JP2005215129A - Liquid crystal display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a low-cost resizing means without generation of flickers, minimizing deterioration of the acute feeling of edges, when the number of scanning lines of an input video image is converted into the number of scanning lines of a liquid crystal panel. <P>SOLUTION: The liquid crystal display which displays a static image on the liquid crystal panel, having scanning lines fewer than the number of scanning lines of the inputted video image, is constituted of a first thinning means for performing scanning line thinning processing according to conversion ratio of the scanning lines; a second thinning means set such that a thinning position is different from that of the first thinning means and for performing scanning line thinning processing according to the conversion ratio of the scanning lines; a first horizontal period expansion means for expanding a horizontal period of an output signal of the first thinning means, according to the conversion ratio of the scanning lines; a second horizontal period expansion means for expanding a horizontal period of an output signal of the second thinning means, according to the conversion ratio of the scanning lines; and a video mixing means for adding the output signal of the first horizontal period expansion means and the output signal of the second horizontal period expansion means with the predetermined mixing ratio. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a display device for displaying an image on a liquid crystal panel, and particularly to an image resizing method when the number of scanning lines of a liquid crystal panel is smaller than the number of scanning lines of an input image.

  A liquid crystal panel is generally used as a display device for portable video equipment such as a digital video camera. Since these devices display recorded images on a television, video recording is performed by a method in accordance with a local broadcast standard. For example, in Japan, the NTSC format has 525 scanning lines, and in Europe, the PAL format has 625 scanning lines. However, in order to reduce the cost by standardization, in general, a liquid crystal panel having a common number of scanning lines is used instead of a panel having the number of scanning lines according to the region. For this reason, resizing processing according to each broadcasting system is required to display images correctly.

  In the conventional product form, the liquid crystal panel is generalized according to the number of scanning lines of NTSC, and the display in the PAL system is generally performed by a method called thinning-out driving of the liquid crystal panel for simple resizing. Met.

  FIG. 22 shows a display form in the PAL system in a conventional general product, and at the same time, shows the principle of thinning driving of the liquid crystal panel.

  Now, assuming that the number of scanning lines of the liquid crystal panel is 240 and the number of effective scanning lines during one field period of PAL is 288, it is necessary to convert the image of 288 lines into 240 lines in order to correctly display a perfect circle on the liquid crystal panel. However, FIG. 22 shows a conventional principle of displaying an 8-line image on a liquid crystal panel having 7 scanning lines for easy understanding.

  As shown in FIG. 22, when the number of scanning lines of the input image is larger than the number of scanning lines of the liquid crystal panel, the entire image is displayed by thinning the driving of the liquid crystal according to the conversion ratio of the number of scanning lines. At this time, important information may be lost as shown in FIG. In the example of FIG. 22, it can be seen that an important line of the original letter A is lost.

  In order to improve this, the thinning position is changed for each field as shown in FIG. 23, and the original information is stored as much as possible by the integration effect of the human eye as shown in FIG.

  The above display method is shown as a specific example in Japanese Patent Laid-Open No. 9-73061 (hereinafter referred to as Document 1).

Reference 1 further shows a method for solving the problem of line inversion that occurs when displaying an interlaced image of 576 lines per frame on a liquid crystal panel having 480 scanning lines. This is a conversion method, and the principle of fundamental scanning line conversion is the same as that in the examples of FIGS.
JP-A-9-73061

  The method shown in FIG. 22 to FIG. 24 and the method shown in Document 1 do not require a special circuit and can realize resize display easily and inexpensively.

  However, in this case, since the image changes for each field, there is a problem that flicker occurs and the display quality is impaired.

  In order to improve this, a method of performing vertical filter processing is also generally performed. However, when the input image is not a natural image and is character information, the edge of the character is blurred by the filter processing and the sharpness is lost. The problem that occurs.

  The present invention has been made in order to improve the above-described problems. When the number of scanning lines of an input video (particularly a still image such as a character) is converted into the number of scanning lines of a liquid crystal panel, flicker does not occur. Furthermore, the present invention provides resizing means for minimizing the deterioration of the edge sharpness.

  A first means for solving the above problem is that in a liquid crystal display device that displays a still image on a liquid crystal panel having fewer scanning lines than the number of scanning lines of the input video, the scanning lines according to the conversion ratio of the scanning lines. A first thinning means for performing thinning processing; a second thinning means for performing scanning line thinning processing according to a conversion ratio of the scanning lines, which is set so that a thinning position is different from that of the first thinning means; The output signal of the first thinning means is changed to the conversion ratio of the scanning line, the first horizontal period extending means for extending the horizontal period in accordance with the conversion ratio of the scanning line, and the output signal of the second thinning means. A second horizontal period extending means for extending the horizontal period in response, and a video mixing means for adding the output signal of the first horizontal period extending means and the output signal of the second horizontal period extending means at a predetermined mixing ratio. It consists of.

  A second means for solving the above problems is a liquid crystal display device that displays a still image on a liquid crystal panel having fewer scanning lines than the number of scanning lines of the input video, a frame memory that holds the input video, and a liquid crystal panel The first video generation means for generating the first still image while thinning out the scanning lines read out from the frame memory in accordance with the number of scanning lines, and the scanning lines read out from the frame memory in accordance with the number of scanning lines of the liquid crystal panel. A second video generating means for generating a second still image at a second thinning position different from the thinning position of the information generating means, an output signal of the first video generating means, and a second video generating means It comprises video mixing means for adding output signals at a predetermined mixing ratio.

  In the first means of the present invention, both the thinned video of the first field and the thinned video of the second field can be obtained at the same time by using only two line memories. Since processing can be performed, resizing processing can be performed without flickering and blurring of vertical edges. In particular, when the input is a still image, the data of both the thinned video of the first field and the thinned video of the second field can be obtained at the same time, not in a pseudo manner, so that the effect is increased and the input video is a character such as OSD. In the case of information, there is a further effect.

  The second means of the present invention has the same effect as the first means.

(Embodiment 1)
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a first embodiment of the present invention. In this embodiment, a natural image (first input video) taken by a camera as an input image and a still image (second input) mainly composed of character information having the same scanning line as the first input video. Video) is input together with display / non-display switching information (hereinafter referred to as a display enable signal), and this does not cause flickering on the liquid crystal panel that is smaller than the number of scanning lines of the input video and minimizes the reduction in sharpness. An example of a liquid crystal display device to be displayed will be described.

  In FIG. 1, reference numeral 1 denotes vertical resizing means for converting the number of scanning lines of a first input image into the number of scanning lines of a liquid crystal panel. In this embodiment, when the conversion ratio of scanning lines is 5: 4, for example, It is assumed that the cycle is extended so as to be 4: 5 as shown in FIG. Here, for the sake of convenience, it is assumed that the vertical resizing means 1 outputs the input signal with a delay of one horizontal cycle period (hereinafter simply referred to as 1H) with respect to the input horizontal cycle as shown in FIG. Here, the vertical resizing means does not have to be particularly special, and even a commonly used means does not affect the effect of the present invention, and thus detailed description thereof is omitted.

  Reference numeral 2 denotes first scanning line thinning means for thinning and outputting the (2 + 5 · N) -th line (N is an integer of 0 or more) of the second input video as shown in FIG. A simple circuit is shown in FIG. 4, reference numeral 21 denotes a first 1H delay circuit that outputs a second input signal after being delayed by 1H, and reference numeral 22 denotes a first input video signal and the output of the first 1H delay circuit 21 shown in FIG. This is a first selector that switches and outputs in response to a select signal. By switching the first selector by the first select signal shown in FIG. 3, the output signal of the first scanning line thinning means shown in FIG. 3 can be obtained by the circuit shown in FIG.

  Reference numeral 3 denotes a second scanning line thinning means for thinning and outputting the (4 + 5 · N) -th line (N is an integer of 0 or more) of the second input video as shown in FIG. A simple circuit is shown in FIG. In FIG. 6, reference numeral 31 denotes a second 1H delay circuit that outputs the second input signal after being delayed by 1H, and reference numeral 32 denotes a second input video signal and the output of the second 1H delay circuit 31 shown in FIG. This is a second selector that switches and outputs in response to a select signal. By switching the second selector by the second select signal shown in FIG. 5, the output signal of the second scanning line thinning means shown in FIG. 5 can be obtained by the circuit shown in FIG. Here, the video signal output from the first scanning line thinning means 2 corresponds to the video signal obtained by the thinning process of the first field, and the video signal output from the second scanning line thinning means 3 is the first. This corresponds to a video signal obtained by thinning out one field. That is, at this stage, the first field image and the second field image are obtained at the same time.

  Reference numeral 4 denotes first horizontal period extending means for extending and outputting the horizontal period of the output of the first scanning line thinning means 2 as shown in FIG. 7, and a specific circuit for realizing this is shown in FIG. FIG. 7 shows timing signal waveforms (first write enable signal and first read enable signal) for controlling the circuit of FIG. In FIG. 8, reference numeral 41 denotes a first line memory for holding 1H period data of an input first scanning line thinning means output signal. This line memory is write-controlled (written when “H”) by the first write enable signal shown in FIG. 7, and read-controlled (read when “H”) by the first read enable signal. As a result, a signal in which the horizontal period of FIG. 7 is extended can be obtained. Here, the ratio of the horizontal period extension is assumed to be extended and output so that the horizontal period becomes 4: 5 when the conversion ratio of the scanning line is, for example, 5: 4, as in the vertical resizing means.

  Reference numeral 5 denotes second horizontal period extending means for extending and outputting the horizontal period of the output of the second scanning line thinning means 3 as shown in FIG. 9, and a specific circuit for realizing this is shown in FIG. FIG. 9 shows timing signal waveforms (second write enable signal and second read enable signal) for controlling the circuit of FIG. In FIG. 10, reference numeral 51 denotes a second line memory for holding 1H period data of the input second scanning line thinning means output signal. The line memory is write-controlled (written when “H”) by the second write enable signal shown in FIG. 9, and read-controlled (read when “H”) by the second read enable signal. As a result, a signal in which the horizontal period of FIG. 9 is extended can be obtained. Here, the ratio of the horizontal period extension is assumed to be extended and output so that the horizontal period becomes 4: 5 when the conversion ratio of the scanning line is, for example, 5: 4, as in the vertical resizing means. The first and second horizontal extending means convert the same scanning line and the same horizontal period as the output of the vertical resizing means 1.

  6 corresponds to the video signal output from the vertical resizing means 1, the video corresponding to the first field output from the first horizontal period extending means, and the second field output from the second horizontal period extending means. A video mixing unit that mixes video at a predetermined mixing ratio. Specifically, a display enable signal (hereinafter referred to as a first display enable signal) output from the first horizontal period extending unit 4 together with a video and a first A display enable signal (hereinafter referred to as a second display enable signal) output together with the video from the two horizontal period extending means 5 is multiplied by the mixing coefficient of the three video signals (respectively, the video output from the vertical resize processing means). The multiplication coefficient is multiplied by the first mixing coefficient, the multiplication coefficient multiplied by the image of the first horizontal period extending means output is the second mixing coefficient, and the output of the second horizontal period extending means is output. A multiplication ratio generating circuit 61 that outputs a multiplication coefficient multiplied by the image is referred to as a third mixing coefficient), a multiplier 62 that multiplies each of the three video signals and the three mixing coefficients, a multiplier 63, and a multiplier 64, and an adder 65 for adding the outputs of the three multipliers.

  Here, when the first display enable signal is ON and the second display enable signal is ON, the mixing ratio generation circuit 61 outputs 0 as the first mixing coefficient, and the second and third mixing coefficients. 0.5 is output. When the first display enable signal is ON and the second display enable signal is OFF, the first mixing coefficient is output as 0.5, the second mixing coefficient is output as 0.5, 0 is output as the third mixing coefficient. When the first display enable signal is OFF and the second display enable signal is ON, the first mixing coefficient is output as 0.5, the second mixing coefficient is output as 0, and the third A mixing coefficient of 0.5 is output. Further, when the first display enable signal is OFF and the second display enable signal is OFF, 1 is output as the first mixing coefficient, and 0 is output as the second and third mixing coefficients. It has become.

  A liquid crystal panel 7 displays the first and second input images.

  Next, the operation of the liquid crystal display device configured as described above is such that the first input image is a single image shown in FIG. 11 (shown by hatching to distinguish it from the second image), and the second input image is The case of the character information shown in FIG. 12 will be described as an example. In order to simplify the explanation, the number of data of the first and second input images is 12 pixels horizontal and 10 lines vertical, and the liquid crystal panel on which this data is displayed is 12 pixels horizontal and 8 lines vertical. In FIG. 12, the display enable signals for the pixels shown in black are all turned on, and the display enable signals for the pixels other than those are all turned off (that is, the pixels display the first video).

  In the case of this example, since the number of input scanning lines is converted into the number of scanning lines of the liquid crystal panel, the conversion ratio is 5: 4, and the conversion ratios shown in FIGS. 2, 3, 5, 7, and 9 are used. It becomes the same waveform as the timing waveform diagram. That is, the thinning line in the first scanning line thinning means is described as the 2 + 5 · Nth line, and the thinning line in the first scanning line thinning means 2 is described as the 4 + 5 · Nth line. When the first input video is a single video, the output is single even if the resize processing is performed, and the output of the vertical resize processing means 1 is the video shown in FIG. Next, the output waveform of the first scanning line thinning means 2 is thinned out from the input second line and the seventh line, and as shown in FIG. 3, the invalid line, the input first line, the input third line, The fourth output line, the fifth input line, and so on are output in this order. That is, the image is as shown in FIG.

  Next, the output waveform of the second scanning line thinning means 3 is thinned out from the fourth line and the ninth line, and as shown in FIG. 5, the invalid line, the first input line, the second input line, The third output line, the fifth input line, and so on are output in this order. That is, the image is as shown in FIG. Next, the output waveform of the first horizontal period extending means 4 is expanded in the horizontal period as shown in FIG. 7, and is output as an image shown in FIG. Similarly, the output waveform of the second horizontal period extending means 5 is expanded in the horizontal period as shown in FIG. 9, and is output as an image shown in FIG. 14 (C).

  Here, in the conventional scanning line conversion method by thinning driving of liquid crystal shown in FIGS. 22 to 24, the second input video in FIG. 11 is one field of the image of FIG. 14B and the image of FIG. 14C. This is equivalent to an image displayed alternately every time. That is, when the field frequency of the input video is 50 Hz, a line where data is displayed and a line where data is not displayed are recognized as 25 Hz flicker. The video mixing means 6 of the present invention mixes and outputs in advance the image of FIG. 14B, the image of FIG. 14C, and further the image of FIG. 14A obtained by scanning line conversion of the first input video. To do. As a result, it is possible to display an image without flicker.

  This operation will be described by extracting the sixth line of the image shown in FIG. FIG. 15 shows the signals on the sixth line of FIGS. 14A, 14B, and 14C. In FIG. 15, FIG. (C) is the output data of the first horizontal period extending means 4 of the first horizontal period extending means 4, (D) is the first display enable signal, (E) is the second mixing coefficient, (F) is the output data of the second horizontal period extending means 5, (G) is the second display enable signal, (H) is the third mixing coefficient, and (I) is the output data of the video mixing means 6. It is. In FIG. 15, since the first pixel data is “L” in the first pixel data, the first mixing coefficient corresponding to the image output from the vertical resizing means 1 is 1, and the first pixel data Since the second and third mixing coefficients corresponding to the data output from the second horizontal period extending means 4 and 5 are 0, only the video output from the vertical resizing means 1 is output from the video mixing means 6. Is output. In the third pixel data, since the first and second display enable signals are both “H”, the first mixing coefficient corresponding to the image output from the vertical resizing means 1 is 0, and the first and second display enable signals are zero. Since the second and third mixing coefficients corresponding to the data output from the two horizontal period extending means 4 and 5 are 0.5, the first and second horizontal period extending means 4 from the video mixing means 6. And 5 are added at a mixing ratio of 0.5 and output.

  By such an operation, the sixth line of the image shown in FIG. 14 becomes the data shown in FIG. FIG. 16 shows a video image output from the video mixing means 6 by such an operation. This image is equal to the image obtained by integrating the image of the first field and the image of the second field, which is displayed by the conventional scanning line conversion method by thinning-out liquid crystal, with the human eye, and the second input image is a still image. In this case, since the same image display is made in all fields, flicker does not occur.

  Here, when the second video is character information, data that is originally black, such as data on the sixth line in FIG. 16, may be mixed with other data, and the original character quality may be lost. This can be improved by increasing the mixing coefficient for a specific color. FIG. 17 shows the second video mixing means 60 for increasing the mixing coefficient of a specific color. In FIG. 17, reference numeral 66 denotes a first signal for detecting the black level of the output signal of the first horizontal period extending means 4 and outputting a signal for correcting the first mixing coefficient so that the mixing ratio increases in accordance with the level. The black level detecting means 67 detects the black level of the output signal of the first horizontal period extending means 5 and outputs a second signal for correcting the second mixing coefficient so that the mixing ratio increases according to the level. The black level detecting means 68 and 69 are multipliers for correcting the mixing coefficient.

  In the example of FIG. 17, the mixing coefficient is increased when the data is black. FIG. 18 shows a display image of the image of FIG. 16 with this configuration. FIG. 18A shows an image when the black data mixing coefficient is slightly increased, and FIG. 18B shows an image when the black data mixing coefficient is further increased. As described above, with respect to data for which the sharpness of the edge is desired to be preserved (black data in FIG. 17), the display quality can be improved by increasing the mixing coefficient of the data. Here, an example of increasing the black data mixing coefficient has been shown, but this differs depending on the product form. This is because, for example, the second input image is character-based information, and red may be emphasized or blue may be emphasized depending on the color constituting the character. This is different for each product, and the color to be emphasized may be changed according to the character display form.

  As described above, in this embodiment, data of two fields by the conventional liquid crystal scanning line thinning drive display can be mixed and output in one field (processing equivalent to field interpolation), so that video can be displayed without occurrence of flicker. In addition, the display quality can be further improved by changing the mixing coefficient for a specific color.

  In the first embodiment, the thinning position by the first scanning line thinning means is 2 + 5 · N (N is an integer of 0 or more), and the thinning position by the second scanning line thinning means is 4 + 5 · N (N is 0 or more). However, it is not necessary to limit the position to this position. Although it is desirable to set the thinning position as equal as possible, the thinning position of the first scanning line thinning means and the second scanning line thinning means is If they are not identical, the same effect can be obtained. It is clear that this thinning position varies depending on the scanning line conversion ratio.

  FIG. 21 is a block diagram of the first and second scanning line thinning means and the first and second horizontal period extending means shown in FIG. Since the first scanning line thinning means and the second scanning line thinning means can be realized by the same configuration as shown in FIGS. 4 and 6, in practice, one 1H delay circuit and two selectors are used as shown in FIG. realizable.

  Further, as shown in FIGS. 7 to 10, since the first horizontal cycle extending means and the second horizontal cycle extending means can be realized by the same control pulse (the write enable signal and the read enable signal are common), One control circuit can be provided. As described above, the circuit of FIG. 21 has an advantage that the interpolation process in the field direction can be realized at low cost by using only three memories that hold data of 1H period without using an expensive field memory.

(Embodiment 2)
FIG. 19 is a diagram showing a second embodiment of the present invention. In FIG. 19, 8 is a field memory that holds the second input image and the display enable signal of the second input image for one field period, and 9 is a scanning line between the field memory 8 and the number of scanning lines of the liquid crystal so as to match. First image generating means 10 for reading out the subtracted first field liquid crystal display image, 10 designates the second field liquid crystal display image in which the scanning lines are thinned out from the field memory 8 so as to coincide with the number of liquid crystal scanning lines. It is the 2nd image generation means to read. Here, the thinned-out positions of the input video in the first video generating means and the second video generating means are the same as those of the first scanning line thinning means and the second scanning line thinning means shown in the first embodiment, respectively. .

  FIG. 20 shows an output waveform diagram in the case where the scanning line ratio between the second input image and the liquid crystal panel is 5: 4. This waveform diagram operates so as to be the same as the outputs of the first horizontal period extending means and the second horizontal period extending means. The following operations and configurations of the video mixing unit 6 and the vertical resizing unit 1 are the same as those in the first embodiment.

  In the first embodiment, the first field video and the second field video displayed on the liquid crystal are generated from the input video by the memory for storing the video for one line and the means for extending the horizontal period. In the example, only the field memory for storing the video of one field is realized instead of these, and other operations are not changed. Therefore, if the character information shown in FIG. 12 is input, the images shown in FIGS. 16 and 18 are displayed. That is, also in the second embodiment, the image mixing means can display the image without flicker and without damaging the sharpness of the edge as much as possible.

  The liquid crystal display device according to the present invention is capable of inexpensive, flickerless, and high-quality display on a liquid crystal panel with different scanning lines from the input video, and has a particularly advantageous effect on character display, and can be broadcast at a low cost in each region. It is useful as a display device such as a digital video camera that requires display corresponding to the above.

The block diagram which shows the liquid crystal display device by the 1st means of this invention Timing waveform diagram for explaining the operation of the vertical resizing means according to the first means of the present invention. Timing waveform diagram for explaining the operation of the first scanning line thinning means according to the first means of the present invention. The block diagram which shows the specific example of the 1st scanning line thinning-out means by the 1st means of this invention Timing waveform diagram for explaining the operation of the second scanning line thinning means in the first means of the present invention. The block diagram which shows the specific example of the 2nd scanning line thinning-out means by the 1st means of this invention Timing waveform diagram for explaining the operation of the first horizontal period extending means according to the first means of the present invention. The block diagram which shows the specific example of the 1st horizontal period expansion means by the 1st means of this invention Timing waveform diagram for explaining the operation of the second horizontal period extending means according to the first means of the present invention. The block diagram which shows the specific example of the 2nd horizontal period expansion means by the 1st means of this invention The figure which shows the input image image for demonstrating operation | movement of the liquid crystal display device by the 1st means of this invention The figure which shows the input image image for demonstrating operation | movement of the liquid crystal display device by the 1st means of this invention The figure which shows the output image image of the 1st and 2nd scanning line thinning-out means by the 1st means of this invention The figure which shows the output image image of the 1st and 2nd horizontal period expansion means by the 1st means of this invention The figure which shows the image image explaining operation | movement of the image | video mixing means by the 1st means of this invention The figure which shows the image image explaining operation | movement of the image | video mixing means by the 1st means of this invention The block diagram which shows the other specific example of the video mixing means by the 1st means of this invention The figure which shows the image image explaining the operation | movement by the other specific example of the image | video mixing means by the 1st means of this invention. The block diagram which shows the liquid crystal display device by the 2nd means of this invention Timing waveform diagram for explaining the operation of the first and second video generation means according to the second means of the present invention. The block diagram which shows the specific Example of the liquid crystal display device by the 1st means of this invention Timing waveform diagram explaining the operation of a conventional liquid crystal display device Timing waveform diagram explaining the operation of a conventional liquid crystal display device The figure which shows the image image explaining operation | movement of the conventional liquid crystal display device

Explanation of symbols

2 First scanning line thinning means 3 Second scanning line thinning means 4 First horizontal cycle extending means 5 Second horizontal cycle extending means 6 Video mixing means 7 Liquid crystal panel 8 Field memory 9 First video generating means 10 Second video generation means

Claims (6)

In a liquid crystal display device that displays the number of scanning lines different from the number of scanning lines of the input video,
A first thinning means for performing scanning line thinning processing in accordance with a scanning line conversion ratio; a second thinning means for performing scanning line thinning processing so that a thinning position differs from that of the first thinning means; and the first The output signal of the thinning-out means extends the horizontal period in accordance with the conversion ratio of the scanning line, and the output signal of the second thinning-out means in the horizontal direction in accordance with the conversion ratio of the scanning line. Second horizontal cycle extending means for extending the period, and video mixing means for adding the output signal of the first horizontal cycle extending means and the output signal of the second horizontal cycle extending means at a predetermined mixing ratio. A liquid crystal display device. 2. The liquid crystal display device according to claim 1, wherein the first and second thinning means are composed of a line memory for delaying the input video by one horizontal period and a switching means for switching the line memory and the input video. In a liquid crystal display device that displays the number of scanning lines different from the number of scanning lines of the input video,
A frame memory that holds an input video, a first video generation unit that generates a first video by thinning in accordance with the number of scanning lines for displaying scanning lines read from the frame memory, and a first information generation unit Second video generation means for generating a second video by thinning out the scanning lines read from the frame memory in accordance with the number of scanning lines at a second thinning position different from the thinning position; and the first video A liquid crystal display device comprising: an output signal of the generating means and an image mixing means for adding the output signal of the second image generating means at a predetermined mixing ratio. A liquid crystal display device for simultaneously displaying a moving image and a still image with a number of scanning lines different from the number of scanning lines of an input video, further comprising moving image resizing means by signal processing, and in addition to the two input signals of the video mixing means, the moving picture 4. The liquid crystal display device according to claim 1, wherein the output signal of said resizing means is further added at a predetermined mixing ratio. 4. The liquid crystal display device according to claim 1, wherein the still image is character data. 4. The liquid crystal display device according to claim 1, wherein the video mixing means increases the mixing ratio of only a specific color signal of the still image signal.

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