JPH0686017A - Color image reader - Google Patents

Abstract

PURPOSE:To provide a color image reader capable of clearly reading the color images of an original surface with true color components by eliminating the positional deviation of the convergence point on a photoelectric converting element of light transmitted through respective color filters for color resolution. CONSTITUTION:The red, green and blue color filters 5R, 5G and 5B constituting a color filter constitutional body 5 are formed by varying the thickness corresponding to the difference of the wave length of the transmitted light and the chromatic aberration of a condenser lens 4 due to the difference of the wave length of the light is corrected. In such a manner, the convergence points on the photoelectric converting element 2 of the light transmitted through the respective color filters 5R, 5G and 5B can be made coincident. The respective color filters 5R, 5G and 5B may be formed by varying the material so as to differ refractive index or by varying both the thickness and the material.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color image reading apparatus for reading a color image on the surface of an original used in a color facsimile, a color image scanner or the like.

[0002]

2. Description of the Related Art A conventional color image reading apparatus of this type is
There is known a perspective view showing the structure thereof as shown in FIG. 3, and as shown in the figure, a document set at a predetermined position.
A one-dimensional photoelectric conversion element (image sensor) 52 arranged to face 51, and a photoelectric conversion element which is arranged between the original 51 and the photoelectric conversion element 52 and which reflects light reflected from the original surface illuminated by the light source 53. A condensing lens 54 for converging on 52, a disc-shaped color filter structure 55 arranged between the condensing lens 54 and the surface of the original 51, and this color filter structure 55 are connected to each other and predetermined. And a rotary drive motor 56 that rotates at a rotational speed.

The color filter structure 55 is, in this example,
Red transmission color filter R ₁ , which transmits only the red component of light
R ₂ , green transmission color filter that transmits only the green component of light
G ₁ , G ₂ , and blue transmission color filters B ₁ , B ₂ that transmit only the blue component of light are formed by arranging radially in the order of red, green, and blue with a fan shape having a central angle of 60 °. ing.

The above color filters are formed to have the same thickness in the light transmitting direction. Reference numeral 55a is a rotation angle detection mark for distinguishing each color filter of the color filter structure 55, and reference numeral 57 is a rotation angle detection sensor provided at the outer peripheral edge position of the color filter structure 55.

When reading a color image such as characters and figures written on the original document 51, the photoelectric conversion element 52 scans one time for the passage of one color filter of the color filter structure 55. As described above, the color filter structure 55 is rotated by a rotation drive motor in synchronization with the scanning of the photoelectric conversion element 52.
Rotate at 56. As a result, each color filter of the color filter structure 55 is sequentially positioned on the optical axis of the condenser lens 54 so as to cross the optical path of the light from the document surface.

In this way, the light reflected from the surface of the original illuminated by the light source 53 and transmitted through the color filter structure 55 is focused on the photoelectric conversion element 52 by the condenser lens 54, and the color image on the original is colored. The color image on the document surface is read by the photoelectric conversion element 52 by separating each color filter of the filter structure 55. In addition,
The color filter structure 55 includes a condenser lens 54 and a photoelectric conversion element 52.
The same applies to the configuration arranged between the and.

[0007]

However, in the above-mentioned conventional color image reading apparatus, since the condensing lens has axial chromatic aberration due to the difference in the wavelength of light passing through each color filter, each color of the color filter structure is The position of the focal point (image forming point of the transmitted color light) of the transmitted color light with respect to the photoelectric conversion element differs for each filter (see FIG. 2). Therefore, the MTF (sharpness: Modulation Transfer Functi) of each color filter is
on), the color image on the document surface is sharp and it is difficult to faithfully read the color components.

The present invention has been made in order to solve the above-mentioned conventional drawbacks, in which light from a document surface irradiated by a light source is passed through a condenser lens and a color filter of a color filter structure to form a photoelectric conversion element. In the color image reading device, in which the color image on the document surface is read by the photoelectric conversion element by performing color separation by each color filter of the color filter structure, in response to the difference in the wavelength of the transmitted light, Each color filter is transmitted through each color filter by changing the thickness or changing the material so that the refractive index is different, or by changing both the thickness and the material to correct chromatic aberration due to the difference in wavelength of light. It is possible to eliminate the misalignment of the focal point with respect to the photoelectric conversion element of light and read the color image on the original surface sharply and faithfully read its color components. And an object thereof is to provide a color image reading apparatus.

[0009]

According to the present invention, there is provided a photoelectric conversion element which is arranged so as to face a document set at a predetermined position and which reads a color image on the document surface by self-scanning, and a document surface illuminated by a light source. A color that has a condenser lens for converging light to the photoelectric conversion element and a plurality of different types of color filters, and these color filters are positioned on the optical axis of the condenser lens to obtain each transmitted color light. A filter structure is provided, and light from the original surface illuminated by a light source is focused on the photoelectric conversion element through the condensing lens and the color filter of the color filter structure, and each color filter of the color filter structure In order to achieve the above object, in a color image reading device in which a color image on a document surface is read by the photoelectric conversion element by color separation, It has taken the technical means.

In the color image reading apparatus according to the present invention, the wavelengths of the light transmitted through the color filters of the color filter structure are different from each other in order to form converging points on the photoelectric conversion element where the respective transmitted color lights are coincident with each other. It is characterized in that it is formed by changing its thickness in accordance with.

According to a second aspect of the present invention, there is provided a color image reading apparatus in which the wavelengths of light transmitted through the color filters of the color filter structure are different from each other in order to form converging points on the photoelectric conversion element where the respective transmitted color lights coincide with each other. It is characterized in that it is made of a material having a different refractive index corresponding to the above.

According to a third aspect of the present invention, there is provided a color image reading apparatus in which the wavelengths of light transmitted through the color filters of the color filter structure are different from each other so that the respective transmitted color lights form converging points on the photoelectric conversion element. It is characterized in that it is formed of a material having a different refractive index and a different refractive index.

[0013]

When the light from the original surface illuminated by the light source is focused on the photoelectric conversion element through the condenser lens and the color filter, the color filter is changed in thickness or refractive index, or both of them. It is possible to change the position of the focusing point of the light transmitted through. Therefore, each color filter of the color filter structure is formed by changing the thickness or changing the material so that the refractive index is different, or by changing both the thickness and the material according to the difference in the wavelength of the transmitted light. Thus, it is possible to correct the chromatic aberration due to the difference in the wavelength of the light including the chromatic aberration on the axis of the condenser lens, and to make the light passing through each color filter have the same focal point on the photoelectric conversion element without displacement.

[0014]

EXAMPLES The present invention will be described below based on examples. FIG. 1 is a perspective view showing the overall configuration of a color image reading apparatus according to an embodiment of the present invention.

In FIG. 1, reference numeral 1 is a document set by being wound around a platen (not shown).
In this embodiment, a one-dimensional photoelectric conversion element 2 which is self-scanning is arranged as an image sensor in opposition to the. Between the original 1 and the photoelectric conversion element 2, a condenser lens 4 for focusing the light (in this case, transmitted light) from the surface of the original illuminated by the transmissive white light source 3a on the photoelectric conversion element 2 is provided. Has been done. The white light source 3b for reflection may be used as the light source.

A disk-shaped color filter structure 5 is arranged between the condenser lens 4 and the photoelectric conversion element 2 in this embodiment, and the color filter structure 5 is rotationally driven connected to the color filter structure 5. It is rotated at a predetermined rotation speed by the motor 6. As a result, the three types of color filters 5R, 5G, and 5B of red, green, and blue of the color filter structure 5 are sequentially positioned on the optical axis of the condenser lens 4 so as to cross the optical path of the light from the document surface. It is supposed to be done.

As will be described later, this color filter structure 5 having three types of color filters 5R, 5G, 5B formed with different thicknesses has a rotation angle detecting portion at the boundary of each color filter at the circumference. A mark 5a is provided, and a weight balancer piece is provided at a required position for absorbing high-speed rotation unevenness due to non-uniform weight due to rotation of the color filter structure 5.
5c are attached respectively.

The rotation angle of the color filter structure 5 is detected by a rotation angle detection sensor 7 for detecting the position of the rotation angle detection mark 5a. Based on this, the color filter structure 5 is detected. The photoelectric conversion element 2 is scanned once for the passage of one color filter. Further, the color image data of the first surface of the original read by the color filter structure 5 and output from the photoelectric conversion element 2 is converted into a color image read signal by a signal processing circuit (not shown) and output. There is.

The color filter structure 5 includes a red transmission color filter 5R that transmits only the red component of light, a green transmission color filter 5G that transmits only the green component of light, and a blue transmission color that transmits only the blue component of light. The filter 5B is formed by arranging radially in the order of red, green and blue with a fan shape having a central angle of 120 °. The respective color filters 5R, 5G, 5B of the color filter structure 5 are formed by changing the thickness thereof in the light transmission direction, as will be described later, corresponding to the difference in the wavelength (color) of the transmitted light. And condensing lens 4
The chromatic aberration due to the difference in the wavelength of the light including the chromatic aberration on the axis is corrected so that the light passing through each color filter has the same focal point on the photoelectric conversion element without displacement.

FIG. 2 shows a condenser lens 4 according to the present invention.
FIG. 6 is a diagram for explaining a method of correcting chromatic aberration and focusing the light transmitted through each color filter to the same position on the photoelectric conversion element 2 in the optical system including the color filter structure 5 and the photoelectric conversion element 2.

In FIG. 2, a point a indicates a focus point of red light when no filter is inserted, and a point A indicates a focus point of red light after passing through the red transmission color filter. In this case, two photoelectric conversion elements are provided. The red transmitted color light forms the focal point on the top. Further, the point b is the focus point of the blue light when the filter is not inserted,
Point B indicates the converging point of blue light by the blue transmission color filter. Here, L _DR is the distance between the condenser lens 4 and the point a, L _R is the distance between the condenser lens 4 and the point A, L _DB is the distance between the condenser lens 4 and the point b, and L _B is the condenser. Lens 4 and point B
The distance between each is shown.

As described above, since the condenser lens 4 has axial chromatic aberration, when each color filter is made of a material having the same thickness t and the same refractive index, the focusing point of the light transmitted through each color filter is The position is different. Therefore, in order to correct the chromatic aberration so that the light transmitted through each color filter forms a focal point at the same position on the photoelectric conversion element 2, it can be realized by changing the thickness of each color filter.

In the case shown in FIG. 2, each color filter 5R,
When the materials of 5G and 5B, that is, the refractive index n is the same, and the transmitted color light by the red transmitted color filter 5R forms the focusing point on the photoelectric conversion element 2, the point B is moved to the position of the point A. the thickness t _B of the blue transmission color filter 5B for the, L _R -L
It can be obtained by the formula of _DB = (1-1 / n) · t _B. Therefore, since the refractive index n is a known value,
When L _R and L _DB are obtained by actual measurement, a blue transmission color filter
A thickness t _{B of} 5B is required. For example, the refractive index n = 1.47,
If the distance L _R = 200.00 mm and the distance L _DB = 199.65 mm, the thickness t _B of the blue transmission color filter 5B is 1.09 mm.
In this case, the thickness of the red transmission color filter 5R is 1.00 mm.
Is. Similarly, the thickness of the green transmission color filter 5G can be obtained.

Further, instead of changing the thickness of each of the color filters 5R, 5G and 5B, each material is formed so as to have a different refractive index according to the difference in the wavelength of the transmitted light. Also, by correcting the chromatic aberration due to the difference in the wavelength of the light including the chromatic aberration on the axis of the condenser lens 4, the light transmitted through each color filter 5R, 5G, 5B is focused on the photoelectric conversion element 2 without displacement. It is possible to make the points coincide, and it is also possible to form by changing both the thickness and the material.

In this way, the materials of the color filters 5R, 5G, 5B of the color filter structure 5 are changed so as to change the thickness or the refractive index in accordance with the difference in the wavelength of the transmitted light, Alternatively, the chromatic aberration due to the difference in the wavelength of the light including the chromatic aberration on the axis of the condenser lens 4 is corrected by forming both the thickness and the material so as to correct each color filter 5R, 5R.
The light passing through G and 5B can be made to have their focal points coincide with each other on the photoelectric conversion element 2 without positional deviation, and as a result, the color image on the document surface is sharper and its color components are better than those of the conventional apparatus. You can read it faithfully.

It should be noted that the same effect can be obtained as a matter of course in a structure in which the color filter structure 5 is arranged between the original 1 and the condenser lens 4. Further, in the above-described embodiment, the weight balancer piece is added to the disk-shaped color filter structure 5.
Since 5c is attached, it is possible to eliminate unevenness in high-speed rotation due to uneven weight due to rotation caused by changing the thickness and material of each color filter 5R, 5G, 5B of the color filter assembly 5, and stable high-speed rotation. Is retained. Further, in the present invention, as the color filter structure having a plurality of color filters, the disk-shaped one is exemplified in the above embodiment, but the invention is not limited to this. For example, a plurality of color filters are connected to form a plate. The present invention is also applicable to those arranged side by side, those having individual independent color filters, and those which are inserted into and removed from the optical path.

[0027]

As described above, according to the color image reading apparatus of the present invention, the thickness of each color filter of the color filter structure is changed or the refractive index is changed in accordance with the difference in the wavelength of the light passing therethrough. It is configured to correct the chromatic aberration due to the difference in the wavelength of the light by changing the material differently, or by changing both the thickness and the material, so that the light transmitted through each color filter is photoelectrically converted. The focusing points can be made to coincide with each other on the element without misalignment, which makes it possible to read the color image on the document surface more sharply and faithfully read its color components than in the past.

[Brief description of drawings]

FIG. 1 is a perspective view showing an overall configuration of a color image reading device according to an embodiment of the present invention.

FIG. 2 is an optical system including a condenser lens, a color filter structure, and a photoelectric conversion element according to the present invention, in which chromatic aberration is corrected and light transmitted through each color filter is focused at the same position on the photoelectric conversion element. It is a figure for explaining.

FIG. 3 is a perspective view showing a configuration of a conventional color image reading device.

[Explanation of symbols]

1 ... Original 2 ... Photoelectric conversion element 3a ... White light source for transmission 3b
White light source for reflection 4 Condenser lens 5 Color filter structure 5a Rotation angle detection mark 5c Weight balancer piece
5R ... Red transmission color filter 5G ... Green transmission color filter
5B ... Blue transmission color filter 6 ... Rotation drive motor 7 ... Rotation angle detection sensor

Claims (3)

[Claims] 1. A photoelectric conversion element, which is arranged so as to face a document set at a predetermined position and reads a color image on the document surface by self-scanning, and light from the document surface illuminated by a light source is focused on the photoelectric conversion element. A condensing lens for
Each of the color filters has a plurality of different types of color filters, and these color filters are provided on the optical axis of the condenser lens to obtain each transmitted color light, and a color filter structure from a document surface illuminated by a light source is provided. Light is focused on the photoelectric conversion element through the condensing lens and the color filter of the color filter structure, and color-separated by each color filter of the color filter structure, whereby a color image on the document surface is converted into the photoelectric conversion element. In a color image reading device configured to read by, each color filter of the color filter structure,
A color image reading device characterized in that the thicknesses of the respective transmitted color lights are changed in correspondence with the wavelength difference of the transmitted light so as to form a converging point on the photoelectric conversion element. 2. A photoelectric conversion element which is arranged so as to face a document set at a predetermined position and reads a color image on the document surface by self-scanning, and light from the document surface irradiated by a light source is focused on the photoelectric conversion element. A condensing lens for
Each of the color filters has a plurality of different types of color filters, and these color filters are provided on the optical axis of the condenser lens to obtain each transmitted color light, and a color filter structure from a document surface illuminated by a light source is provided. Light is focused on the photoelectric conversion element through the condensing lens and the color filter of the color filter structure, and color-separated by each color filter of the color filter structure, whereby a color image on the document surface is converted into the photoelectric conversion element. In a color image reading device configured to read by, each color filter of the color filter structure,
A color image reading apparatus, characterized in that each transmitted color light is formed of a material having a different refractive index corresponding to a difference in wavelength of transmitted light so as to form a converging point on the photoelectric conversion element. 3. A photoelectric conversion element, which is arranged so as to face a document set at a predetermined position and reads a color image of the document surface by self-scanning, and light from the document surface illuminated by a light source is focused on the photoelectric conversion element. A condensing lens for
Each of the color filters has a plurality of different types of color filters, and these color filters are provided on the optical axis of the condenser lens to obtain each transmitted color light, and a color filter structure from a document surface illuminated by a light source is provided. Light is focused on the photoelectric conversion element through the condensing lens and the color filter of the color filter structure, and color-separated by each color filter of the color filter structure, whereby a color image on the document surface is converted into the photoelectric conversion element. In a color image reading device configured to read by, each color filter of the color filter structure,
A color characterized in that each transmitted color light is formed of a material having a different refractive index and a different thickness in order to form a converging point on the photoelectric conversion element in accordance with the difference in the wavelength of the transmitted light. Image reading device.