JPH07108973B2 - Document reader - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a document reading device, and more particularly to a document reading device using a fluorescent lamp having a plurality of emission spectra that change with time.

[Prior Art] As a method for photoelectrically reading a color image on a document in an image input section of a facsimile, a filter switching method, a light source switching method, and the like have been attracting attention in recent years.

In this light source switching system, a plurality of light sources having different spectral characteristics are sequentially blinked while irradiating the original surface with light in synchronization with the original reading scanning cycle of the image sensor, and the reflected light from the original is instantaneously coupled to the image sensor. By forming an image, a plurality of types of photoelectric conversion signals corresponding to the number of the light sources are obtained for the same scanning line of the document, and thereafter, scanning is performed on the basis of the levels of these photoelectric conversion signals to scan and scan the scanning line of the document. The color of the image is determined.

In this system, for example, as shown in FIG. 5, a blue fluorescent lamp is used.
21 and the red fluorescent lamp 22 are sequentially blinked in synchronization with the scanning cycle of the image sensor 23 by a predetermined lighting circuit (not shown), and the blue fluorescent lamp 21 emits blue light BL.
However, the red light RL from the red fluorescent lamp sequentially irradiates the same portion (line) of the document 24. Then, the reflected light from the document 24 is imaged on the image sensor 23 through the lens system 25, and is converted by the image sensor 23 into a photoelectric conversion signal of an electrical level corresponding to the light amount of the reflected light, and a signal processing circuit. At 26, color discrimination is performed, and the extracted image signal is corrected so that the receiving side can perform preferable color reproduction.

By the way, the blue fluorescent lamp 21 and the red fluorescent lamp 22, respectively, are configured by utilizing the light emission of calcium tungstate, magnesium germanate, on the same line while irradiating the light from each fluorescent lamp. One by one
You have to scan each time. Therefore, since two fluorescent lamps are used, it is difficult to synchronize the timing of lighting and scanning, and it is impossible to perform reading with good positional accuracy, and the configuration of each lighting circuit becomes complicated, There is a problem that the device becomes large.

[Problems to be Solved by the Invention] As described above, in the conventional color original reading apparatus, when the emission spectrum has to be sequentially changed, in order to make a plurality of light sources blink in synchronization with each other, timing synchronization is required. However, there is a problem in that the position accuracy is lowered and the device becomes large in size.

The present invention has been made in view of the above circumstances, and provides a small-sized document reading device with high accuracy and high reliability that can read two or more colors with one scan per line. The purpose is to

[Means for Solving Problems] In the present invention, when phosphors having different afterglow characteristics are simultaneously excited (lighted), the emission spectrum changes with time after the excitation is stopped (after light is turned off). In order to use it for reading the original, at least two kinds of phosphors with different afterglow characteristics are used in a single fluorescent lamp to obtain an emission spectrum that changes with time when the lamp is turned off. It is characterized by having done.

That is, the document reading apparatus of the present invention includes at least two types of phosphors having different afterglow characteristics, and obtains an emission spectrum that changes with time based on the difference in the afterglow characteristics of each of the phosphors when turned off. And an image reading unit for reading the reflected light of the document based on the light emission of the fluorescent lamp and the reflected light of the document based on the afterglow when the fluorescent lamp is turned off.

[Operation] With such a configuration, it is possible to obtain a spectrum similar to that emitted from a plurality of types of light sources sequentially from one light source, and thus it is possible to read two or more colors by one scan per line. In addition to being able to perform high-precision reading without misalignment, the structure of the lighting circuit is simple and
The size of the device can be reduced.

[Embodiment] Hereinafter, a document reading apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

This document reading apparatus uses two light sources having different afterglow characteristics.
A fluorescent lamp that is equipped with various types of phosphors and that, when turned off, obtains an emission spectrum that changes with time based on the difference in the afterglow characteristics of each of the phosphors, and the reflected light of the original based on the emission of this fluorescent lamp. And an image reading unit for reading the reflected light of the document based on the afterglow when the fluorescent lamp is turned off.

This fluorescent lamp, as shown in the schematic diagram in FIG.
Magnesium germanate Mg ₂ GeO on the inner wall of the glass tube 1.
₄ and a phosphor layer 2 containing calcium tungstate CaWO ₄ as a main component are applied, and the mercury atom 3 enclosed in the glass tube 1 serves as a cathode and is formed on both ends of the glass tube 1. The graphite electrode 4 thus formed is used as an anode, arc discharge is generated between these electrodes, and the phosphor layer 2 coated on the inner wall of the glass tube is stimulated by the emission spectrum resulting from the arc discharge. As shown in FIG. And fluorescence spectra a and b having two peak wavelengths of blue and blue are emitted. In addition, in FIG.
The vertical axis I shows the light intensity, and the horizontal axis shows the wavelength λ. The red spectrum a is due to the light emission of germanium, and the blue spectrum b is due to the light emission of calcium tungstate, but the former has a longer afterglow time than the latter and emits light for a certain period of time after being turned off. To last.

Therefore, by blinking this fluorescent lamp with a blinking signal of an appropriate frequency, the emission spectrum can be changed periodically.

Utilizing this fact, FIG. 3 shows an original reading device using this fluorescent lamp as a light source of a two-color original reading device.

This device uses the fluorescent lamp as a light source to irradiate a document traveling in the direction of the arrow with light, and (line + red +
An attempt is made to alternately read two colors of (blue) spectrum and (red) spectrum. Light from the fluorescent lamp 12 reflected by the original 11 is guided to an image sensor 14 via a lens system 13, and the image sensor The image signal read by 14 is digitized by the A / D converter 15, and further corrected by the signal correction circuit 16 so that the image signal is reproduced on the receiving side preferably, and stored in the random access memory (RAM) 17. It is something that is done.

In this fluorescent lamp, as shown in FIG. 4, by giving a blinking signal S of an appropriate blinking frequency, the magnesium germanate having a long afterglow time can emit the next lighting signal as shown by a characteristic curve R. While it continues to emit light until it is given, the calcium tungstate having a short afterglow time emits light for a while after lighting as shown by the characteristic curve B. Therefore, these emission spectra are combined into a red + red spectrum as shown in FIG. 4C.
Alternating blue and red spectra.

By using this fluorescent lamp, the conventional two-color original reading device requires two fluorescent lamps and one line must be read twice by each fluorescent lamp, whereas one fluorescent lamp is used. It is only necessary to use the lamp, and it is possible to read a two-color original by scanning once for each line, and the apparatus is extremely simplified and downsized.

In the above-mentioned embodiment, magnesium germanate and calcium tungstate were used as a combination of phosphors having different afterglow characteristics, but the combination is not necessarily limited to this and can be appropriately selected as needed. It is also possible to use three types of phosphors having different afterglow characteristics and emission spectra to form a fluorescent lamp that can periodically change the three types of emission spectra.

[Effects of the Invention] As described above, according to the document reading apparatus of the present invention, a plurality of types of phosphors having different afterglow characteristics are used, and the emission spectrum changes with time when turned off. Therefore, a plurality of different emission spectra similar to those emitted from a plurality of light sources can be sequentially obtained with one lamp light source, the structure of the lighting circuit is simplified, and the device can be downsized.

[Brief description of drawings]

FIG. 1 is a diagram showing a fluorescent lamp used in a document reading apparatus according to an embodiment of the present invention, FIG. 2 is a diagram showing an emission spectrum of the fluorescent lamp shown in FIG. 1, and FIG. FIG. 4 is a diagram showing an example original reading device, FIG. 4 is an operation explanatory view of the original reading device of the embodiment of the present invention, and FIG. 5 is a diagram showing a conventional two-color original reading device. 1 ... glass tube, 2 ... phosphor layer, 3 ... mercury atom, 4
...... Graphite electrode, 11 …… Document, 12 …… Fluorescent lamp, 13 ……
Lens system, 14 …… image sensor, 15 …… A / D converter, 1
6 …… Signal correction circuit, 17 …… Random access memory,
S: blinking signal, R: curve showing the emission state of magnesium germanate, B ... curve showing the emission state of calcium tungstate, C ... curve showing the synthesized spectrum, 21 ... blue fluorescent lamp, 22 ... Red fluorescent lamp, 23 ...
Image sensor, 24 manuscript, 25 lens system, 26
... Signal processing circuit.

Claims (1)

[Claims] 1. A fluorescent lamp comprising at least two types of phosphors having different afterglow characteristics, and capable of obtaining an emission spectrum which changes with time based on the difference in the afterglow characteristics of the respective phosphors when turned off. An original reading device comprising: an image reading unit that reads reflected light of the original based on light emission of the fluorescent lamp and reflected light of the original based on afterglow when the fluorescent lamp is turned off.