WO2009091063A1

WO2009091063A1 - Image signal processor

Info

Publication number: WO2009091063A1
Application number: PCT/JP2009/050680
Authority: WO
Inventors: Tomohisa Higuchi
Original assignee: Thine Electronics, Inc.
Priority date: 2008-01-17
Filing date: 2009-01-19
Publication date: 2009-07-23
Also published as: JP5222307B2; JPWO2009091063A1

Abstract

An image signal processor (1) comprises a motion detecting section (11), a previous frame image data generating section (12), and a corrected image data output section (13). The motion detecting section (11) detects the direction of the motion of images in image data on each frame of an image signal to be inputted. The previous frame image data generating section (12) generates image data on the frame preceding by one frame on the basis of image data on the current frame of the image signal to be inputted and the result of the motion detection by the motion detecting section (11). The corrected image data output section (13) corrects image data on the current frame of the inputted image signal on the basis of image data (G2) on the current frame of the image signal to be inputted and image data (G1) on the frame preceding by one frame generated by the previous frame image data generating section (12) and outputs the corrected image data to a liquid crystal display (2).

Description

Image signal processing device

The present invention relates to an image signal processing device that processes image data of each frame of an input image signal and then outputs the image signal to a liquid crystal display device.

Image display devices are roughly classified into impulse display devices and hold display devices. In a CRT (Cathode Ray Tube), which is an example of an impulse display device, a screen is scanned by an electron gun, and display is performed only on pixels that have reached an electron beam. On the other hand, in a liquid crystal display device or an organic electroluminescence display device which is cited as an example of a hold-type display device, the frame of the image signal is updated at a constant period, and an instruction to display an image of a certain first frame is given. The display of the first frame image is held until the display of the next second frame image is instructed. Compared to the impulse-type display device, the hold-type display device has various features such as less image distortion.

However, the liquid crystal display device has a problem that the response is slow. That is, it takes time from when the target display value of an image of a certain frame is instructed until the actual display value on the liquid crystal display device becomes the target display value. The required time may exceed the frame update period. Therefore, when a moving image with fast movement is displayed on the screen of the liquid crystal display device, the moving image may be blurred.

An overdrive technique is known as a technique intended to solve such a problem (see Patent Documents 1 and 2). Overdrive technique, when attention is paid to a certain pixel on the screen of the liquid crystal display device, the image data G ₁ corresponding to the target display value in a certain first frame, corresponding to a target display value in the next second frame When the image data G ₂ to be processed is different, the image data G ₂ is corrected and the corrected image data G ₂ ′ is given to the liquid crystal display device. In this correction, “G ₂ <G ₂ ′” is set when “G ₁ <G ₂ ”, and “G ₂ > G ₂ ′” is set when “G ₁ > G ₂ ”. Thus, by providing an image signal processing device that outputs the image signal to the liquid crystal display device after processing the image data of each frame of the image signal, the actual display value in the liquid crystal display device quickly reaches the target display value. To be done.
Japanese Patent Laying-Open No. 2005-043864 JP 2006-091412 A

In the overdrive technology disclosed in

Patent Documents

1 and 2, the image data of the first frame immediately before the second frame is stored in order to correct the image data of the second frame. Therefore, it is necessary to use a large-capacity storage device that can store image data for at least one frame, and the cost of an image signal processing device including such a large-capacity storage device is high.

The present invention has been made to solve the above-described problems, and an object thereof is to provide an image signal processing apparatus that can be configured at low cost.

An image signal processing apparatus according to the present invention is an image signal processing apparatus that processes image data of each frame of an input image signal and then outputs the image signal to a liquid crystal display device. A motion detection unit that detects the direction of image motion based on the image data of each frame of the signal; (2) the current frame image data of the input image signal; and the direction of motion of the image detected by the motion detection unit; Based on the above, the previous frame image data generating unit for generating the image data of the previous frame, (3) the current frame image data of the input image signal, and the previous frame image data generated by the previous frame image data generating unit A corrected image data output unit that corrects the image data of the current frame of the input image signal based on the image data and outputs the corrected image data to the liquid crystal display device. It is characterized by providing.

In the image signal processing apparatus according to the present invention, the motion detection unit detects the direction of the image motion based on the image data of each frame of the input image signal. In addition, the previous frame image data generation unit generates image data of the previous frame based on the current frame image data of the input image signal and the direction of motion of the image detected by the motion detection unit. . Then, the corrected image data output unit outputs the input image signal based on the current frame image data of the input image signal and the previous frame image data generation unit generated by the previous frame image data generation unit. The image data of the current frame is corrected, and the corrected image data is output to the liquid crystal display device.

In the image signal processing device according to the present invention, the motion detection unit detects the direction and speed of the image motion based on the image data of each frame of the image signal, and the direction of the image motion detected by the motion detection unit is the line direction. (Horizontal direction), the previous frame image data generation unit outputs the image data of the current frame of the input image signal in the line direction according to the direction and speed of the motion of the image detected by the motion detection unit. It is preferable to generate image data one frame before by shifting to.

In the image signal processing device according to the present invention, when the direction of motion of the image detected by the motion detector is a direction perpendicular to the line direction (vertical direction), the previous frame image data generator generates the input image The image data of the previous frame is generated by changing the image data of each line of the current frame of the signal to a value between the original image data of the line and the image data of the previous line. Is preferred.

Note that the above processing may be performed on the entire image data of the frame, but if only a part of the image displayed on the screen is a moving image, it corresponds to that part of the image It may be performed only on image data to be processed.

The image signal processing apparatus according to the present invention can be configured at low cost.

FIG. 1 is a diagram showing a configuration of an image signal processing apparatus 1 according to the present embodiment. FIG. 2 is a diagram for explaining an example of corrected image data output from the corrected image data output unit 13 included in the image signal processing apparatus 1 according to the present embodiment. FIG. 3 is a diagram for explaining an example of corrected image data output from the corrected image data output unit 13 included in the image signal processing apparatus 1 according to the present embodiment. FIG. 4 is a diagram illustrating an example of corrected image data output from the corrected image data output unit 13 included in the image signal processing apparatus 1 according to the present embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Image signal processing apparatus 2 Liquid crystal display device 11 Motion detection part 12 Previous frame image data generation part 13 Corrected image data output part

The best mode for carrying out the present invention will be described below in detail with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

FIG. 1 is a diagram showing a configuration of an image signal processing apparatus 1 according to the present embodiment. The image signal processing device 1 processes the image data of each frame of the input image signal and then outputs the image signal to the liquid crystal display device 2. The image signal processing device 1 outputs a motion detection unit 11, a previous frame image data generation unit 12, and A corrected image data output unit 13 is provided. In the case of a color image, image data of one color will be described below, but the same applies to image data of other colors.

The motion detector 11 detects the direction of image motion based on the image data of each frame of the input image signal. In addition, it is preferable that the motion detection unit 11 detects the speed of motion in addition to the direction of motion of the image. The motion detection unit 11 outputs the motion detection result to the previous frame image data generation unit 12. Here, the image that is subject to motion detection may be an image of the entire frame, or may be an image of a partial region of the entire image, and a background image that has no motion or is small. It may be an image with movement in the image.

Various algorithms for motion detection by the motion detection unit 11 are known. For example, a matching method is used. That is, the motion detection unit 11 determines whether the image data of a certain area A ₁ in the image G ₁ ′ of the previous frame matches the image data of any area of the image G ₂ of the current frame. If there is a matching area A _{2 in} the image G ₂ of the current frame, the direction (= R (Δx, Δy)) and distance (L = (Δx) from the area A ₁ to the area A ₂ are determined. ^By detecting ² + Δy ² ) ^1/2 ) in units of pixels, the direction R and the speed (V = L / Δt) of the motion of the image are detected. However, Δx and Δy indicate the movement amount along each axis of the image in the two-dimensional coordinates, and Δt indicates the display cycle (reciprocal of the frame rate) of the images displayed in time series.

The previous frame image data generation unit 12 is based on the current frame image data G ₂ (A ₂ ) of the input image signal and the motion detection result (direction R and distance L or speed V) by the motion detection unit 11. generating the image data G ₁ of the previous frame. For example, the area A ₂ of the image data G ₂ of the current frame is moved by the distance L in the −R direction. However, the image data G ₁ (A ₁ ) one frame before generated by the previous frame image data generation unit 12 is estimated from the image data G ₂ (A ₂ ) of the current frame and the motion of the image. However, when the image is moving at a constant speed in a certain direction, it is in good agreement with the actual image data one frame before.

Corrected image data output unit 13, based on the image data G ₂ of the current frame of the input image signal, the previous frame image data generating unit 12 the image data G ₁ of the previous frame produced by, is input Then, the image data G ₂ of the current frame of the image signal is corrected, and the corrected image data is output to the liquid crystal display device 2. For this correction, the same overdrive technique as that of the prior art can be used.

Namely, when attention is paid to a certain pixel on the screen of the liquid crystal display device 2, relative to the previous frame image data generating unit 12 the image data G ₁ of the previous frame produced by an image of the current frame of the image signal input When the data G ₂ is different, the image data G ₂ is corrected and the corrected image data G ₂ ′ is given to the liquid crystal display device 2. More specifically, “G ₂ <G ₂ ′” is set when “G ₁ <G ₂ ”, and “G ₂ > G ₂ ′” is set when “G ₁ > G ₂ ”.

In the liquid crystal display device 2, an image is displayed based on the corrected image data G ₂ ′ output from the corrected image data output unit 13. As a result, the actual display value in the liquid crystal display device 2 quickly reaches the target display value.

FIG. 2 and FIG. 3 are diagrams for explaining an example of the corrected image data output from the corrected image data output unit 13 included in the image signal processing apparatus 1 according to the present embodiment. Here, it is assumed that the direction of motion of the image detected by the motion detection unit 11 is the line direction, and the image is moving to the right. At this time, the previous frame image data generation unit 12 shifts the image data of the current frame of the input image signal in the line direction according to the direction and speed of the motion of the image detected by the motion detection unit 11. Thus, the image data of the previous frame is generated.

The horizontal axis of each figure (a)-(c) shows the pixel position on the line of a certain horizontal direction in the image of a frame. Each Figure (a) shows the intensity distribution on the line of the image data G ₂ of the current frame of the input image signal (luminance distribution). Each Figure (b) shows the intensity distribution on the line of the previous frame image data generating unit 12 the image data G ₁ of the previous frame generated by. Each figure (c) shows the intensity distribution on the line of the corrected image data G ₂ ′ output from the corrected image data output unit 13.

When the image is moving to the right, the image data G _{1 of the} previous frame generated by the previous frame image data generation unit 12 (each figure (b)) is the image data of the current frame of the input image signal. It is obtained by shifting G ₂ (each figure (a)) to the left. The shift amount corresponds to the speed of image movement, that is, the amount of image movement per frame. When the image data moves in the two-dimensional coordinate system, the image data may be moved by the distance moved in the direction opposite to the moving direction of the image data of interest.

Focusing on the pixel in the center in the drawing (a) ~ (c), in the example shown in Figure 2, compared to the image data G ₁ of the target pixel in the previous frame before generated by the frame image data generating unit 12 Since the image data G ₂ of the target pixel in the current frame is large (FIGS. 4A and 4B), the corrected image data G ₂ ′ of the target pixel output from the corrected image data output unit 13 is the image It is data _{G 2} greater than (FIG. (c)). In the example shown in FIG. 3, the image data G ₂ of the target pixel in the current frame is smaller than the image data G ₁ of the target pixel in the previous frame generated by the previous frame image data generation unit 12 (the same (A), (b)), the corrected image data G ₂ ′ of the target pixel output from the corrected image data output unit 13 is set to a value smaller than the image data G ₂ ((c) in the figure). By inputting the image data G ₂ ′ corrected based on such overdrive technology to the liquid crystal display device 2, the actual display value in the liquid crystal display device 2 quickly reaches the target display value. The

As described above, when the image is moving in the line direction (lateral direction), processing can be performed for each line, so that the image data of the current frame of the input image signal is sequentially stored for one line. In addition, the image data of the previous frame generated by the previous frame image data generation unit 12 may be stored sequentially for one line. Therefore, the image signal processing apparatus 1 may be configured at low cost because a storage unit with a small storage capacity may be used.

FIG. 4 is a diagram illustrating another example of the corrected image data output from the corrected image data output unit 13 included in the image signal processing apparatus 1 according to the present embodiment. Here, it is assumed that the direction of motion of the image detected by the motion detection unit 11 is the vertical direction perpendicular to the line direction, and the image is moving downward. The intensity (value magnitude) of the image data is shown with the right direction of the line in FIG. At this time, the previous frame image data generation unit 12 converts the image data G ₂ of each line of the current frame of the input image signal into the original image data G ₂ of the line and the image data G _{1 of the} previous line. The image data G1 _one frame before is generated. Corrected image data output section 13, the image data G ₁ line changing this value, on the basis of one image data G ₂ of the line original after, corrects the image data G ₂ of the current frame.

The vertical axes in FIGS. 9A to 9C represent pixel positions on a certain column (a pixel arrangement in a direction perpendicular to the line) in the frame image. FIG (a) shows the distribution of luminance on the said column of the image data G ₂ in the current frame of the image signal input by a solid line, and the corrected image output from the corrected image data output section 13 The distribution of the data G ₂ ′ on the column is indicated by a broken line. Further, FIG. (B), (c), the the distribution of the said column of the previous frame image data generating unit 12 the image data G ₁ of the previous frame is generated by a solid line. Note that a storage unit that stores image data for three lines is used. The image signal processing apparatus 1, for each frame, the image data from the first line L ₁ to the M line L _M is input in the order of lines. M is the total number of lines.

At the time after the image data of the (m + 2) th line L _{m + 2} is input to the image signal processing apparatus 1, the image data of each of the three lines L _m to L _{m + 2} is stored in the storage unit. At the time after the image data of the next (m + 3) th line L _{m + 3} is input to the image signal processing apparatus 1, the image data of each of the _three lines L _{m + 1} to L _{m + 3} is stored in the storage unit. . This time, previous frame picture data generator unit 12, as shown in FIG. (B), the line L _{m +} a ₁ of the image data, the line L _{m + first} original image data G _{2, m + 1} and the preceding line by changing the value G _{1, m + 1} between the image data G _{1, m} of (upper line) _{L m,} and generates a one-frame preceding image data _{G 1, m + 1.} Furthermore, the corrected image data G based on the image data G _{1, m + 1 of} the line L _{m + 1} whose value has been changed and the original image data G _{2, m + 2 of the} next line (lower line) L _{m + 2} 'Generate _{2, m + 1} . This overdrive technique can be used for this correction.

At the time after the image data of the next (m + 4) th line L _{m + 4} is input to the image signal processing apparatus 1, the image data of each of the three lines L _{m + 2} to L _{m + 4} is stored in the storage unit. In this case, the previous frame image data generator 12, as shown in FIG. (C), line L _{m + 2} of the image data, the line L _{m + 2} of the original image data G _{2, m + 2} with the previous line by changing the value G _{1, m + 2} between the image data G _{1, m + 1} of the (upper _{line) L m + 1,} and generates a one-frame preceding image data _{G 1, m + 2.} Further, the corrected image data based on the image data G _{1, m + 2 of} the line L _{m + 2} whose value has been changed and the original image data G _{2, m + 3 of the} next line (lower line) L _{m + 3} G ′ _{2, m + 2} is generated. This overdrive technique can be used for this correction.

The previous frame image data generation unit 13 repeats the above processing every time image data for one line is input, so that the corrected image data G ₂ as indicated by a broken line in FIG. 'Can be generated. Further, by using a storage unit that stores image data for three lines, it is possible to cope with not only the case where the image moves downward but also the case where the image moves downward. As described above, when the image is moving in the direction perpendicular to the line direction, the image signal processing apparatus 1 may use a storage unit that stores image data for three lines, and thus can be configured at low cost.

The present invention can be used for an image signal processing apparatus that processes image data of each frame of an input image signal and then outputs the image signal to a liquid crystal display device.

Claims

An image signal processing device that outputs image signals to a liquid crystal display device after processing image data of each frame of an input image signal,
A motion detector for detecting the direction of motion of the image based on the image data of each frame of the input image signal;
A previous frame image data generation unit that generates image data of the previous frame based on the image data of the current frame of the input image signal and the direction of motion of the image detected by the motion detection unit;
Based on the current frame image data of the input image signal and the previous frame image data generated by the previous frame image data generation unit, the current frame image data of the input image signal is corrected. Then, the corrected image data output unit for outputting the corrected image data to the liquid crystal display device,
An image signal processing apparatus comprising:
The motion detection unit detects the direction and speed of image motion based on the image data of each frame of the image signal,
When the direction of motion of the image detected by the motion detection unit is a line direction, the previous frame image data generation unit, according to the direction and speed of motion of the image detected by the motion detection unit, By shifting the image data of the current frame of the input image signal in the line direction, the image data of the previous frame is generated,
The image signal processing apparatus according to claim 1.
When the direction of motion of the image detected by the motion detector is a direction perpendicular to the line direction, the previous frame image data generator generates image data of each line of the current frame of the input image signal. The image data of the previous frame is generated by changing to a value between the original image data of the line and the image data of the previous line.
The image signal processing apparatus according to claim 1.