JPH088673B2 - Liquid crystal drive - Google Patents

Description

The present invention relates to a liquid crystal drive device for driving a dot matrix liquid crystal display panel.

[Prior Art] Conventionally, a dot matrix liquid crystal display panel is generally used for a display unit of a small portable television receiver or the like. Since the television image must be displayed every 17 [mS] (= 1/60 [s]), the response speed of the liquid crystal display panel is inevitably desired to be sufficiently higher than 17 [mS]. However, the response speed of liquid crystal display panels at present is
It is about 50 [mS] to 100 [mS], and there is a drawback that afterimages are visible when displaying a moving image.

Therefore, the following method has been conceived as a liquid crystal driving device that improves the response speed and eliminates the afterimage. That is, focusing on one pixel in the liquid crystal display panel, 1F (frame: “frame” in the specification of the present application means that all the picture elements that constitute one screen are scanned one by one, for example, a TV signal). In the case of displaying by scanning all the picture elements that make up one screen for each one field, it is considered that one field of the TV signal is equal to one frame referred to in the present application.
It does not necessarily match the "frame" of the signal. ), The image data is refreshed. It is well known that a liquid crystal display panel has a cumulative response, but if this cumulative response is expressed as a mathematical model, y _n = (1-K) x _n + Ky _n-1 (1) (where K : constant x _n: input image data y _n: an output image data (data to be displayed)). When this equation (1) is Z-transformed, Y (z) = (1-K) X (z) + KZ- ¹ Y (z) Y (z) = (1-K) X (z) / (1-KZ ^-1 ) ……
(2) (However, it is a delay operator for Z ^-1 : 1 frame). Therefore, the transfer function H of the liquid crystal display panel
(Z) can be considered as H (z) = (1−K) / (1−KZ ⁻¹ ) (3). Here, if the signal is preprocessed with a transfer function opposite to the transfer function of the liquid crystal display panel, the response speed of display can be improved. That is, X (z) = (1-KZ ^-1 ) W (z) / (1-K) ...
(4), and when this (4) a Z inverse transform equation, thereby obtaining a _{x n = (w n -Kw n} -1) / (1-K) ...... (5) becomes equation. The signal obtained in this way
Since the amplitude of x _n becomes large and it is impossible to display it on the liquid crystal display panel as it is, it is necessary to make the amplitudes of x _n and w _n equal by a limiter.

[Problems to be Solved by the Invention] However, the signal x _n obtained as described above is effective in improving the response of a fast-moving image, but on the other hand, it has little motion and is close to a still image. Since a slight change is emphasized in the image, there is a problem that noise increases.

The present invention has been made in view of the above situation, and by always compensating an image signal in an appropriate state, the response speed is improved so that an afterimage is not visible when the image changes greatly. On the other hand, it is an object of the present invention to provide a liquid crystal driving device that does not generate noise when an image change is small.

[Means and Actions for Solving the Problem] The present invention detects whether or not a change in data in a specific pixel is greater than or equal to a certain set value, and when the variation is greater than or equal to a certain set value, “0 <K < If the value is less than the set value in the range of "1", the value of the constant K is variably set in the range of "-1 <K <0", and this constant K is used to convert the data of the nth frame to the n-1th frame. 1 / (1 after subtracting K times the frame data
-K), and the liquid crystal display panel is driven using the obtained processed data, so that it is possible to obtain an image in which the occurrence of afterimages and noise is significantly reduced.

Embodiments Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a circuit configuration of one embodiment. An analog video input signal is quantized by an A / D converter 11 in pixel units of N × M dots, and a 1-frame delay circuit 12 as a digital signal w _n. Is sent to the + input side of the subtractor 13. The 1-frame delay circuit 12 receives the input signal w _n for 1 frame, 17 [mS]
Then, the signal is delayed by only and output to the multiplier 14 as a signal w _n-1 . The multiplier 14 multiplies the signal w _n-1 by K to obtain Kw _n-1 , and the subtracter 13
-Send to the input side. The subtractor 13 subtracts w _n -Kw _n-1 from the signal w _n from the A / D converter 11 and the signal Kw _n-1 from the subtractor 13, and outputs the difference to the multiplier 15. The multiplier 15 multiplies the input signal by 1 / (1-K) and sends it to the limiter 16. The limiter 16 uses the above-mentioned A / D converter 1 for the received signal.
When the amplitude of the output signal w _n of 1 is exceeded, this is limited by calculation, and the output is sent to the segment driver 17 as the signal x _n . The segment driver 17 drives a segment electrode of a liquid crystal display panel (LCD) 18 according to the signal x _n . The common electrode of the liquid crystal display panel 18 is driven by the common driver 19, and the liquid crystal display panel 18, the common driver 19 and the A / D converter 11 are used.
Both operate in synchronization with the timing signal sent from the timing signal generation circuit 20.

Then, the digital signal w _n output from the A / D converter 11 is also sent to the motion detection circuit 21. The signal x _n output from the limiter 16 is delayed by one frame by the one-frame delay circuit 22 and input to the motion detection circuit 31.
It is determined whether or not the change (movement) of the image of the pixel is large by subtracting the two signals w _n and x _n−1 having the time difference of the frame. The motion detection circuit 21 variably sets the value of the constant K in accordance with the result of the determination, and the multiplier 14 and the multiplier 15 described above.
Send to.

For example, a digital signal w _n output from the A / D converter 21 and a signal x _n-1 obtained by delaying the signal input to the segment driver 17 by one frame by the one-frame delay circuit 22 are the luminance components of the video signal. Since it is represented by data having a weight of m bits, it is determined whether or not the change in the image is large depending on whether or not these differences are equal to or more than a predetermined bit. When it is determined that the change in the image is large, the motion detection circuit 21 multiplies the preset constant K in the range of “0 <K <1” by the multiplier.
14, sent to the multiplier 15. Therefore, the 1-frame delay circuit 12, the subtractor 13, the multiplier 14, the multiplier 15, and the limiter 16
Then, after the signal processing for emphasizing the image change is applied to the image data, it is output to the segment driver 17. Therefore, the image displayed on the liquid crystal display panel 18 has no afterimage, and the response speed is improved. In this case, as the value of the constant K approaches “1”, the degree of emphasis increases.

When the motion detection circuit 21 determines that the change in the image is small, the motion detection circuit 21 sends the preset constant K to the multipliers 14 and 15 in the range of “−1 <K <0”. To do. Therefore, the 1-frame delay circuit 12, the subtractor 13, the multiplier 14, the multiplier 15, and the limiter 16 perform signal processing for weakening the image change on the image data, and then, the segment driver
Output to 17. Therefore, the image displayed on the liquid crystal display panel 18 has less noise.

FIG. 2 shows the frequency and amplitude of the signal x _n processed by the constant K output from the motion detection circuit 21 and input to the segment driver 17. Motion detection circuit
When 21 determines that the change in the image is large, “0 <K <
As a result of processing using the constant K output in the range of “1”,
The higher the frequency of the signal X _n , the larger the amplitude. On the other hand, when the motion detection circuit 21 determines that the change in the image is small, the signal X _n is processed by using the constant K output in the range of “−1 <K <0”. The degree of is small. This is because the transfer function H (z) of the liquid crystal display panel is as shown in the above equation (3), and Z ⁻¹ = e ^−jwT (6) is substituted into the equation (3). Looking at the frequency characteristics, The following expression is obtained, and when the value of K is in the range of “0 <K <1”, it is a high-pass filter characteristic, and the value of K is in the range of “−1 <K <0”. In some cases, the characteristics are like a low pass filter. As described above, when the change in the image is large, the response is improved to prevent the occurrence of the afterimage, and when the change in the image is small, the generation of the noise is prevented. can get.

[Effects of the Invention] As described in detail above, according to the present invention, it is detected whether or not a change in data in a specific pixel is greater than or equal to a certain set value, and if it is greater than or equal to a certain set value, "0 <K If the value is less than the set value in the range of <1 ”, the value of the constant K is variably set in the range of“ −1 <K <0 ”, and the constant K is used to convert the data of the nth frame to the n−th frame. K of 1 frame data
Since the multiplication is subtracted and then 1 / (1-K) is multiplied, the obtained processed data is used to drive the liquid crystal display panel.
It is possible to provide a liquid crystal drive device capable of obtaining an image in which the occurrence of afterimages and noise is significantly reduced.

[Brief description of drawings]

The drawings show an embodiment of the present invention. FIG. 1 is a block diagram showing a circuit configuration, and FIG. 2 is a diagram showing characteristics of frequency and amplitude. 11 …… A / D converter, 12,22 …… 1 frame delay circuit, 13…
… Subtractor, 14, 15 …… Multiplier, 16 …… Limiter, 17 ……
Segment driver, 18 …… Liquid crystal display panel, 19 …… Common driver, 20 …… Timing signal generation circuit, 21 ……
Motion detection circuit.

Claims (1)

[Claims] 1. A liquid crystal drive device for displaying a video signal on a liquid crystal display panel having a cumulative response, and a detection means for detecting whether or not a change in data in a specific pixel is equal to or more than a set value. When the change of the data by the detecting means is equal to or more than a set value, the constant K is in the range of “0 <K <1”, and when it is less than the set value, the constant K is in the range of “−1 <K <0”. Using the setting means for variably setting the value and the constant K output from the setting means, K times the data of the (n-1) th frame is subtracted from the data of the nth frame and then multiplied by 1 / (1-K). A liquid crystal driving device comprising: a processing means, wherein the processing means drives the liquid crystal display panel using the processed data.