JPS6251020B2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to an image information reading device.

Examples of conventional image information reading devices include:
As shown in FIG. 1, a fiber substrate 2 is placed near the image information 1 conveyed by a pair of scanner rollers.
2, a light sensor 3 is installed on the upper surface of the fiber substrate 2, and a light source 4 is arranged to illuminate one side (image information reading section) of the fiber substrate 2, as shown in FIG. An apparatus is known in which image information of a document 1 is imaged on an image information reading section of a solid-state imaging device 6 (CCD) via a lens 5 to obtain the image information as an electrical signal.

In the device using the optical fiber shown in FIG. 1, since the light source 4 is disposed outside the fiber substrate 2, the effective illumination flux of image information irradiated by the light source 4 is reduced, so the light utilization is reduced. Efficiency will be significantly lower. Furthermore, in the illustrated example, the light receiving width of the optical sensor 3 with respect to the light reflected by the fiber substrate 2 is small, so a high-output light source is required in consideration of the sensitivity of the optical sensor 3. Furthermore, light source 4
Since it is necessary to install the fiber in the immediate vicinity of the fiber, it is unreasonable in terms of arrangement, and also shading correction is required.

The present invention provides an image information reading device using an optical fiber, which was developed in view of the above points, and its purpose is to improve the utilization rate of a light source and the reliability of reading image information.

The present invention will be explained below with reference to illustrated embodiments.

FIG. 3 shows an example of an image information reading device using a bundle of optical fibers bent in a V-shape.

A light source 14 is integrally disposed at one end of an optical fiber bundle 20 having a V-shaped bent portion 20a, and an amorphous semiconductor optical sensor 13 is integrally disposed at the other end, and one of the thin optical fiber bundles 20A has a small number of propagation modes. The light source light propagating through the bending part 20a is emitted outward from the bending part 20a, the emitted light illuminates image information placed near the bending part 20a, and the reflected light from this image information is introduced from the bending part 20a. Then, it is guided into the other thick optical fiber bundle 20B having a large number of propagation modes, and an electric signal corresponding to the image information is obtained by the amorphous semiconductor optical sensor 13 disposed at the end of the optical fiber bundle. This is what I did. In addition,
The bent portion 20a of the fiber bundle is arranged near the original 1, and preferably arranged so that the irradiation angle and the reflection angle of the irradiated light from the light source 14 are approximately equal.

As is clear from the above embodiments, according to the image information reading device of the present invention, the light source 14 is directly disposed at the end of the light source fiber 20A.
The irradiation light from the light source 14 passes through the light source fiber 20A and is efficiently emitted from the bent portion 20a of the fiber bundle 20, so that the image information of the original 1 is irradiated. In addition, since this irradiated portion directly becomes the reading portion for image information, the scattered light is effectively introduced from the bent portion 20a, passes through the reading fiber 20B, and reaches the photonic crystalline semiconductor optical sensor 13.
An electrical signal corresponding to image information is obtained. As is clear from the above, according to the present invention, an image information reading device with high light utilization efficiency of a light source and high reliability in reading image information is provided.

Since the present invention uses an amorphous semiconductor optical sensor, it is possible to create a long optical sensor of about 200 mm, and a contact type image information reading device can be obtained, which can be used as a document reading device for a facsimile machine, for example. Optimal equipment will be provided. Note that if the optical sensor is a solid-state image sensor (CCD) as shown in Figure 2, it is not possible to obtain a long sensor, so a means of compressing image information such as a lens is required. It becomes impossible to provide information reading devices. By the way, the sensor of the present invention can be a long sensor because the sensor part (semiconductor) is amorphous and can be formed by vapor deposition or sputtering.

FIG. 4 shows an example of an amorphous semiconductor optical sensor. This sensor consists of a Cr layer B on top of a transparent electrode A.
and Se-As-Te films C are deposited, respectively, and an Au electrode D is further deposited or sputtered thereon.

Therefore, if this optical sensor is used, a long image information reading device that integrates the above-mentioned fiber bundle and optical sensor can be provided. FIGS. 5 to 7 show an example of manufacturing this reading device.

For example, as shown in FIG. 5, the unit fiber 20 shown in FIG.
0B are arranged in a straight line and fixed on a fiber substrate 30 by means such as plastic forming, and the ends of the reading fibers 20B of this fiber substrate 30 are polished to obtain a smooth surface. A transparent electrode A is placed on this smooth surface as shown in FIG.
(SnO ₂ or In ₂ O ₃ ) to form one electrode of the sensor. Next, Cr is deposited on this transparent electrode A.
Layer B, Se-As-Te film C, and Au electrode are vapor-deposited or sputtered to form a long amorphous semiconductor optical sensor 13 integrated with the fiber bundle, while unit fibers 20A for the light source are assembled together. The end face is used as a light source 14 as a fiber bundle.
An image information reading device is completed by integrating the light emitting surface of an LED (for example, an LED) (see FIG. 7).

As the fibers in the above embodiments, a thin fiber with a small number of propagation modes is used as an illumination fiber, and a thick fiber with a large number of propagation modes is used as a reading fiber. This is because the light from the illumination light source is efficiently converted into a part of the propagation mode of the reading fiber at the bend of each fiber, and the scattered light from the document surface of the illumination light irradiated through the illumination fiber is used for reading. This is because all modes of the fiber are excited, and only a part of the modes are effectively used as reading light except for being absorbed by the illumination fiber.

As described above, according to the present invention, the utilization efficiency of the light source and the reliability of reading image information are high.
It is possible to provide an image information reading device that is small and has a large reading width.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram of an example of a conventional image information reading device using a fiber, FIG. 2 is an explanatory diagram of an example of a conventional image information reading device using a lens, and FIG. 3 is an explanatory diagram of an example of a conventional image information reading device using a lens. An explanatory diagram, FIG. 4 is an explanatory diagram showing an example of a photosensor using an amorphous semiconductor, and FIGS. 5 to 7 show still other embodiments of the present invention using the above amorphous semiconductor photosensor. It is an explanatory view of a manufacturing example. 1... Original (image information), 20... Fiber, 20
A... Illumination fiber, 20B... Reading fiber, 13... Amorphous semiconductor optical sensor, 14... Light source.

Claims (1)

[Claims] 1 A light source is integrally disposed at one end of an optical fiber bundle having a refracting portion, and an amorphous semiconductor optical sensor is integrally disposed at the other end, and the light from the light source propagates through one thin optical fiber bundle with a small number of propagation modes. The emitted light is emitted outward from the bent part, the emitted light illuminates image information placed near the bent part, and the reflected light from this image information is introduced from the bent part to generate the other propagation mode. An image information reading device characterized in that an electrical signal corresponding to image information is obtained by guiding a large number of thick optical fibers into a bundle and using an amorphous semiconductor optical sensor disposed at the end of the optical fiber bundle.