luminance, and can lengthen the time for these to match.

  Furthermore, the display control apparatus 1 brings the ratio of the number of low-luminance pixel frames to the number of high-luminance pixel frames closer to 1 as the temperature of the display element 11 is higher. Therefore, the display control device 1 can more reliably match the displayable luminance of the display element 11 with the desired luminance, and can lengthen the time for these to match.

  Further, the display control device 1 includes the backlight 20 of the display element in the latter half of at least one of the time during which the high luminance pixel frame is displayed on the display element and the time during which the low luminance pixel frame is displayed on the display element. Lights up. Therefore, the display control device 1 can display a desired luminance.

  Furthermore, since the display control apparatus 1 adjusts the lighting time of the backlight 20 based on the temperature of the display element 11, it can display desired luminance more reliably.

  Furthermore, since the display control device 1 increases the lighting time of the backlight 20 as the temperature of the display element 11 is higher, it can display the desired luminance more reliably.

  The preferred embodiments of the present disclosure have been described in detail above with reference to the accompanying drawings, but the technical scope of the present disclosure is not limited to such examples. It is obvious that a person having ordinary knowledge in the technical field of the present disclosure can come up with various changes or modifications within the scope of the technical idea described in the claims. Of course, it is understood that it belongs to the technical scope of the present disclosure.

The following configurations also belong to the technical scope of the present disclosure.
(1)
The input pixel is divided into a high-brightness pixel frame having a higher brightness than the input pixel and a low-brightness pixel frame having a lower brightness than the input pixel, and each of the high-brightness pixel frame and the low-brightness pixel frame is consecutively framed. And a display control device including a display control unit for displaying on the display element.
(2)
The display control device according to (1), wherein the display control unit equalizes the number of display elements that display the high-luminance pixel frame and the number of display elements that display the low-luminance pixel frame at each time point.
(3)
The display control device according to (1) or (2), wherein the display control unit adjusts a ratio between the number of the high luminance pixel frames and the number of the low luminance pixel frames based on the temperature of the display element. .
(4)
The display control device according to (3), wherein the display control unit brings the ratio of the number of the low luminance pixel frames to the number of the high luminance pixel frames closer to 1 as the temperature of the display element is higher.
(5)
The display control unit is configured to display the display element at a second half of at least one of a time during which the high luminance pixel frame is displayed on the display element and a time during which the low luminance pixel frame is displayed on the display element. The display control apparatus according to any one of (1) to (4), wherein a backlight is turned on.
(6)
The display control device according to (5), wherein the display control unit adjusts a lighting time of the backlight based on a temperature of the display element.
(7)
The display control device according to (6), wherein the display control unit increases a lighting time of the backlight as the temperature of the display element is higher.
(8)
The input pixel is divided into a high-brightness pixel frame having a higher brightness than the input pixel and a low-brightness pixel frame having a lower brightness than the input pixel, and each of the high-brightness pixel frame and the low-brightness pixel frame is consecutively framed. Display control method including displaying on the display element.
(9)
On the computer,
The input pixel is divided into a high-brightness pixel frame having a higher brightness than the input pixel and a low-brightness pixel frame having a lower brightness than the input pixel, and each of the high-brightness pixel frame and the low-brightness pixel frame is consecutively framed. Program for realizing the display control function to be displayed on the display element.

DESCRIPTION OF SYMBOLS 1 Display control apparatus 10 Liquid crystal display panel 20 Backlight 30 Data driver 40 Gate driver 50 Temperature sensor 60 Display control part 61 Image processing part 62 Storage part 63 Backlight control part 64 Timing control part

Claims (9)

  The input pixel is divided into a high-brightness pixel frame having a higher brightness than the input pixel and a low-brightness pixel frame having a lower brightness than the input pixel, and each of the high-brightness pixel frame and the low-brightness pixel frame is consecutively framed. And a display control device including a display control unit for displaying on the display element.   The display control device according to claim 1, wherein the display control unit equalizes the number of display elements that display the high-luminance pixel frame and the number of display elements that display the low-luminance pixel frame at each time point.   The display control apparatus according to claim 1, wherein the display control unit adjusts a ratio between the number of the high luminance pixel frames and the number of the low luminance pixel frames based on a temperature of the display element.   The display control device according to claim 3, wherein the display control unit brings a ratio of the number of the low-luminance pixel frames to the number of the high-luminance pixel frames closer to 1 as the temperature of the display element is higher.   The display control unit is configured to display the display element at a second half of at least one of a time during which the high luminance pixel frame is displayed on the display element and a time during which the low luminance pixel frame is displayed on the display element. The display control device according to claim 1, wherein the backlight is turned on.   The display control apparatus according to claim 5, wherein the display control unit adjusts a lighting time of the backlight based on a temperature of the display element.   The display control device according to claim 6, wherein the display control unit increases the lighting time of the backlight as the temperature of the display element increases.   The input pixel is divided into a high-brightness pixel frame having a higher brightness than the input pixel and a low-brightness pixel frame having a lower brightness than the input pixel, and each of the high-brightness pixel frame and the low-brightness pixel frame is consecutively framed. Display control method including displaying on the display element. On the computer,
The input pixel is divided into a high-brightness pixel frame having a higher brightness than the input pixel and a low-brightness pixel frame having a lower brightness than the input pixel, and each of the high-brightness pixel frame and the low-brightness pixel frame is consecutively framed. Program for realizing the display control function to be displayed on the display element.

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