JP2015148719A - Liquid crystal display device and driving method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display device capable of performing overdrive while achieving a PSR(Panel Self Refresh) function and visual field angle improvement processing and a driving method.SOLUTION: A liquid crystal display device includes: a storage part for storing time-sequentially input gradation data in order of frames; a first pattern generation part for, when a first display system for performing image display based on the input gradation data is selected, generating a gradation pattern determining a target gradation value from the input gradation data of frame units, and for stopping the input of the gradation data, and for, when a second display system for performing image display based on the gradation data stored in the storage part is selected, generating a gradation pattern determining the target gradation value from the gradation data of frame units stored in the storage part; a second pattern generation part for generating a reference pattern from the gradation data stored in the storage part; and a driving part for, on the basis of the generated gradation patterns and the generated reference pattern, performing overdrive for shortening a response time of liquid crystal on a liquid crystal panel.

Description

  The present invention relates to a liquid crystal display device and a driving method capable of overdrive while realizing a PSR function and a viewing angle improvement process.

  In recent years, liquid crystal display devices that have realized viewing angle improvement processing and overshoot processing have been proposed (see, for example, Patent Document 1).

  In the viewing angle improvement processing, for example, in a liquid crystal display panel, high gradation display and low gradation display are performed on adjacent pixels, and high gradation display and low gradation display are switched for each display frame. By adopting such a configuration, in each display frame, even when each pixel is viewed from an oblique direction, the gradation and color are converted into gradations that are not easily changed. As a result, the liquid crystal display panel Viewing angle characteristics can be improved.

  The overshoot process is a technique for improving the response speed of the liquid crystal by raising the drive voltage of the liquid crystal slightly (or slightly lowering) the original drive voltage when the image to be displayed changes. In the overshoot process, when displaying the current frame image, the target gradation value is determined by referring to the gradation value of each pixel in the previous frame image. Is provided with a frame memory.

  In recent years, there has been a demand for reduction of power consumption in liquid crystal display devices. For example, in a situation where it is not necessary to display a moving image, image display is performed based on an image of a specific frame held in a frame memory. A liquid crystal display device equipped with a PSR function (PSR: Panel Self Refresh) is known.

JP 2013-167766 A

  When the PSR function is installed in the liquid crystal display device disclosed in Patent Document 1, a frame memory for realizing the overshoot process and a frame memory for realizing the PSR function are required, which increases the manufacturing cost. It had the problem that. The viewing angle improvement process is realized by temporally switching between a high gradation pixel and a low gradation pixel. In the PSR process, an image is displayed based on the gradation data held in the frame memory. Therefore, it was difficult to make both compatible.

  The present invention has been made in view of such circumstances, and can perform overdrive for improving the response speed of the liquid crystal while realizing the PSR function and the viewing angle improvement processing without adding a frame memory. An object is to provide a liquid crystal display device and a driving method.

  The liquid crystal display device according to the present invention is a liquid crystal display device that displays an image by driving a liquid crystal display panel having a plurality of pixels based on gradation data input in time series in units of frames. A storage unit that sequentially stores the gradation data that has been received, a first display method that displays an image based on the input gradation data, and a level that is stored in the storage unit when input of the gradation data is stopped. A selection unit that selects one of the second display methods for performing image display based on the tone data, and when the first display method is selected, each pixel of the image to be displayed from the input grayscale data in units of frames When the second display method is selected by generating a gradation pattern that defines the target gradation value in, the target in each pixel of the image to be displayed is determined from the gradation data in units of frames stored in the storage unit. A first pattern generation unit that generates a gradation pattern that defines tone values, and a reference pattern that defines the gradation value of each pixel to be referred to when performing image display according to the gradation pattern generated by the first pattern generation unit Based on the second pattern generation unit generated from the gradation data stored in the storage unit, the gradation pattern generated by the first pattern generation unit, and the reference pattern generated by the second pattern generation unit, The liquid crystal display panel includes a drive unit that performs overdrive to shorten the response time of the liquid crystal.

  In the liquid crystal display device according to the present invention, the first pattern generation unit generates a gradation pattern that defines a target gradation value of each pixel in an image of a current frame to be displayed, and the second pattern The generation unit generates the same pattern as the gradation pattern for the image of the frame immediately before the current frame as the reference pattern.

  The liquid crystal display device according to the present invention is characterized in that the first pattern generation unit generates a gradation pattern in which gradation values of two adjacent pixels are different from each other by a predetermined value or more.

  In the liquid crystal display device according to the present invention, the driving unit is configured to use the liquid crystal at a voltage higher than a driving voltage corresponding to the target gradation value based on a difference in gradation value between the gradation pattern and the reference pattern. The display panel is driven.

  The driving method according to the present invention is a method for driving a liquid crystal display panel having a plurality of pixels based on gradation data input in time series in units of frames. A first display method for displaying an image based on the input gradation data, and a first display method for stopping the input of the gradation data and performing an image display based on the gradation data stored in the storage unit; When either one of the two display methods is selected and the first display method is selected, a gradation pattern that defines a target gradation value for each pixel of the image to be displayed from the input gradation data in units of frames. When the second display method is selected, a gradation pattern defining a target gradation value for each pixel of the image to be displayed is generated from the gradation data in units of frames stored in the storage unit, Generated floor A reference pattern that determines the gradation value of each pixel to be referred to when performing image display according to the pattern is generated from the gradation data stored in the storage unit, and based on the generated gradation pattern and the reference pattern, The liquid crystal display panel is characterized by performing overdrive for shortening the response time of the liquid crystal.

  According to the present application, it is possible to realize overdrive for improving the response speed of the liquid crystal while realizing the PSR function and the viewing angle improvement process without adding a storage means such as a frame memory.

It is a block diagram which shows the principal part structure of the liquid crystal display device which concerns on this Embodiment. It is explanatory drawing explaining operation | movement when a PSR function is OFF. It is explanatory drawing explaining the production | generation method of the gradation pattern in a 1st viewing angle improvement process part. It is explanatory drawing explaining the production | generation method of the gradation pattern in a 2nd viewing angle improvement process part. It is a schematic diagram which shows an example of a gradation pattern and a reference pattern. It is explanatory drawing explaining operation | movement when a PSR function is ON. FIG. 10 is an explanatory diagram for explaining a viewing angle improvement process in the second embodiment. It is explanatory drawing explaining the production | generation method of the gradation pattern in a 1st viewing angle improvement process part. 12 is an explanatory diagram for explaining a viewing angle improvement process according to Embodiment 3. FIG. 12 is an explanatory diagram for explaining a viewing angle improvement process according to Embodiment 4. FIG.

Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof.
Embodiment 1 FIG.
FIG. 1 is a block diagram showing a main configuration of the liquid crystal display device according to the present embodiment. The liquid crystal display device according to the present embodiment includes a frame memory 11, a switching unit 12, a first viewing angle improvement processing unit 13, a second viewing angle improvement processing unit 14, and an overshoot processing unit 15 (hereinafter referred to as an OS processing unit 15). And a liquid crystal display panel 16. In the present embodiment, the first display method for displaying an image based on frame-by-frame gradation data sequentially input from the outside, and the gradation stored in the frame memory 11 while the gradation data input is stopped. One of the second display methods (PSR function) for displaying an image based on the data can be selected.

  In addition, regarding the selection of the display method, the display method may be switched from one to the other when a selection operation from the user is accepted, and the control unit (not shown) inside the liquid crystal display device is switched at an appropriate timing. It is good.

  When the first display method is selected, the frame memory 11 is sequentially input with gradation data in units of frames in time series. The frame memory 11 has a storage capacity for storing gradation data for one frame. When gradation data corresponding to a new frame is input, the gradation data of the previous frame is newly input. It is configured to be overwritten and erased by frame gradation data.

  A signal indicating whether or not the second display method is selected (that is, a signal indicating ON / OFF of the PSR function) is input to the switching unit 12, and gradation data to be displayed is input in accordance with the signal. It has the function of switching the source.

  When a signal indicating that the second display method is not selected (a signal indicating that the PSR function is turned off) is input to the switching unit 12, in order to perform image display in the first display method, the switching unit 12 Gradation data in units of frames sequentially input from the outside is sent to the first viewing angle improvement processing unit 13 in the subsequent stage. Gradation data in units of frames sequentially input from the outside is also sent to the frame memory 11 and stored in the frame memory 11. The second viewing angle improvement processing unit 14 synchronizes with the timing when the switching unit 12 sends the gradation data to the first viewing angle improvement processing unit 13, and the second viewing angle improvement processing unit 14 stores the level of the previous frame stored in the frame memory 11. Read and obtain key data. That is, when displaying an image by the first display method, the first viewing angle improvement processing unit 13 is input with the gradation data corresponding to the Nth frame via the switching unit 12 and the second viewing angle. Gradation data corresponding to the (N−1) th frame is input to the improvement processing unit 14 via the frame memory 11.

  When a signal indicating that the second display method is selected (a signal indicating that the PSR function is on) is input to the switching unit 12, the gradation to be displayed in order to perform image display in the second display method The data input source is switched to the frame memory 11. At this time, the input of new gradation data to the frame memory 11 is stopped. The first viewing angle improvement processing unit 13 reads out and acquires gradation data of a specific frame stored in the frame memory 11. The second viewing angle improvement processing unit 14 reads out the gradation data stored in the frame memory 11 in synchronization with the timing at which the first viewing angle improvement processing unit 13 reads out the gradation data from the frame memory 11. get. That is, when performing video display by the second display method, the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14 store gradation data of a specific frame stored in the frame memory 11. Entered.

  The first viewing angle improvement processing unit 13 generates a gradation pattern that defines the target gradation value of each pixel in the image of the current frame to be displayed on the liquid crystal display panel 16. The gradation pattern generated by the first viewing angle improvement processing unit 13 is a pattern in which the gradation values of two adjacent pixels are different from each other by a predetermined value or more, and the high gradation pixel and the low gradation pixel are spatially separated. It is a zigzag pattern arranged alternately. In addition, the first viewing angle improvement processing unit 13 switches between a high gradation pixel and a low gradation pixel for each frame, and sends the gradation pattern to the OS processing unit 15 in the subsequent stage.

  A gradation pattern in which high gradation pixels and low gradation pixels are alternately arranged spatially is generated, and an intermediate gradation image is displayed by driving the liquid crystal display panel 16 based on the gradation pattern. Therefore, when the liquid crystal display panel 16 is viewed from an oblique direction, whitening of the intermediate gradation is suppressed. In the present embodiment, since a staggered pattern in which high gradation pixels and low gradation pixels are alternately arranged for each pixel is used, it is possible to enhance the fineness of the image. Further, since the high gradation pixel and the low gradation pixel are switched over time, the luminance can be averaged and the staggered sub-pixel can be made inconspicuous.

  The second viewing angle improvement processing unit 14 generates, as a reference pattern, the same pattern as the gradation pattern for the image of the frame immediately before the current frame to be displayed on the liquid crystal display panel 16. That is, the reference pattern generated by the second viewing angle improvement processing unit 14 is a staggered pattern in which high-gradation pixels and low-gradation pixels are spatially alternately arranged like the gradation pattern. When the Nth frame gradation pattern is generated by the 1 viewing angle improvement processing unit 13, a pattern corresponding to the gradation pattern of the (N-1) th frame is generated as a reference pattern. The second viewing angle improvement processing unit 14 sends the reference pattern to the subsequent OS processing unit 15 in synchronization with the first viewing angle improvement processing unit 13.

  When the first display method is selected, the second viewing angle improvement processing unit 14 is synchronized with the acquisition of the Nth frame gradation data by the first viewing angle improvement processing unit 13. By acquiring the gradation data of the (N−1) th frame from the frame memory 11, the gradation pattern generated by the first viewing angle improvement processing unit 13 and the reference pattern generated by the second viewing angle improvement processing unit 14 The frame can be shifted by one frame between them. On the other hand, when the second display method is selected, the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14 both read out and acquire the gradation data stored in the frame memory 11. To do. Therefore, strictly speaking, it is not possible to shift the frame by one frame between the two, but by generating a pattern in which the pattern to be generated is shifted by one frame, a frame that is shifted by one frame is generated in a pseudo manner. be able to.

  The OS processing unit 15 receives the gradation pattern sent from the first viewing angle improvement processing unit 13 and the reference pattern sent from the second viewing angle improvement processing unit 14 in synchronization with the first viewing angle improvement processing unit 13. Then, the liquid crystal display panel 16 is overdriven based on the gradation pattern and the reference pattern. The gradation pattern defines the target gradation value of each pixel in the image of the current frame to be displayed, and the reference pattern is a pattern indicating the gradation value of each pixel in the frame immediately before the current frame. is there. The OS processing unit 15 overdrives the liquid crystal display panel 16 based on the change from the gradation value of each pixel indicated by the reference pattern to the target gradation value of each pixel indicated by the gradation pattern.

  FIG. 2 is an explanatory diagram for explaining the operation when the PSR function is off. When the PSR function is off, the switching unit 12 receives a signal indicating that the PSR function is off. In response to the input of the signal, the switching unit 12 switches the input source of the gradation data. That is, the switching unit 12 sends to the first viewing angle improvement processing unit 13 the grayscale data inputted in time series from the outside.

  The gradation data input from the outside in time series is also supplied to the frame memory 11. The frame memory 11 holds the gradation data of the frame immediately before the current frame by delaying the supplied gradation data by one frame when writing to the storage area.

  The second viewing angle improvement processing unit 14 synchronizes with the fact that the switching unit 12 sends the gradation data of the current frame to the first viewing angle improvement processing unit 13, and the second viewing angle improvement processing unit 14 Gradation data is acquired.

  The first viewing angle improvement processing unit 13 generates a gradation pattern that determines a target gradation value for each pixel when displaying an image of the current frame, based on the gradation data of the current frame acquired from the switching unit 12. To do. At this time, the first viewing angle improvement processing unit 13 changes the gradation value between adjacent pixels by a predetermined amount or more, and the gradation pattern in which the high gradation pixels and the low gradation pixels are alternately arranged in space. Is generated.

  FIG. 3 is an explanatory diagram for explaining a method of generating a gradation pattern in the first viewing angle improvement processing unit 13. For example, the first viewing angle improvement processing unit 13 sets the gradation value of each pixel after performing resolution conversion that doubles each pixel in the vertical direction and the horizontal direction, thereby setting the high gradation pixel and A gradation pattern in which low gradation pixels are alternately arranged is generated.

FIG. 3A shows a state in which an arbitrary pixel of interest in the image of the Nth frame (frame N) is subjected to resolution conversion twice in the vertical direction and the horizontal direction, and the gradation value of each pixel is set. When the gradation value of the pixel of interest before resolution conversion is P _N , the first viewing angle improvement processing unit 13 sets the gradation values of the four pixels after resolution conversion to P _N , as shown in FIG. 3A. −α, P _N + α, P _N + α, P _N −α (α is an appropriate integer). By executing such resolution conversion and gradation value setting for each pixel while changing the target pixel, a gradation pattern in which high gradation pixels and low gradation pixels are alternately arranged is generated. be able to.

Similarly, FIG. 3B shows a state in which the pixel of interest in the image of the (N + 1) th frame (frame N + 1) is subjected to resolution conversion twice in the vertical direction and the horizontal direction, and the gradation value of each pixel is set. . When the gradation value of the pixel of interest before resolution conversion is P _{N + 1} , the first viewing angle improvement processing unit 13 reduces the low gradation if the corresponding pixel is a high gradation in the previous frame (Nth frame). As shown in FIG. 3B, the gradation values of the four pixels after the resolution conversion are respectively changed to P _{N + 1} + α and P _{N + 1} − so that if the gradation is low, the gradation becomes high. α, P _{N + 1} −α, P _{N + 1} + α (α is an appropriate integer). By executing such resolution conversion and gradation value setting for each pixel while changing the target pixel, a gradation pattern in which high gradation pixels and low gradation pixels are alternately arranged is generated. In addition, a gradation pattern in which high gradation pixels and low gradation pixels are switched can be generated from the gradation pattern for the Nth frame.

  In this embodiment, a gradation value that is higher by α than the original gradation value is set to a high gradation pixel, and a gradation value that is lower than the original gradation value by α is set to a low gradation pixel. Although the configuration is adopted, the value of α can be determined as appropriate, and may be a predetermined constant or a variable determined according to the level of the original gradation value. Also, a configuration in which a gradation value higher by α than the original gradation value is set for a high gradation pixel, and a gradation value lower by β (β ≠ α) than the original gradation value is set for a low gradation pixel. It is good.

  On the other hand, when the second viewing angle improvement processing unit 14 displays the image of the current frame based on the gradation data of the current frame acquired from the frame memory 11 in the same manner as the first viewing angle improvement processing unit 13. As a reference pattern in which the gradation value of each pixel to be referred to is determined, the same pattern as the gradation pattern one before the current frame is generated.

  FIG. 4 is an explanatory diagram for explaining a method of generating a gradation pattern in the second viewing angle improvement processing unit 14. Similar to the first viewing angle improvement processing unit 13, the second viewing angle improvement processing unit 14 performs resolution conversion for enlarging each pixel twice in the vertical direction and the horizontal direction, and then converts the gradation value of each pixel. By setting, a gradation pattern in which high gradation pixels and low gradation pixels are alternately arranged is generated.

When the first viewing angle improvement processing unit 13 generates a gradation pattern for the image of the Nth frame, the second viewing angle improvement processing unit 14 refers to the image of the N−1th frame immediately before it. Generate a pattern. FIG. 4A shows a state in which the pixel of interest in the image of the (N−1) th frame is subjected to resolution conversion twice in the vertical direction and the horizontal direction, and the gradation value of each pixel is set. When the gradation value of the target pixel before the resolution conversion is P _N−1 , the second viewing angle improvement processing unit 14 sets the gradation values of the four pixels after the resolution conversion to P P as shown in FIG. 4A. _N−1− α, P _N−1 + α, P _N−1 + α, and P _N−1 −α (α is an appropriate integer). By executing such resolution conversion and gradation value setting for each pixel while changing the pixel of interest, a reference pattern in which high gradation pixels and low gradation pixels are alternately arranged is generated. Can do.

Similarly, FIG. 4B shows a state in which the pixel of interest in the image of the Nth frame is subjected to resolution conversion twice in the vertical direction and the horizontal direction, and the gradation value of each pixel is set. If the tone value of the pixel of interest before the resolution conversion was P _N, the second viewing angle improving module 14, a low gray level if the corresponding pixel is high tone in the previous frame (N-1 th frame) As shown in FIG. 4B, the gradation values of the four pixels after the resolution conversion are respectively changed to P _N −α, P _N + α, and P _N + α so that the higher gradation is obtained when the gradation is low. , P _N −α (α is an appropriate integer). By executing such resolution conversion and gradation value setting for each pixel while changing the pixel of interest, a reference pattern in which high gradation pixels and low gradation pixels are alternately arranged is generated. From the reference pattern for the (N-1) th frame, a reference pattern in which high gradation pixels and low gradation pixels are switched can be generated.

  Note that the reference pattern generated from the Nth frame image generated by the second viewing angle improvement processing unit 14 is a gradation pattern generated from the Nth frame image generated by the first viewing angle improvement processing unit 13. It becomes substantially the same.

  FIG. 5 is a schematic diagram illustrating an example of a gradation pattern and a reference pattern. When the first viewing angle improvement processing unit 13 generates the gradation pattern corresponding to the Nth frame (frame N), the low gradation pixels and the high gradation pixels are spatially (vertical direction and horizontal direction). A pattern arranged alternately is generated. In FIG. 5, hatched squares represent low gradation pixels, and white squares represent high gradation pixels.

  When one frame has elapsed, the first viewing angle improvement processing unit 13 generates a gradation pattern by switching between a low gradation pixel and a high gradation pixel, and therefore a gradation pattern corresponding to the Nth frame. In FIG. 5, the low gradation pixel (high gradation pixel) is changed to a high gradation pixel (low gradation pixel) in the gradation pattern corresponding to the (N + 1) th frame. Similarly, a high gradation pixel (low gradation pixel) in the gradation pattern corresponding to the (N + 1) th frame becomes a low gradation pixel (high gradation pixel) in the gradation pattern corresponding to the (N + 2) th frame. Be changed.

  On the other hand, when the first viewing angle improvement processing unit 13 generates a gradation pattern corresponding to the Nth frame, the second viewing angle improvement processing unit 14 generates an N−1th frame (frame) immediately before it. A reference pattern corresponding to N-1) is generated.

  When one frame has elapsed, the second viewing angle improvement processing unit 14 generates a gradation pattern by switching between a low gradation pixel and a high gradation pixel, and therefore the reference corresponding to the (N−1) th frame. A high gradation pixel (low gradation pixel) in the pattern is changed to a low gradation pixel (high gradation pixel) in the reference pattern corresponding to the Nth frame. Similarly, a low gradation pixel (high gradation pixel) in the gradation pattern corresponding to the Nth frame becomes a high gradation pixel (low gradation pixel) in the gradation pattern corresponding to the N + 1th frame. Be changed.

  FIG. 6 is an explanatory diagram for explaining the operation when the PSR function is on. When the PSR function is on, input of gradation data is stopped and a signal indicating that the PSR function is on is input to the switching unit 12. In response to the input of the signal, the switching unit 12 switches the input source of the gradation data. That is, the switching unit 12 sends the gradation data of a specific frame stored in the frame memory 11 to the first viewing angle improvement processing unit 13.

  The second viewing angle improvement processing unit 14 synchronizes with the switching unit 12 sending the gradation data of the current frame to the first viewing angle improvement processing unit 13, and the specific frame held in the frame memory 11. The gradation data is acquired.

  The first viewing angle improvement processing unit 13 generates a gradation pattern that defines a target gradation value for each pixel when displaying an image, based on the gradation data acquired from the switching unit 12. At this time, the first viewing angle improvement processing unit 13 changes the gradation value between adjacent pixels by a predetermined amount or more, and the gradation pattern in which the high gradation pixels and the low gradation pixels are alternately arranged in space. Is generated.

  Further, the second viewing angle improvement processing unit 14 generates a reference pattern that determines the gradation value of each pixel to be referred to when displaying an image, based on the gradation data acquired from the frame memory 11. When the PSR function is on, the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14 both refer to the gradation pattern and the reference based on the gradation data of a specific frame acquired from the frame memory 11, respectively. Get the pattern. For this reason, the second viewing angle improvement processing unit 14 cannot inherently generate a reference pattern corresponding to a frame immediately before the current frame to be displayed, but only generates a pattern for one frame. By using a shifted pattern, it is possible to generate a reference pattern that is shifted by one frame in a pseudo manner.

  As described above, in the present embodiment, when the PSR function is off, the first viewing angle improvement processing unit 13 sets the target floor of the image to be displayed based on the gradation data in units of frames input from the outside. A gradation pattern in which a tone value is determined is generated, and the second viewing angle improvement processing unit 14 generates a reference pattern for executing OS processing using the gradation data of the previous frame held in the frame memory 11. To do. When the OS processing unit 15 drives the liquid crystal display panel 16 using the gradation pattern of the current frame input from the first viewing angle improvement processing unit 13, the previous frame input from the second viewing angle improvement processing unit 14. By overdriving with reference to this reference pattern, the response time of the liquid crystal can be shortened to improve the moving image display performance, and the viewing angle improvement processing can be realized by giving a gradation value difference between the pixels.

  In the present embodiment, when the PSR function is on, the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14 are based on the gradation data of a specific frame held in the frame memory 11. A gradation pattern and a reference pattern are generated respectively. The OS processing unit 15 is artificially generated by the second viewing angle improvement processing unit 14 when driving the liquid crystal display panel 16 using the gradation pattern of the current frame input from the first viewing angle improvement processing unit 13. Overdrive can be performed by referring to the reference pattern of the previous frame. That is, in the present embodiment, the liquid crystal response is achieved while realizing the PSR function for reducing power consumption by sharing one frame memory 11 in the PSR function and OS processing without adding the frame memory. Overdrive for shortening the time can be realized.

Embodiment 2. FIG.
In the first embodiment, as an example of the gradation pattern generation method in the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14, the gradation value of each pixel is set after resolution conversion. Although the configuration has been described, the method for generating a gradation pattern is not limited to the method described in the first embodiment. In the second embodiment, a method of generating a gradation pattern without performing resolution conversion will be described.
Note that the second embodiment is different from the first embodiment only in the gradation pattern generation method, and the hardware configuration and the like of the liquid crystal display device are exactly the same as those in the first embodiment. And

  FIG. 7 is an explanatory diagram for explaining the viewing angle improvement processing in the second embodiment. 7A shows the viewing angle improvement processing by the first viewing angle improvement processing unit 13, and FIG. 7B shows the viewing angle improvement processing by the second viewing angle improvement processing unit 14. As described in the first embodiment, when the PSR function is OFF, for example, the gradation data corresponding to the Nth frame is input to the first viewing angle improvement processing unit 13 through the switching unit 12 and the second Gradation data corresponding to the (N−1) th frame delayed by one frame is input to the viewing angle improvement processing unit 14 through the frame memory 11.

  In the example of the input gradation data shown in FIG. 7, a white square represents a high gradation pixel, a hatched square represents an intermediate gradation pixel, and a black square represents a low gradation pixel. In addition, in order to simplify the description, the input grayscale data shown in FIG. 7 separates a region where high gradation pixels are arranged, a region where intermediate gradation pixels are arranged, and a region where low gradation pixels are arranged. Data.

  The first viewing angle improvement processing unit 13 converts a high gradation pixel and a low gradation pixel into a staggered gradation pattern in which the pixels of the intermediate gradation are lined up in a space alternately. In addition, the first viewing angle improvement processing unit 13 switches between a high gradation pixel and a low gradation pixel for each frame, and sends the gradation pattern to the OS processing unit 15 in the subsequent stage.

  The second viewing angle improvement processing unit 14 generates, as a reference pattern, the same pattern as the gradation pattern for the image of the frame immediately before the current frame to be displayed on the liquid crystal display panel 16. That is, the reference pattern generated by the second viewing angle improvement processing unit 14 is a staggered pattern in which high-gradation pixels and low-gradation pixels are alternately arranged in a spatial manner, similarly to the gradation pattern. When the corner improvement processing unit 13 generates the gradation pattern of the Nth frame, a pattern corresponding to the gradation pattern of the (N−1) th frame is generated as a reference pattern. The second viewing angle improvement processing unit 14 sends the reference pattern to the subsequent OS processing unit 15 in synchronization with the first viewing angle improvement processing unit 13.

  In the above-described viewing angle improvement processing, the case where the PSR function is off has been described, but the same applies to the case where the PSR function is on. When the PSR function is ON, the gradation data corresponding to the same frame number is input to both the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14 through the frame memory 11, and the second viewing angle. The improvement processing unit 14 generates a reference pattern shifted by one frame in a pseudo manner by generating a pattern shifted by one frame from the first viewing angle improvement processing unit 13. At this time, the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14 respectively change the gradation by directly changing the pattern of the portion where a plurality of intermediate gradation pixels are arranged, as described above. A pattern and a reference pattern are generated.

  FIG. 8 is an explanatory diagram for explaining a method of generating a gradation pattern in the first viewing angle improvement processing unit 13. In the second embodiment, the first viewing angle improvement processing unit 13 changes the gradation value of each pixel in the region where the intermediate gradation pixels are arranged without performing resolution conversion, thereby reducing the high gradation pixel and the low gradation pixel. A gradation pattern in which gradation pixels are alternately arranged is generated.

FIG. 8A shows an area in which two grayscale pixels are arranged in the vertical direction and the horizontal direction in the grayscale data of the Nth frame (frame N). When the gradation value of each pixel before the gradation pattern generation is P _N , the first viewing angle improvement processing unit 13 sets the gradation value of each pixel to P _N + α and P _N −α as shown in FIG. 8A. , P _N −α, P _N + α (α is an appropriate constant). The first viewing angle improvement processing unit 13 applies such a change in pixel value to each pixel in the intermediate gradation region, whereby gradations in which high gradation pixels and low gradation pixels are alternately arranged are arranged. Generate a pattern.

In the example shown in FIG. 8A, the gradation values of all the pixels to be converted are all set to P _N , but the gradation values are not necessarily the same, and appropriate gradation values belonging to the intermediate gradation region are respectively set. It only has to have. Note that whether or not each pixel belongs to an intermediate gradation can be determined using an existing determination method, for example, between a first threshold value and a second threshold value (first threshold value <second threshold value). A pixel having a gradation value can be determined as a pixel having an intermediate gradation.

FIG. 8B shows a region in which two grayscale pixels are arranged in the vertical direction and the horizontal direction in the grayscale data of the (N + 1) th frame (frame N + 1). When the gradation value of each pixel before generation of the gradation pattern is P _{N + 1} , the first viewing angle improvement processing unit 13 reduces the low level if the corresponding pixel in the previous frame (Nth frame) is high gradation. The gradation values of the respective pixels are changed to P _{N + 1} −α, P _{N + 1} + α, P _{N + 1} + α, and P _{N +} so that the gradation becomes high if the gradation is low. Change to _1- α (α is an appropriate integer). The first viewing angle improvement processing unit 13 applies such a change in pixel value to each pixel in the intermediate gradation region, whereby gradations in which high gradation pixels and low gradation pixels are alternately arranged are arranged. Generate a pattern.

  In this embodiment, a gradation value that is higher by α than the original gradation value is set to a high gradation pixel, and a gradation value that is lower than the original gradation value by α is set to a low gradation pixel. Although the configuration is adopted, the value of α can be determined as appropriate, and may be a predetermined constant or a variable determined according to the level of the original gradation value. Also, a configuration in which a gradation value higher by α than the original gradation value is set for a high gradation pixel, and a gradation value lower by β (β ≠ α) than the original gradation value is set for a low gradation pixel. It is good.

  Although the gradation pattern generation method by the first viewing angle improvement processing unit 13 has been described with reference to FIG. 8, the same applies to the method by which the second viewing angle improvement processing unit 14 generates the reference pattern. Similar to the first viewing angle improvement processing unit 13, the second viewing angle improvement processing unit 14 is referred to when displaying the image of the current frame based on the gradation data of the current frame acquired from the frame memory 11. As a reference pattern in which the gradation value of each power pixel is determined, the same pattern as the gradation pattern one before the current frame is generated.

  As described above, in the second embodiment, the gradation pattern and the reference pattern can be generated without converting the resolution of the original image, and the viewing angle improvement process and the overdrive are performed using these patterns. can do.

Embodiment 3 FIG.
In the first and second embodiments, in order to improve the viewing angle on the liquid crystal display panel 16, in the first viewing angle improvement processing unit 13 and the second viewing angle improvement processing unit 14, the gradation between two adjacent pixels is determined. By changing the value by a predetermined value or more, a pattern in which high gradation pixels and low gradation pixels are spatially alternately arranged is generated. However, the viewing angle improvement processing is limited to this structure. It is not a thing. For example, a viewing angle improvement process in consideration of gradation characteristics such as gamma characteristics and tone characteristics in the liquid crystal display panel 16 may be performed. In the third embodiment, a configuration for realizing the viewing angle improvement processing in consideration of the gradation characteristics of the liquid crystal display panel 16 will be described.

  FIG. 9 is an explanatory diagram for explaining the viewing angle improvement processing according to the third embodiment. The horizontal axis of the graph shown in FIG. 9 represents the input gradation value (0 to 255), and the vertical axis represents the output gradation value (0 to 255). In FIG. 4, the specific C0 indicates a tone characteristic when the viewer observes the display surface of the liquid crystal display panel 16 from the vertical direction. On the other hand, the characteristic C1 indicates the tone characteristic when the viewer observes from the direction of −30 degrees with respect to the display surface, and the characteristic C2 indicates the tone characteristic when the viewer observes from the direction of +30 degrees with respect to the display surface. Is shown.

In the third embodiment, viewing angle improvement processing is performed using such gradation characteristics. That is, the first viewing angle improvement processing unit 13 enlarges one pixel (whose gradation value is P _N ) to four pixels by resolution conversion, and then sets one of two pixels adjacent in the vertical direction as a characteristic C1. and the corresponding gray scale value (P _N + a) to convert the other of the corresponding pixel value in the characteristic C2 to (P _N -b). By changing the gradation value in this way, the viewer who observes the liquid crystal display panel 16 can obtain an average gradation value (that is, an average brightness value) of the gradation value based on the characteristic C1 and the gradation value based on the characteristic C2. In this case, the pixel is observed.
Further, the second viewing angle improvement processing unit 14 generates a reference pattern corresponding to the frame immediately before the current frame to be displayed, as in the first and second embodiments.

  As described above, in the third embodiment, the high gradation pixel and the low gradation pixel are determined in consideration of the gradation characteristics of the liquid crystal display panel 16, and therefore, an appropriate viewing angle with respect to the liquid crystal display panel 16. Adjustments can be made.

Embodiment 4 FIG.
In Embodiment 1-3, the viewing angle improvement processing is realized by giving a gradation value difference between adjacent pixels in one frame. However, the viewing angle improvement processing is realized by giving a gradation value difference between frames. May be realized. In the fourth embodiment, a configuration for realizing a viewing angle improvement process by giving a gradation value difference between frames will be described.

FIG. 10 is an explanatory diagram for explaining the viewing angle improvement processing according to the fourth embodiment. In the fourth embodiment, the first viewing angle improvement processing unit 13 sets the upper half region of the image to low gradation pixels for the Nth, N + 2th, N + 4th,. A gradation pattern in which the above area is set to a high gradation pixel is generated. Also, the first viewing angle improvement processing unit 13 sets the upper half area of the image to high gradation pixels and sets the lower half area of the image to the lower order for the (N + 1) th, N + 3th, N + 5th,. A gradation pattern set for a tone pixel is generated. By changing the gradation value in this way, the viewer who observes the liquid crystal display panel 16 can artificially observe the video signal represented by the average level of the odd-numbered frame and the even-numbered frame. become.
Further, the second viewing angle improvement processing unit 14 generates a reference pattern corresponding to the frame immediately before the current frame to be displayed, as in the first and second embodiments.

  As described above, in the fourth embodiment, the viewing angle processing can be performed by giving a gradation value difference between frames.

  The embodiment disclosed this time is to be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the meanings described above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  In Embodiment 1 of the present invention, in a liquid crystal display device that displays an image by driving a liquid crystal display panel (16) having a plurality of pixels based on gradation data input in time series in units of frames. A storage unit (11) for sequentially storing the input gradation data in a frame; a first display method for displaying an image based on the input gradation data; and the input of the gradation data to stop the storage A selection unit (12) for selecting one of the second display methods for performing image display based on the gradation data stored in the unit (11); when the first display method is selected, the input frame unit floor When tone patterns defining target tone values for each pixel of an image to be displayed are generated from tone data, and the second display method is selected, the tone for each frame stored in the storage unit (11) From the data A first pattern generation unit (13) that generates a gradation pattern that defines a target gradation value for each pixel of an image to be displayed, and performs image display according to the gradation pattern generated by the first pattern generation unit (13). A second pattern generation unit (14) that generates a reference pattern that defines the gradation value of each pixel to be referred to from the gradation data stored in the storage unit (11), and the first pattern generation unit ( Drive that performs overdrive for reducing the response time of the liquid crystal in the liquid crystal display panel (16) based on the gradation pattern generated in 13) and the reference pattern generated by the second pattern generation unit (14) A part (15) is provided.

  In the present invention, the first display method for displaying an image based on gradation data input in time series, and the image display based on the gradation data stored in the storage unit by stopping the input of the gradation data. It is possible to select the second display method for performing the above.

  When the first display method is selected, a gradation pattern in which the target luminance is determined is generated from gradation data of each frame that is sequentially input, and a reference pattern is generated from the gradation data of the frame stored in the storage unit The liquid crystal display panel is overdriven using these gradation patterns and reference patterns. By configuring the viewing angle improvement pattern with the gradation pattern generated by the first pattern generation unit, the viewing angle in the liquid crystal display panel is improved, so the viewing angle improvement process and the overshoot process (overdrive) are common. This is realized using a storage unit.

  When the second display method is selected, the input of gradation data is stopped, so that power consumption can be reduced compared to normal display (first display method). Further, when the second display method is selected, a gradation pattern and a reference pattern are generated from the gradation data of the frame stored in the storage unit, and a liquid crystal display panel is used by using these gradation pattern and reference pattern. Overdrive to. That is, even when the second display method is selected, viewing angle improvement processing and overshoot processing (overdrive) are realized without adding a storage unit such as a frame memory.

  In Embodiment 2 of the present invention, the first pattern generation unit (13) generates a gradation pattern that defines a target gradation value of each pixel in an image of the current frame to be displayed. The two pattern generation unit (14) is characterized in that the same pattern as the gradation pattern for the image of the frame immediately before the current frame is generated as the reference pattern.

  In the present invention, the liquid crystal display device controls the driving voltage for the liquid crystal display panel based on the change from the gradation value of the previous frame determined by the reference pattern to the gradation value of the current frame determined by the gradation pattern. An overdriver that shortens the response time of the liquid crystal is realized.

  In Embodiment 3 of the present invention, the first pattern generator (13) generates a gradation pattern in which the gradation values of two adjacent pixels are different from each other by a predetermined value or more. .

  In the present invention, the gradation pattern generated by the first pattern generation unit is a staggered pattern in which high gradation pixels and low gradation pixels are alternately arranged. Tone pixels are switched. By driving the liquid crystal display panel based on such a gradation pattern, whitening in the intermediate gradation is suppressed while enhancing the fineness of the displayed image.

  In Embodiment 4 of the present invention, the drive unit (15) is based on a difference between gradation values of the gradation pattern and the reference pattern, and has a voltage higher than the drive voltage corresponding to the target gradation value. The liquid crystal display panel (16) is driven.

  In the present invention, the driving unit drives the liquid crystal display panel with a voltage higher than the driving voltage corresponding to the target gradation value based on the difference between the gradation values of the gradation pattern and the reference pattern. The response time of the liquid crystal when shifting to a high gradation is shortened.

  In Embodiment 5 of the present invention, in a method for driving a liquid crystal display panel (16) having a plurality of pixels based on gradation data input in time series in units of frames, the input gradation data is The first display method for storing images sequentially in the storage unit (11) and displaying an image based on the input gradation data, and the level stored in the storage unit (11) after stopping the input of the gradation data. When any one of the second display methods for performing image display based on the tone data is selected and the first display method is selected, the target for each pixel of the image to be displayed is determined from the input gradation data for each frame. When a gradation pattern in which gradation values are defined is generated and the second display method is selected, the target floor in each pixel of the image to be displayed is determined from the gradation data in frame units stored in the storage unit (11). Set the key value Generating a tone pattern, and generating a reference pattern defining a tone value of each pixel to be referred to when performing image display according to the generated tone pattern from the tone data stored in the storage unit (11), On the basis of the generated gradation pattern and reference pattern, overdrive for reducing the response time of the liquid crystal in the liquid crystal display panel is performed.

  When the first display method is selected, a gradation pattern in which the target luminance is determined is generated from gradation data of each frame that is sequentially input, and a reference pattern is generated from the gradation data of the frame stored in the storage unit The liquid crystal display panel is overdriven using these gradation patterns and reference patterns. By configuring the viewing angle improvement pattern with the gradation pattern generated by the first pattern generation unit, the viewing angle in the liquid crystal display panel is improved, so the viewing angle improvement process and the overshoot process (overdrive) are common. This is realized using a storage unit.

  When the second display method is selected, the input of gradation data is stopped, so that power consumption can be reduced compared to normal display (first display method). Further, when the second display method is selected, a gradation pattern and a reference pattern are generated from the gradation data of the frame stored in the storage unit, and a liquid crystal display panel is used by using these gradation pattern and reference pattern. Overdrive to. That is, even when the second display method is selected, viewing angle improvement processing and overshoot processing (overdrive) are realized without adding a storage unit such as a frame memory.

11 Frame memory 12 Switching unit 13 First viewing angle improvement processing unit 14 Second viewing angle improvement processing unit 15 Overshoot processing unit 16 Liquid crystal display panel

Claims (5)

In a liquid crystal display device that displays an image by driving a liquid crystal display panel including a plurality of pixels based on gradation data that is input in time series in frame units.
A storage unit for storing the input gradation data in frame order;
Either the first display method for displaying an image based on the input gradation data, or the second display method for stopping the input of gradation data and performing an image display based on the gradation data stored in the storage unit A selection part for selecting one,
When the first display method is selected, a gradation pattern that defines a target gradation value for each pixel of an image to be displayed is generated from the input gradation data for each frame, and the second display method is selected. A first pattern generation unit that generates a gradation pattern that defines a target gradation value for each pixel of an image to be displayed, from the gradation data in units of frames stored in the storage unit;
A second pattern for generating a reference pattern that defines a gradation value of each pixel to be referred to when performing image display according to the gradation pattern generated by the first pattern generation unit from the gradation data stored in the storage unit An overdrive for reducing the response time of the liquid crystal in the liquid crystal display panel based on the generation pattern and the gradation pattern generated by the first pattern generation unit and the reference pattern generated by the second pattern generation unit; A liquid crystal display device comprising a drive unit for performing the operation. The first pattern generation unit generates a gradation pattern that defines a target gradation value of each pixel in an image of a current frame to be displayed;
2. The liquid crystal according to claim 1, wherein the second pattern generation unit is configured to generate, as the reference pattern, a pattern that is the same as a gradation pattern for an image of a frame immediately before the current frame. Display device.   The liquid crystal display device according to claim 2, wherein the first pattern generation unit generates a gradation pattern in which gradation values of two adjacent pixels are different from each other by a predetermined value or more.   The driving unit drives the liquid crystal display panel with a voltage higher than a driving voltage corresponding to the target gradation value based on a difference in gradation value between the gradation pattern and the reference pattern. The liquid crystal display device according to claim 1, wherein the liquid crystal display device is a liquid crystal display device. In a method of driving a liquid crystal display panel having a plurality of pixels based on gradation data input in time series in frame units,
The input gradation data is stored in the storage unit sequentially in the frame,
Either the first display method for displaying an image based on the input gradation data, or the second display method for stopping the input of gradation data and performing an image display based on the gradation data stored in the storage unit Select one,
When the first display method is selected, a gradation pattern that defines a target gradation value for each pixel of the image to be displayed is generated from the input gradation data for each frame,
When the second display method is selected, a gradation pattern defining a target gradation value for each pixel of the image to be displayed is generated from the gradation data stored in the storage unit in the frame unit,
A reference pattern that defines a gradation value of each pixel to be referred to when performing image display according to the generated gradation pattern is generated from the gradation data stored in the storage unit,
A driving method comprising performing overdrive for reducing a response time of liquid crystal in the liquid crystal display panel based on the generated gradation pattern and reference pattern.

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