KR20190031226A - Optical recording apparatus - Google Patents

Abstract

The present invention relates to an optical recording apparatus (1) which irradiates light irradiated from a plurality of pixels (20) arranged in a zigzag shape with a main scan direction (M) as a long direction to an object (W) relatively moving in a sub scan direction (S) to write an image. According to the present invention, the size of the sub scan direction is reduced as possible and thus miniaturization of the entire apparatus is realized. The pixel has a shape of an octagon with a long width which has all cut corners including a corner part corresponding to two pixels adjacent in the sub scan direction, and an interval between the pixels in the sub scan direction becomes zero or the pixels are overlapped with the sub scan direction. The central axis (C2) of pixel rows R (red), G (green), and B (blue) is fit to the central axis (C0) of an erect iso-lens (30), and each central axis (C1 to C3) of the pixel rows R, G, and B is arranged between the central axes of a two-rowed refractive index distribution type lens.

Description

[0001] OPTICAL RECORDING APPARATUS [0002]

The present invention relates to an optical recording apparatus for irradiating light irradiated from a plurality of pixels arranged in a zigzag pattern along a main scanning direction to a writing target which relatively moves in a sub scanning direction to write an image And more particularly to an optical recording apparatus which realizes downsizing of the entire apparatus by narrowing the size in the sub-scanning direction.

Patent Document 1 below discloses an image exposure apparatus having a plurality of rows of light emitting elements in which a plurality of light emitting elements are arranged in a line shape. The exposure apparatus includes an array light source group including first to third array light sources in a staggered arrangement in which one of the rows of light emitting devices adjacent to each other in the short side direction is shifted in a long side direction with respect to the other, A dichroic prism for mixing the emitted light to form outgoing light in the form of a line and a lens array for focusing the outgoing light formed by the light mixing means onto a photo paper. The interval d between the light emitting elements of the array light sources in the zigzag array is set to be 500 mu m or less. According to such a configuration, it is possible to reduce the exposure of the exposure position due to the use of an array light source having a plurality of rows of light emitting elements or a lens having a wide aperture, and to improve the "cord" formed due to the characteristics of the halogenated silver- It is possible to prevent deterioration of image quality.

Patent Document 1: Japanese Patent Application Laid-Open No. 2004-299083

According to the image exposure apparatus of Patent Document 1, since a plurality of pixels are arranged in a zigzag shape with the main scanning direction being a long side direction, pixels adjacent to each other in the zigzag direction are electrically separated from each other, I needed to do it. Therefore, pixels and pixels adjacent in a zigzag pattern are arranged at appropriate intervals in the sub-scan direction. However, in this case, there is a problem that the size of the device relating to the sub-scan direction can not be further reduced because the width of the pixel array in the zigzag arrangement is increased by at least the interval in the sub-scan direction.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the conventional art described above, and it is an object of the present invention to irradiate light to be written, which relatively moves in the sub scanning direction, to light irradiated from a plurality of pixels arranged in a zigzag shape along the main scanning direction, An object of the present invention is to provide an optical recording apparatus which realizes miniaturization of the whole apparatus by narrowing the size in the sub-scanning direction as much as possible in the optical recording apparatus performing writing.

An optical recording apparatus according to a first aspect of the present invention has a pixel column made up of a plurality of pixels arranged in a staggered arrangement with a main scanning direction being a long side direction and relatively moving And writing the image to the write target by selectively causing the pixels to emit light, the optical recording apparatus characterized in that in the pixel column, the closest of two pixels arranged adjacent to two different positions in the sub- Is formed in a separated shape that does not electrically conduct.

In the optical recording apparatus according to the second aspect, in the optical recording apparatus according to the first aspect, the two adjacent pixels disposed at different positions in the sub-scanning direction have substantially zero intervals in the main scanning direction, And the interval in the scanning direction is substantially 0 or overlaps with the sub-scanning direction.

The recording apparatus according to the third aspect is characterized in that, in the optical recording apparatus according to the second aspect, the pixel has a first pair of sides parallel to the main-scan direction and arranged at a first interval in the sub- And a second pair of sides arranged parallel to the scanning direction and spaced apart from each other by a second gap larger than the first gap in the main-scan direction, and an octagon formed by cutting four corners of a quadrangle, A first pair of sides arranged at a first interval and a second pair of sides arranged at a second interval larger than the first interval in parallel with the sub scanning direction and in the main scanning direction, A hexagonal shape obtained by cutting out two edges facing each other of the adjacent pixels among the two edges and a shape including a major axis in the main scanning direction and an ellipse having a minor axis in the sub scanning direction And is characterized in that the shape of one selected from the group.

The optical recording apparatus according to the fourth aspect is characterized in that, in the optical recording apparatus according to the second aspect, the closest distance D of two pixels arranged adjacent to two different positions in the sub-scanning direction is 3 [ (The length of the pixel in the sub-scan direction) / (2 2).

The optical recording apparatus according to the fifth aspect is characterized in that, in the optical recording apparatus according to any one of the first to fourth aspects, the three pixel columns having respective luminescent colors red, green and blue, A plurality of lens arrays of a plurality of unit lenses arranged in a main scanning direction are arranged in a plurality of rows in a sub scanning direction, And a center axis parallel to the main scanning direction of the lens train at one end in the sub scanning direction and a center axis parallel to the main scanning direction of the lens train at the other end in the sub scanning direction, Wherein the central axes of the three pixel columns are arranged between the central axes parallel to the main scanning direction, And a central axis parallel to the main scanning direction of the pixel rows at the center with respect to the three pixel column central scanning directions are made to coincide with each other so that the central axis of the equalizing equalizing lens passing through the center of the length in the sub- , And the equalization equalizing lens and the pixel column are disposed.

According to the optical recording apparatus of the first aspect, light emitted from a pixel row in which a plurality of pixels are arranged in a zigzag pattern in a main scanning direction is irradiated while relatively moving in a sub-scanning direction with respect to a writing target, In the recording apparatus, since the corresponding portions of two pixels arranged adjacent to two positions in the sub-scanning direction different from each other in the sub-scanning direction are formed as discrete shapes, these two pixels can be electrically driven independently , There is no need to provide a gap between the two pixels in the sub-scanning direction. Therefore, the size in the sub-scanning direction is narrowed as much as possible, and the overall size of the apparatus can be reduced.

According to the optical recording apparatus of the second aspect, since the two adjacent pixels arranged at positions different in the sub-scanning direction from each other are substantially 0 in the main scanning direction, It is possible to carry out substantially continuous writing in the main scanning direction, and the image quality of the obtained image is improved. In addition, since the interval between the two pixels in the sub-scan direction is substantially 0 or overlaps with respect to the sub-scan direction, the effect of miniaturizing the entire device by narrowing the size in the sub-scan direction can be obtained.

According to the optical recording apparatus according to the third aspect, the shape of the pixel is arbitrarily selected from a long octagon, a hexagon, and an ellipse, which are all long in the main-scan direction, so that the size of the sub- The effect of downsizing can be surely obtained.

According to the optical recording apparatus of the fourth aspect, the size in the sub-scan direction is reduced by setting the maximum value when the manufacturing threshold value is 3 mu m as the lower limit and the distance in the main-scan direction is 0 as the upper limit The effect of downsizing the entire device can be obtained more reliably.

According to the optical recording apparatus of the fifth aspect, since the size of the three pixel columns of red, green and blue colors is small in the sub scanning direction, the central axis parallel to the main scanning direction is aligned The center axes of the three pixel columns can be arranged within a range between the center axis of the lens train on one side in the sub scanning direction of the equalization equalization lens and the center axis on the other side in the sub scanning direction. The positional relationship between the unit lenses constituting the equalization equalizing lens and the pixels is not the same in all the unit lenses, and therefore, the light intensity of the light emitted from the uniformly equalizing lens has a regular repetitive pattern. However, Since the heat is arranged at a position near the center axis of the equalization equalizing lens, the amount of variation in which the light intensity of the light emitted from the equalizing lens regularly fluctuates along the main scanning direction is reduced as much as possible, . The fact that the dimension of the three pixel columns in the sub scanning direction is small and can be arranged at a position close to the center axis of the equalization lens means that the diameter of the unit lens can be made smaller, The number of lens rows in the main scanning direction arranged in the scanning direction can be made smaller. That is, it is premised that the dimensions and arrangement of the pixel and the pixel column are the same, and the diameter of the unit lens can be made small by suitably setting the number of columns of the lens column, and the diameter of the unit lens is set appropriately This means that it is possible to easily set the size and the size of the lens in accordance with the shape and size of the pixel array. Therefore, it is possible to provide an optical recording apparatus with good image quality at a lower cost So that it can be easily realized.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic block diagram of an optical recording apparatus according to an embodiment of the present invention. FIG.
2 is a front view of the optical recording apparatus of the embodiment.
3 is a view showing an example of a first shape of a pixel in the optical recording apparatus according to the embodiment and an example of the arrangement of the pixel and the equal-size equalizing lens.
4 is a view showing an example of a second shape of a pixel in the optical recording apparatus according to the embodiment and an example of arrangement of the pixel and the equal-size equalizing lens.
5 is a view showing an example of a third shape of a pixel in the optical recording apparatus according to the embodiment and an example of arrangement of the pixel and the equal-size equalizing lens.
Fig. 6 is a view showing an example of a fourth shape of a pixel in the optical recording apparatus according to the embodiment, and an example of arrangement of the pixel and the equal-size equalizing lens. Fig.
FIG. 7 is a diagram showing an example of arrangement of pixel columns in an optical recording apparatus, wherein (1) is an example of arranging the pixel columns at a predetermined interval in the main scanning direction, (2) (3) is an example of staggered arrangement along the main scanning direction without spacing in the sub-scanning direction, and (4) shows an example of arrangement of pixel columns in the optical recording apparatus of the embodiment Fig.

Embodiments of the present invention will be described with reference to Figs. 1 to 7. Fig.

The optical recording apparatus 1 according to the present embodiment is provided with the organic EL element 2 as a light source and the R (red), G (green), and B And is a means for forming a full color image by writing once to the writing target W such as a color film by the light of the primary color. Note that an organic EL element is merely an example of a light source, and the principle of light emission of the light source is irrelevant.

However, since the organic EL element is a surface emitting element, there is an advantage that the in-plane uniformity of light emission is high. Therefore, an organic EL element is suitable as a light source for an optical recording apparatus as compared with a point light emission light source such as a general LED.

The optical recording apparatus 1 is driven by a digital color image signal obtained from, for example, a video apparatus or the like, and is used as a color video printer for printing an image in a full color on a write destination W. In addition, Type printer, a silver chloride type printer, a label printer, and the like. That is, the type of the write target W and the principle of optical recording are irrelevant.

As shown in Fig. 1, the optical recording apparatus 1 has an organic EL element 2 which moves along a sub-scan direction S indicated by an arrow S with respect to a write target W positioned and fixed at a predetermined position. The organic EL element 2 is housed inside the case 3.

As shown in Fig. 1, the case 3 of the organic EL element 2 reciprocates along the sub-scanning direction S (arrow S) with respect to the writing target W by the moving mechanism 4 as the moving means. The moving mechanism 4 includes guiding means (not shown) for guiding the case 3 of the organic EL element 2 movably in the sub scanning direction S and a pair of pulleys 6 , And a drive motor (7) for rotating one side of the pulley (6).

When the drive motor 7 is driven to circulate the drive belt 5, the case 3 of the organic EL element 2 can be guided by guide means (not shown) and moved along the sub scanning direction S. A plurality of color films as the writing target W are held at predetermined positions, and when writing by light is completed, the developing device 8 performs development (current image) and discharges the color film to the outside of the apparatus.

Although not shown, the present apparatus is provided with a control means including a CPU or a drive circuit having an internal memory, and the control means controls the light emission of each light emitting dot of the organic EL element 2, And controls the driving of the moving mechanism 4. [

1, the organic EL element 2 includes a plurality of dot-shaped light emitting elements (not shown) arranged on the inner surface of a translucent substrate 11 constituting a box-shaped envelope 10 20). Although not shown in detail, the pixel 20 is formed by a laminated structure of a multilayer film including an organic thin film. These pixels 20 constitute three pixel columns arranged in a zigzag pattern along the main scanning direction M orthogonal to the sub-scanning direction S and perpendicular to the plane of Fig. 1, as will be described later in detail. The pixel columns correspond to the three colors R (red), G (green), and B (blue), and are arranged at a predetermined interval in the sub-scanning direction S.

1, the light emitted from the pixel columns R (red), G (green), and B (blue) is focused on the outer surface of the substrate 11 of the organic EL element 2, W lens 30 for irradiating the wafer W to the wafer stage. As shown in Figs. 1 to 3, the sizing equalization lens 30 is a zoom lens having a lens array composed of a refractive index distribution type lens 31, which is a plurality of cylindrical unit lenses arranged in the main scanning direction M, Are arranged in two rows in the direction S and are integrally integrated.

Fig. 3 shows the arrangement of the pixel 20 and the equalization equalization lens 30 by enlarging the area Z shown in Fig. 3, the pixel arrays of three kinds of pixels 20 of R (red), G (green), and B (blue) of the organic EL element 2 have a main scanning direction for each color in a long direction In a zigzag manner. That is, the plurality of pixels 20 forming one set of columns for each color are alternately arranged one by one along the main scanning direction M so that the positions of the sub-scanning directions S take one of the two positions.

As shown in Fig. 3, each of the pixels 20 is formed into a horizontally elongated octagonal pattern in which the main scanning direction M is a long direction. That is, this octagon is formed by a first pair of sides b, b parallel to the main scanning direction M and arranged with a first interval Y in the sub-scanning direction S, And the four corners of the rectangle formed by the second pair of sides a and a arranged at a second interval X larger than the interval are cut out in the same equilateral triangle shape. Therefore, the dimension (lateral dimension) X of the side b parallel to the main scanning direction M is a horizontally long octagon that is larger than the dimension (longitudinal dimension) Y of the side a parallel to the sub scanning direction S.

The area of the pixel 20 is determined so as to obtain the required light intensity, and thus the shape can be arbitrarily set within a range in which a predetermined area can be secured. In the present embodiment, the dimension (transverse dimension) X of the side b is larger than the dimension (longitudinal dimension) Y of the side a parallel to the sub-scanning direction S, Octagon. Therefore, the sizes of the pixel columns R, G, and B with respect to the sub-scanning direction S are narrowed as much as possible, and the apparatus can be made compact.

3, in each of the pixel columns R, G, and B, the pixel 20 is arranged with the length of the main scanning direction M of the pixel 20 as a pitch with respect to the main scanning direction M, The interval between the pixel 20 and the pixel 20 in the main scanning direction M is zero. The pixel 20 is arranged with the length of the sub-scan direction S of the pixel 20 as a pitch with respect to the sub-scan direction S, The interval is also zero.

The reason why the spacing of the pixels 20 can be set to 0 in the sub-scanning direction S in this manner is that since the shape of the pixel 20 is octagonal as described above, in each pixel column R, G, This is because the two pixels 20 and 20 disposed adjacent to two positions having different directions are in a separated shape in which respective corresponding portions are not in contact with each other. The portions corresponding to (i.e., facing each other) are the portions where the adjacent pixels and the pixel are closest to each other. The neighboring pixel 20 and the pixel 20 are not electrically connected to each other even though the interval in the sub-scanning direction S is 0, so that they can be driven independently of each other. In addition, in the pixel columns R, G, and B, since the intervals between the pixels 20 and the pixels 20 adjacent to each other in the sub-scan direction S do not have to be spaced apart from each other, , The effect of not increasing the size in the sub-scanning direction is higher, and the effect is obtained for each column of the three colors. Therefore, the size of the full-color device as a whole in the sub- .

The arrangement of the pixels for separating the adjacent pixels from the pixels and not electrically conducting them may be defined from the following distance conditions. That is, irrespective of the shape of the pixel, the closest distance D between the adjacent pixel and the pixel satisfies the following equation in order to make the distance between the adjacent pixel and the pixel to be zero, while making the distance in the main-

3 mu m < D < (length of the pixel in the sub-scan direction) / (2 &

In the above equation, the lower limit of 3 占 퐉 is a threshold value from the manufacturing viewpoint at the present time. The upper limit is the maximum value when the distance in the main scanning direction is set to zero, and the pixel column is a zigzag arrangement of the rhombic pixels.

As shown in Fig. 3, three pixel columns R, G, and B having respective light emission colors of R (red), G (green), and B (blue) are parallel to each other, Respectively. The relationship between the pixel columns R, G, and B and the above-mentioned equalization equalization lens 30 will be described below. In the equalization equalization lens 30, (Not shown) parallel to the main scanning direction M of the lens array (for example, the lens array on the upper side in the drawing) and the lens array (for example, the lens array on the lower side in the drawing) Center axes C1 to C3 of the three pixel columns R, G, and B are disposed between a central axis (not shown) parallel to the main scanning direction M of the pixel rows R, G, The center axis C0 of the equalizing equalization lens 30 passing through the center of the length of the equalizing equalization lens 30 in the sub scanning direction S and the center axis C0 of the equalizing equalization lens 30 parallel to the main scanning direction M, G and B and the pixel rows R, G, and B are arranged so that the center axis C2 of the green pixel column G coincides with the sub scanning direction of the sub scanning direction.

As described above, in the optical recording apparatus 1, since the sizes of the sub-scanning directions of the respective pixel columns R, G, and B are small, the center axis C2 parallel to the main scanning direction M Between the central axis of the lens train on one side of the sub scanning direction S of the equalizing equalization lens 30 and the central axis of the lens train on the other side of the sub scanning direction S when three lenses are arranged coincident with the central axis C0 The center axes C1 to C3 of the pixel columns R, G, and B can be arranged. The positional relationship between the refractive index profile type lens 31 constituting the equalization equalization lens 30 and the pixel 20 is not the same in all the refractive index profile type lenses 31. Therefore, The three pixel columns R, G, and B are disposed at positions close to the central axis C0 of the equalization equalization lens 30. Therefore, The fluctuation amount in which the luminous intensity of the light emitted from the equalization equalizing lens 30 fluctuates regularly along the main scanning direction M is reduced as much as possible and the effect of improving the image quality of the image formed on the writing target W is obtained.

The fact that the dimensions of the three pixel columns R, G, and B in the sub-scan direction S are small and can be arranged at a position close to the central axis C0 of the equalization equalization lens 30 means that the refractive index distribution of the refractive index distribution type lens 31 When the diameter is smaller or the diameter of the refractive index distribution type lens 31 is the same, the number of lens columns in the main scanning direction M arranged in the sub-scanning direction S is smaller or the number of lens rows of the equal- Means that the optical recording apparatus 1 can be used as an optical system of the optical recording apparatus 1 of the present invention and it is possible to realize the optical recording apparatus 1 of good image quality at a lower cost. In this embodiment, a standard and comparatively inexpensive stereoscopic equalizing lens 30 in which two refractive index distribution type lenses 31 having a diameter of about four times the length X of the pixel 20 in the main scanning direction M are accumulated in a zigzag shape, The effect can be obtained.

Referring to Fig. 7, the advantages of the structure in which the opposing positions of the pixels 20 and 20 arranged in a zigzag pattern are cut off and electrically isolated as in the present embodiment will be described again based on the knowledge of the present inventors.

7 is a view showing a pixel column in which the horizontal direction is the main scanning direction and the vertical direction is the sub scanning direction. (1) in the drawing shows a state in which the pixels 40 are arranged at a predetermined interval in the main scanning direction in order to electrically isolate the pixels 40 from each other. In this structure, a continuous line can not be formed in the main scanning direction on the writing target, and the quality of the image becomes insufficient. Therefore, it is also conceivable to arrange the pixels 40 without providing a gap in the main scanning direction as shown in (2) of FIG. 2. However, the pixels 40 can not be electrically driven independently, I can not. Therefore, it is possible to consider a zigzag arrangement in which the main scanning direction is a long direction as shown in (3) of the figure. In this structure, however, since the corner portions of the two adjacent pixels 40 and 40 in the sub- , Can not be employed either. The arrangement of the light emitting elements in the zigzag arrangement in the image exposure apparatus of Patent Document 1 is such that the spacing in the sub scanning direction between pixels adjacent to each other in a staggered pattern is And the two pixels are electrically isolated from each other. However, in this configuration, the size in the sub-scan direction is enlarged, and the size of the image exposure apparatus or the optical recording apparatus is also increased, so that the request for compacting from the market can not be satisfied. The inventors of the present invention have found that the pixels 40 and 40 arranged in a staggered shape in (3) in the figure cut off the corner portions facing each other to form an octagon as shown in (4) By making the shape longer in the main scanning direction and shorter in the sub scanning direction so that the zigzag arrangement having a higher image quality can be formed without any difficulty in electrical connection and furthermore the dimension in the sub scanning direction can be made narrower And can be realized by an inexpensive equalization lens.

In the embodiment described above, the shape of the pixel 20 is an octagon, the interval between the adjacent pixels 20 in the main scanning direction M is 0, and the interval in the sub-scanning direction S is 0 there was. However, in the present embodiment, since the pixels 20 arranged in a zigzag shape are formed in a shape in which the opposed positions are cut off, as shown in Fig. 4, the pixels 20 adjacent to each other in the zigzag direction, 20 in the sub scanning direction S may overlap with each other. With this arrangement example, the size in the sub-scanning direction S can be further narrowed.

5 shows an example in which the shape of the pixel 20 is a hexagon. That is, in the pixel columns R, G, and B, only the opposite corner portions of the pixel 20 and the adjacent pixel 20 in the zigzag direction are cut out in the same equilateral triangular shape. This shape example also provides the same effect as the shape example of Fig.

6 shows an example in which the shape of the pixel 20 is an ellipse. This ellipse is an ellipse in which the main scanning direction M is the long axis and the sub scanning direction S is the short axis, and the corner of the octagonal pixel 20 shown in Fig. 3 is further rounded. This shape example also provides the same effect as the shape example of Fig.

1: Optical recording device
2: Organic EL element as a light source
20: pixel
30: Sizing lens
31: a refractive index distribution type lens as a unit lens constituting the equalization equalization lens
S: sub scanning direction
M: Direction of main share direction
A: The first pair of sides
B: The second pair of sides
C1, C2, C3: a center axis of the pixel column
C0: Centering axis of the equalizing lens
R, G, and B: pixel columns
X: first interval
Y: second interval
W: Entries

Claims (6)

Wherein the pixel has a pixel column made up of a plurality of pixels arranged in a zigzag pattern in a main scanning direction in a long direction and selectively emits the pixels while relatively moving along a sub scanning direction orthogonal to the main scanning direction with respect to the writing target, An optical recording apparatus for writing an image on a write target,
Wherein a closest portion of two pixels disposed adjacent to two different positions in the sub-scanning direction in the pixel column is a separated shape that does not electrically conduct,
Wherein the pixel column includes three pixel columns having red, green, and blue light emission colors, and the three pixel columns are arranged in parallel in a sub-scanning direction at a predetermined interval,
The optical recording apparatus is characterized in that a plurality of lens columns made up of a plurality of unit lenses arranged in the main scanning direction are arranged in a plurality of rows in a sub scanning direction and converge light irradiated from the three pixel columns, An equalizing lens,
The pixel includes:
A first pair of sides which are parallel to the main scanning direction and are arranged with a first gap in the sub scanning direction and a second pair of sides which are parallel to the sub scanning direction and are arranged at a second gap larger than the first gap in the main scanning direction An octagon formed by cutting four corners of a rectangle formed by a pair of sides,
A first pair of sides which are parallel to the main scanning direction and are arranged with a first gap in the sub scanning direction and a second pair of sides which are parallel to the sub scanning direction and are arranged at a second gap larger than the first gap in the main scanning direction A quadrangle formed by cutting out two corners facing each other of the four adjacent corners of a quadrangle composed of a pair of sides,
And a shape selected from the group of shapes including the shape,
Wherein the first pair of sides of each of the plurality of pixels having the shape of the octagonal or hexagonal shape are parallel to each other
And an optical recording medium.
The method according to claim 1,
Scanning direction, the two adjacent pixels disposed at different positions in the sub-scanning direction are substantially 0 in the main-scan direction, and the intervals in the sub-scan direction are substantially 0 or overlapped with respect to the sub- Recording device.
3. The method of claim 2,
The distance D at which the two pixels disposed adjacent to the two different positions in the sub-scanning direction approach the closest reaches 3 mu m < D < (length of the pixel in the sub-scanning direction) / Recording device.
The method according to claim 1,
Wherein a positional relationship between each pixel of said three pixel columns and a plurality of unit lenses of said equalization equalization lens is different in at least a part of said plurality of unit lenses.
The method according to claim 1,
Scanning direction, between a central axis parallel to the main-scan direction of the lens train at one end in the sub-scan direction and a central axis parallel to the main-scan direction of the lens train at the other end in the sub- And the center axes of the three pixel columns are arranged.
6. The method according to any one of claims 1 to 5,
Scanning direction in the main scanning direction of the pixel train parallel to the main scanning direction and passing through the center of the length in the sub scanning direction of the equalizing equalizing lens and in the middle of the three scanning lines among the three pixel trains Wherein the equalizing lens and the pixel array are disposed such that the parallel central axes coincide with each other.

Images