JPH08227108A - Liquid crystal image forming method and liquid crystal image forming device - Google Patents

Abstract

PURPOSE: To form and provide bright and clear images by obtaining the resolution higher than the pixel density of a liquid crystal panel. CONSTITUTION: The liquid crystal panel first comes into contact with a piezoelectric element like (A) and a stationary plate is put into a state of maintaining contact with the piezoelectric element (reference position). The liquid crystal panel is moved in an (x, 0) direction (first movement position) when only the piezoelectric element for moving in an X direction acts like (B). Further, the liquid crystal panel is moved together with a block material and the stationary plate in a (0, y) direction (second movement position) when only the piezoelectric element for moving in a Y direction acts like (C). Finally, the liquid crystal panel is eventually moved in the (x, y) direction (third movement position) when both of the piezoelectric elements act like (D). Namely, the one image is exposed in the reference position and is then moved to the respective positions (third position) and is subjected to exposing, by which the images are formed and 4-times higher resolution is obtd.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal image forming method and a liquid crystal image forming apparatus, and more particularly to a liquid crystal image forming method and a liquid crystal image forming method in which an image is formed by controlling the degree of transmission of each pixel arranged vertically and horizontally. Forming apparatus

[0002]

2. Description of the Related Art Conventionally, there has been a liquid crystal display device applied to a television monitor or the like. A liquid crystal display device is assembled by using a liquid crystal panel as a main component. This liquid crystal panel is applied to a printer that displays a digital image and projects the transmitted image onto a photosensitive material for printing.

However, particularly in printers, high quality display functions such as high resolution, high gradation and high contrast are required, and these are determined by the pixel density of the liquid crystal panel. Therefore, it is impossible to expect a resolution higher than the pixel density of the applied liquid crystal panel. In particular, when forming a small image such as an index print used as a heading of a plurality of image frames recorded on a photographic film, the deterioration of resolution becomes remarkable.

One of the factors limiting the pixel density of a liquid crystal panel
The first is to secure the wiring space required for the liquid crystal panel. On the other hand, in a CCD sensor that can be wired in the thickness direction, high density images can be obtained because the density can be increased. As related technology of this CCD sensor, CC
There is a technique in which the CCD is gradually shifted when an image is read by the D sensor to artificially realize a reading resolution higher than the pixel density (Japanese Patent Laid-Open No. 58-111580, etc.).

[0005]

However, in the above-mentioned prior art, since the CCD can be wired in the thickness direction as described above, a reading resolution higher than the pixel density can be realized.
It cannot be applied to a structure such as a liquid crystal panel, that is, a structure utilizing transmitted light. It should be noted that due to improvement in wiring technology, even when applied to a liquid crystal panel used for a printer or the like, color mixture may occur on a print obtained, and the resolution is also affected. Therefore, it is possible to simply use the above technology. Can not.

In view of the above facts of the present invention, it is an object of the present invention to obtain a liquid crystal image forming method and a liquid crystal image forming apparatus capable of realizing a clear image by obtaining a resolution higher than the pixel density of a liquid crystal panel.

[0007]

According to another aspect of the present invention, there is provided a liquid crystal image forming method, wherein a liquid crystal panel including a plurality of pixel groups arranged vertically and horizontally at a predetermined pitch is exposed at a reference position, and then at least 1. It is characterized in that the exposure is performed once at a moving position where the pixels are moved so as not to overlap.

According to a second aspect of the present invention, there is provided the liquid crystal image forming method according to the first aspect, wherein the pixels are arranged in a staggered pattern.

According to a third aspect of the present invention, there is provided a liquid crystal image forming method, wherein the liquid crystal panel is composed of a plurality of pixel groups arranged in a matrix with a pitch dimension that is at least equal to the vertical and horizontal side dimensions of each pixel. A first movement position moved from the reference position in the X direction on the array plane by ½ of the pitch dimension, and a second movement position moved from the reference position in the Y direction on the array plane by ½ of the pitch dimension. And a third moving position which is moved from the reference position in the X-direction and the Y-direction on the array plane by ½ of the pitch dimension to expose one pixel. It is characterized by that.

According to a fourth aspect of the present invention, there is provided a liquid crystal image forming apparatus comprising: a liquid crystal panel which is composed of a plurality of pixel groups arranged vertically and horizontally with a pitch dimension at least twice the vertical and horizontal side dimensions of each pixel, and which is arranged at a reference position. A moving mechanism for moving the liquid crystal panel in the X and Y directions on the array plane, and a moving means for giving a predetermined moving amount to the moving mechanism,
After the liquid crystal panel is exposed at the reference position, the coordinates (x, 0) direction, the coordinates (0, y) direction, and the coordinates (x,
and a control means for controlling the moving means so as to sequentially move in the y) direction and perform exposure at each position.

According to a fifth aspect of the present invention, in the liquid crystal image forming apparatus according to the fourth aspect, the moving means is composed of a piezoelectric element.

[0012]

According to the liquid crystal image forming method of the first aspect, the liquid crystal panel composed of a plurality of vertically and horizontally arranged pixel groups is moved at least once after the exposure at the reference position so that the pixels do not overlap. Since the exposure is performed at the moved position, a resolution higher than the pixel density of the liquid crystal panel can be obtained and a clear image can be realized. Moreover, since the pixels do not overlap with each other, no color mixture occurs on the print.

According to the liquid crystal image forming method of the second aspect, since the pixels of the liquid crystal panel are arranged in a staggered arrangement in a staggered manner, a larger number of pixel densities can be simulated by a small number of movements. This can be realized, and therefore, an efficient and high-resolution image can be obtained.

According to a third aspect of the present invention, there is provided a liquid crystal panel comprising a plurality of pixel groups arranged in a matrix with a pitch dimension at least twice the vertical and horizontal side dimensions of each pixel. Since the exposure is performed at a total of four positions including the reference position and the first to third movement positions, an image having a resolution four times the pixel density can be swiftly and easily provided without causing color mixing due to overlapping pixels. Obtainable.

According to another aspect of the liquid crystal image forming apparatus of the present invention, the liquid crystal is composed of a plurality of pixel groups arranged vertically and horizontally with a pitch dimension which is at least twice the lateral dimension of each pixel, and is arranged at the reference position. For each image on the array plane, the panel is in the coordinate (x, 0) direction and coordinate (0, y).
Direction and the coordinate (x, y) direction are sequentially moved by the moving mechanism, and one image is exposed by controlling by the control means so that exposure is performed at each position. The resolution can be easily realized in a pseudo manner.

According to the liquid crystal image forming apparatus of the fifth aspect, since the liquid crystal image forming apparatus has the moving means composed of the piezoelectric element, it is possible to easily and accurately control the movement of the liquid crystal panel so that the pixels do not overlap each other. , The configuration can be simplified.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The liquid crystal image forming method and apparatus of the present invention will be described in detail below with reference to the drawings. FIG. 1 shows a liquid crystal image forming apparatus 10 according to an embodiment of the present invention.

The liquid crystal image forming apparatus 10 includes a print unit 1
2 are provided. The print unit 12 is provided with a light source 14 for printing exposure by a halogen lamp or a compact LED and a reflector. On the burning optical axis L of the light source emitted from the light source 14, R
Color separation filters 16 for each color of (red), G (green), and B (blue) are provided. Each of these color separation filters 16 is inserted into or removed from the optical axis L according to a signal from the driver 18.

A liquid crystal panel 20 to be described later is provided on the printing optical axis L below the color separation filter 16. A liquid crystal panel drive unit 22 that drives the liquid crystal panel 20 is connected to the liquid crystal panel 20, and the liquid crystal panel drive unit 22 is connected.
Is further connected to a controller 24 that controls the drive of the liquid crystal panel drive unit 22. Further, the liquid crystal panel 20 is provided with a liquid crystal panel moving unit 26 that moves the liquid crystal panel 20 within a plane indicated by a chain line M in FIG. The liquid crystal panel moving unit 26 uses, for example, PZT (pb
Piezoelectric elements 28, 64 (see FIGS. 2 and 3) such as a mixed crystal of TiO ₃ and pbZrO ₃ ) and a polymer film (for example, vinylidene fluoride) are applied, and these are controlled by the controller 24. It is like this. The driving of the piezoelectric elements 28 and 64 will be described later.

The controller 24 includes a negative image storage section 30.
And controls the drive and movement of the liquid crystal panel 20 based on the negative image data input from the negative image storage unit 30.

The printing optical axis L below the liquid crystal panel 20 is
A black shutter 34 is arranged so as to sandwich the printing lens 32. The black shutter 34 is opened / closed in response to a drive signal from the driver 36, and passes or blocks light on the printing optical axis L. Also, the lens 32 is
It is possible to move along the optical axis L, so that the enlargement magnification can be changed.

Below the black shutter 34 and below the printing optical axis L, a photographic printing paper 38 is positioned by a photographic printing paper conveying section 40. One end of the printing paper 38 is wound in layers on a rotation shaft (not shown).

Next, the structure of the liquid crystal panel 20 and its peripheral portion will be described with reference to FIGS.

The liquid crystal panel 20 comprises a support plate 20A and a display surface 20B. The support plate 20A is formed in a frame shape, holds the display surface 20B in a central rectangular hole, and
A wiring board (not shown) is attached. Display surface 20
In B, a large number of pixels (for example, about 510,000 pixels) capable of displaying white, black, and intermediate colors thereof are arranged in a matrix with a predetermined pitch dimension by an electric means. Pixel pitch dimension (see dimension G in FIG. 5A)
Is at least twice as large as the pixel size (see size P in FIG. 5A) so that the pixels do not overlap when the liquid crystal panel 20 is moved. For example, the size of one pixel is 20 × 20 μm (the size of one side is 20 μm).
Most preferably, the pitch dimension G is 40 μm.

A pair of block members 42 are arranged on one opposite side of the liquid crystal panel 20. The block member 42 is provided with an insertion opening 46 having an opening area approximately equal to the side surface of the liquid crystal panel 20, and the opposite side end portion of the liquid crystal panel 20 is inserted therein. The insertion port 46 penetrates to the opposite surface of the block member 42, and the plate member 44 is attached to the opposite surface.

Here, an auxiliary member 48 is attached to the plate member 44 corresponding to one of the block members 42 so as to face the opening surface of the insertion opening 46, and the opposing surface of the auxiliary member 48 on the insertion opening 46 side is A piezoelectric element 28 is arranged. The auxiliary member 48 and the piezoelectric element 28 are fitted in the insertion opening 46. The auxiliary member 48 and the plate member 44 may be fixed to each other by using a screw or the like, or by an adhesive or the like. The piezoelectric element 28 is in contact with the side surface of the liquid crystal panel 20 in the width direction so as to face each other inside the block member 42, and the liquid crystal panel is moved by the amount of movement in the width direction (X direction on the pixel array plane) set by the control means. 20 can be moved.

A pressing member 52 is arranged on the other plate member 44 via a compression coil spring 50, and the insertion port 46 is inserted.
It is housed in. One end of the compression coil spring 50 between the pressing member 52 and the plate member 44 is housed in a circular groove 54 provided in the plate member 44, and the other end is in contact with the pressing member 52. As a result, the liquid crystal panel 20 is pressed by the pressing member 52 in the direction of coming into contact with the piezoelectric element 28.

The pair of block members 42 are used for the liquid crystal panel 20.
Are screwed to the pair of fixing plates 56 arranged on the other opposite sides of the. Brackets 60 are attached to the outer surface of one of the fixing plates 56 at a predetermined interval, and a piezoelectric element 64 attached to an auxiliary member 62 is arranged on the surface facing the fixing plate 56 so as to contact the fixing plate 56. ing. The piezoelectric element 64 can move the liquid crystal panel 20 via the fixing plate 56 and the block member 42 by the amount of movement in the longitudinal direction (Y direction on the array plane of pixels) set by the control means. ing.

A coaxial circular hole is provided in each of the pair of fixing plates 56 and the bracket 60, and a shaft 66 passes therethrough. The end of the shaft 66 is locked by an E-shaped ring 68 near the bracket 60 to prevent movement in the axial direction.

A compression coil spring 70 is attached to a shaft 66 between the fixing plate 56 and the bracket 60 on the side opposite to the side where the piezoelectric element 64 is arranged. The compression coil spring 70 has a function of urging the liquid crystal panel 20 in a direction of coming into contact with the piezoelectric element 64 via the fixing plate 56.

As a result, as shown in FIG.
Normally, the liquid crystal panel 20 is in contact with the piezoelectric element 28 and the fixing plate 56 is in contact with the piezoelectric element 64 (reference position (0, 0)), and when only the piezoelectric element 28 acts, the liquid crystal panel 20 becomes (x , 0) direction (first movement position) and only the piezoelectric element 64 acts, the liquid crystal panel 20
Is moved in the (0, y) direction (second moving position) together with the block member 42 and the fixing plate 56, and when the piezoelectric element 28 and the piezoelectric element 64 act together, the liquid crystal panel 20
It moves in the (x, y) direction (third movement position).

Next, the operation of this embodiment will be described. When the image data to be subjected to the printing exposure, which is temporarily stored in the negative image storage unit 30, is transmitted to the liquid crystal panel drive unit 22 via the controller 24, the liquid crystal panel drive unit 22 operates to transmit the transmitted image. Based on the data, a negative image is formed on the liquid crystal panel 20 composed of pixels arranged in a matrix at a predetermined pitch, and the photographic printing paper 38 is exposed according to a predetermined process.

This will be described in more detail below with reference to FIGS. 4 and 5. Here, FIG. 5 exemplifies the pixel density between each stage in an image obtained when the liquid crystal panel is moved and exposed according to the flow shown in FIG.

In step 100, the liquid crystal panel 20
The pixel data in is read out. Here, the pixel data refers to data relating to all pixels for moving the liquid crystal panel 20 such that the size and pitch dimension of one pixel and the pixel density do not overlap, and the liquid crystal panel assembled in advance. 20 data may be input in the memory. Alternatively, a plurality of types may be stored in advance, and identification symbols (A, B ... E types) may be input and selected.

When the pixel data is read out (input), in step 102, the X direction (x, 0), the Y direction (0, y) and the X direction are obtained based on the input pixel data.
Each movement amount in the −Y direction (x, y) is determined. When the movement amount is determined, in step 104,
The negative image storage unit 30 stores the negative image.
In this embodiment, since the liquid crystal panel 20 is positioned at four positions to expose one image, the resolution is set for the stored negative image so that the number of pixels is four times the number of pixels of the liquid crystal panel 20. To do. Next, the reference (0,0) position, (x, 0)
The pixels corresponding to each of the position, the (0, y) position, and the (x, y) position are selected. First, the image data selected as the reference position is sent to the liquid crystal panel drive unit 22 via the controller 24. And is displayed on the liquid crystal panel 20 in step 106.

When the negative image is displayed on the liquid crystal panel 20, in step 108, the negative image at the reference position is exposed on the photographic paper 38 in this state, that is, the liquid crystal panel 20 at the reference position for a predetermined time (FIG. 4). (A)).

When the exposure at the reference position is completed, in step 110, the movement amount to the (x, 0) position is given from the controller 24 to the liquid crystal panel moving unit 26 via the piezoelectric element 28, and the liquid crystal panel 20 is Move to the (x, 0) position. When the liquid crystal panel 20 is moved to the (x, 0) position, the image data selected as the (x, 0) position in step 112 is sent to the liquid crystal panel drive unit 22 via the controller 24, and the image data is displayed on the liquid crystal panel 20. Is displayed in. When the negative image is displayed on the liquid crystal panel 20, a predetermined exposure is performed at the moving position in step 114 (FIG. 5 (B)).

When the moving exposure at the (x, 0) position is completed, in step 116, the moving amount to the (0, y) position is given from the controller 24 to the liquid crystal panel moving section 26 via the piezoelectric element 64. The liquid crystal panel 20
Move to the (0, y) position. When the liquid crystal panel 20 moves, the image data selected as the (0, y) position in step 118 is displayed on the liquid crystal panel 20 via the controller 24. On the liquid crystal panel 20 (0,
y) When the negative image at the position is displayed, step 1
At 20, the predetermined exposure is performed at the moving position (FIG. 5 (C)).

When the moving exposure at the (0, y) position is completed, the amount of movement to the (x, y) position is given from the controller 24 to the liquid crystal panel moving section 26 via the piezoelectric elements 28 and 64 in step 122. , Liquid crystal panel 20
Moves to the (x, y) position. When the liquid crystal panel 20 moves, the image data selected as the (x, y) position in step 124 is displayed on the liquid crystal panel 20 via the controller 24. When the negative image at the (x, y) position is displayed on the liquid crystal panel 20, a predetermined exposure is performed at the moving position in step 114 (FIG. 5 (D)).

In this embodiment, after the exposure at the reference position, the exposure is performed in the X direction, the Y direction, and the XY direction, but the exposure is not limited to this order. Further, either the movement to the movement position or the display of the negative image at the movement position may be performed first.

Further, since the pixels are arranged with a pitch dimension which is twice or more the side dimension of each of the vertical and horizontal sides of the pixel of the liquid crystal panel 20, the amount of movement of half the pitch dimension in each of the X and Y directions. However, when the pitch dimension is larger, the amount of movement can be changed to further increase the resolution. For example, when the pitch dimension is three times or more the side dimension of each of the vertical and horizontal directions, the amount of movement to the first to third movement positions is set to 1/3 of the pitch dimension, respectively, and the X direction, the Y direction, and the XY By moving in each direction for exposure, and then moving by the same amount of movement for exposure, the resolution can be increased 9 times. Each pixel data can also be created by interpolating the captured data.

Although the pixels of the liquid crystal panel 20 are arranged in a matrix in this embodiment, they may be arranged in a staggered pattern. In this case, as shown in FIG. 6, after the exposure is performed at the reference position (FIG. 6A), for example, only the Y direction is moved to perform the exposure (FIG. 6B), and the elements are arranged in a matrix. It is possible to obtain an image having the same resolution as that of the image obtained when the liquid crystal panel 20 including the above-described pixels is moved and exposed three times. Therefore, since a larger pixel density can be pseudo-realized with a small number of movements, a high-resolution image can be obtained quickly.

Further, when a high resolution image obtained by the above liquid crystal image forming method is stored, it can be converted into a 1/4 memory by converting it into movement amount data.

In this embodiment, a piezoelectric element that can be easily electrically controlled and has a compact structure is used as the moving means. However, if the movement of the liquid crystal panel 20 can be given to the moving mechanism, the piezoelectric element is limited to this. I can't.

Further, in this embodiment, the liquid crystal panel 20 in which the pixels are arranged in a zigzag pattern or a matrix is used.
If the pixels do not overlap when the liquid crystal panel 20 is moved, the array shape of the pixels is not limited to these.

According to this embodiment, an available liquid crystal panel can be used to provide a higher resolution image, while a lower cost liquid crystal panel can be used to form an image of the same resolution. Can be used.

[0047]

As described above, according to the present invention, an image having a resolution higher than the pixel density of the liquid crystal panel can be formed, so that a clear image can be realized.

[Brief description of drawings]

FIG. 1 is a schematic diagram of a liquid crystal image forming apparatus according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view showing a structure of a liquid crystal panel and its peripheral portion of a liquid crystal image forming apparatus according to an embodiment of the present invention.

FIG. 3A is a plan view showing a structure of a liquid crystal panel and its peripheral portion of a liquid crystal image forming apparatus according to an embodiment of the present invention,
FIG. 3B is a characteristic diagram when the movement of the liquid crystal panel of FIG.

FIG. 4 is a flowchart illustrating a flow of a liquid crystal image forming method according to an embodiment of the present invention.

FIG. 5 is a conceptual diagram illustrating the pixel density of an image obtained by the liquid crystal image forming method according to the embodiment of the present invention.

FIG. 6 is a conceptual diagram illustrating a pixel density of an image obtained by a liquid crystal image forming method according to another embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Liquid crystal image forming apparatus 12 Printing part 20 Liquid crystal panel 24 Controller 26 Liquid crystal panel moving part 28 Piezoelectric element 42 Block material 44 Plate material 50 Compression coil spring 52 Pressing member 56 Fixing plate 60 Bracket 64 Piezoelectric element 66 Shaft 70 Compression coil spring

Claims (5)

[Claims] 1. A liquid crystal panel composed of a plurality of pixel groups arranged vertically and horizontally at a predetermined pitch dimension is exposed at a reference position and then exposed at a moving position at least once so that the pixels do not overlap. A method for forming a liquid crystal image, comprising: 2. The liquid crystal image forming method according to claim 1, wherein the pixels are arranged in a zigzag pattern. 3. A side dimension of at least 2 in each of the vertical and horizontal directions of the pixel.
The liquid crystal panel composed of a plurality of pixel groups arranged in a matrix with a double pitch dimension, a reference position,
A first movement position that is moved from the reference position in the X direction on the array plane by ½ of the pitch dimension, and a first movement position that is moved from the reference position in the Y direction on the array plane by ½ of the pitch dimension. 1 pixel is exposed by sequentially moving to four positions, that is, the second moving position and the third moving position which is moved from the reference position in the X direction and the Y direction on the array plane by ½ of the pitch dimension. A method for forming a liquid crystal image, comprising: 4. A side dimension of at least 2 in each of the vertical and horizontal directions of the pixel.
A liquid crystal panel that is arranged at a reference position and is composed of a plurality of vertically and horizontally arranged pixel groups with a double pitch dimension; a moving mechanism that allows the liquid crystal panel to move in the X and Y directions on an array plane; A moving unit that gives a moving amount to the moving mechanism; and a coordinate (x, 0) direction, a coordinate (0, y) direction, and a coordinate (x,
A liquid crystal image forming apparatus comprising: a control unit that controls the moving unit so as to sequentially move in the y direction and expose at each position. 5. The liquid crystal image forming apparatus according to claim 4, wherein the moving unit is composed of a piezoelectric element.