JPS634989B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION A. Technical Field of the Invention The present invention relates to an image information reading device that converts optical information on image information paper into electrical signals and reads them.
In particular, the present invention relates to an image information reading device in which the optical filter of the photoelectric conversion section can be switched to a plurality of types having different transmission wavelengths, and the image output and pixel size for reading are kept constant even when the switching is performed.

B. Background of the Technology In image information reading devices such as optical character reading devices, facsimile machines, and copying machines, optical filters and charge-coupled devices are used in photoelectric conversion units that convert optical information on image information paper such as forms into electrical signals. have. Since this charge-coupled device has a sensitivity peak near the wavelength of red light or infrared light, a red filter or an infrared filter is usually used as the optical filter. In this case, there is no problem if all the information on the image information paper, such as letters and line diagrams, is in a color other than red, but there has been an increasing demand to read letters, line diagrams, seals, etc. written in red. . At this time, if a red filter is used, the red characters, diagrams, seals, etc. become transparent to the red color of the surrounding background and cannot be seen as characters at all. Therefore, if you use a green filter, which is a complementary color to red, the red characters, line diagrams, seals, etc. mentioned above will become black characters,
It can be seen as a diagram, etc., and read as image information. However, since the amount of light transmitted through the green filter is only about one-third of the amount of light transmitted through the red filter, the sensitivity of the charge-coupled device falls to about one-third of that when using the red filter. Therefore, if the transport speed of the image information paper is the same as when using the red filter, the video output voltage for reading the charge coupled device will drop to about one-third. In order to make this video output similar to that of the red filter, the storage time of the charge-coupled device should be increased approximately three times, but in this case, the pixel size of the sub-scanning method increases approximately three times. Therefore, there is a need for an image information reading device that can output the same amount of video as when using a red filter and keep the pixel size constant even when switching to a green filter.

C. Purpose of the invention The present invention has been made in response to the above circumstances.
It is an object of the present invention to provide an image information reading device that can switch the optical filter of a photoelectric exchange unit to multiple types with different transmission wavelengths, and can keep the reading video output and pixel size constant even when switching. shall be.

D. Structure of the Invention The object of the invention is to include a paper feeding section that transports image information paper by combining a pulse motor and a drive roller, a light source section that irradiates reading light onto the image information paper, and an optical filter. In an image information reading device comprising a photoelectric conversion unit that combines a lens and a charge-coupled device on the same axis to photoelectrically convert the reflected light from the image information paper, the optical filter has a plurality of types having different transmission wavelengths. a filter switching mechanism configured to sequentially switch and arrange each of the optical filters on the optical axis, and a rotational operation of the pulse motor and a shift operation of the charge-coupled device to be synchronized with each other. a clock generator for sending a clock signal from a common oscillation source to the pulse motor and the charge-coupled device; a detection means for detecting the type of optical filter disposed on the optical axis; Based on the detection result, the clock frequency from the clock generating section is set to the image information such that the charge-coupled device has an accumulation time that equalizes the difference in the amount of transmitted light for each optical filter, and the pixel size is constant. This is achieved by providing an image information reading device characterized by comprising a clock frequency switching means for switching to a frequency that gives the paper conveyance speed.

E. Embodiments of the Invention Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

An image information reading device, such as an optical character reading device, according to the present invention includes a mechanism section, a control section, and a recognition section. As shown in FIG. 1, the mechanism section includes a hopper section 2 that stores image information sheets 1 such as documents and sequentially feeds out the image information sheets 1, and a hopper section 2 that sequentially feeds out the image information sheets 1 such as documents, and one image information sheet 1 that is fed out from the hopper section 2. a separator section 3 that separates the separated image information sheets 1, an aligner section 4 that sets the separated image information sheets 1 on a reading reference surface, and a reading section 5 that reads the image information sheets 1 set on the reading reference surface by running at a constant speed. , transport units 6 and 6' that transport the image information paper 1 that has been read to stacker units 7 and 7', which will be described later, and stacker units 7 and 7' that store the transported image information paper 1. It becomes.

As shown in FIG. 1, the reading section 5 has a paper feeding section that combines a pulse motor 8 and drive rollers 9, 9' to run the image information paper 1 at a constant speed, and has a light source 10 such as a halogen lamp. and a transparent plate 11 to irradiate the image information paper 1 with reading light, and a reflecting mirror 12 that changes the light reflected from the image information paper 1 in a predetermined direction, and light of a necessary wavelength. An optical filter 13 that extracts only the image, a lens 14 that forms a reduced image at an appropriate rate, and a charge-coupled device (CCD)
15 on the same optical axis 16 to photoelectrically convert the reflected light from the image information paper 1.

As shown in FIG. 2, the optical filter 13 of the photoelectric conversion section is constructed by arranging a first optical filter 13' and a second optical filter 13'', each having a different transmission wavelength, adjacent to a holder 17. There is.
Here, as the first optical filter 13', a red filter is used that provides the amount of transmitted light for which the charge-coupled device 15 has the highest sensitivity, and as the second optical filter 13'', red characters, diagrams, or seals are used. A green filter, which is a complementary color to red, is used to view the images as black characters, line diagrams, etc.

A filter switching mechanism 18 is provided at the base end of the holder 17. This filter switching mechanism 18 includes a solenoid 19 connected to the base end of the holder 17, a filter switching detection switch 20',
20''.Then, the solenoid 19
When the holder 17 is driven, the holder 17 slides in the direction of arrow A or B in a plane orthogonal to the optical axis 16, and the first optical filter 13' is placed on the optical axis 16.
Alternatively, the second optical filter 13'' can be made to appear or disappear by switching as appropriate. At this time, the contactor 21' of the filter switching detection switch 20' or 20''
Or the protrusion 2 of the holder 17 on which 21" slides
2' or 22'', the respective internal microswitches are actuated to send out filter switching signals S1 or S2 from leads 23' or 23'', respectively. Note that instead of using the solenoid 19, the operator may manually switch. Also,
As shown in FIG. 3, a clock generator 24 is connected to the pulse motor 8 and the charge-coupled device 15, and a clock signal for rotating the pulse motor 8 and a clock signal to the charge-coupled device 15 are connected to the pulse motor 8 and the charge-coupled device 15. The clock signal for performing the shift operation to output the received light signal is generated by the clock generator 24.
Supplied from. This clock generating section 24
consists of a reference clock circuit 25, a frequency dividing circuit 26, and a changeover switch 27.
is the filter changeover detection switch 20' or 2
In response to the switching signals S1 and S2 sent from 0'', the contacts 28 and 29 are switched and connected to switch the reference clock circuit 25 and the frequency divider circuit 26, and drive the pulse motor 8 and charge-coupled device 15, respectively. A clock signal of the same frequency is sent through the circuit 30 or 31.The clock pulse of the reference clock circuit 25 has a period of _t1 , as shown in FIG. The clock pulse after passing through 26 is
As shown in FIG. b, the period _t2 is about three times the above-mentioned _t1 , and the clock frequency is about one third of the original.

When the changeover signal S1 sent from one of the filter changeover detection switches 20' shown in FIG. The pulse motor 8 and charge-coupled device 15 are supplied with a reference clock signal 3 as shown in FIG. 4a.
2 is sent out and the switching signal S2 sent out from the other filter changeover detection switch 20'' is input, the changeover switch 27 is connected to the other contact 29 side and the pulse motor 8 and the charge coupled device 1 are connected.
5, a clock signal 33 of the frequency divider circuit shown in FIG. 4b is sent. This includes a red first optical filter 13' and a green second optical filter 1.
3'', there is a difference in the amount of transmitted light of about three times between them, so the conveyance speed of the image information paper 1 and the storage time of the charge-coupled device 15 are set accordingly.

Next, the operation of the image information reading device according to the present invention will be explained. First, if the image information sheet 1 does not contain red characters, line diagrams, or seals,
The solenoid 19 of the filter switching mechanism 18 shown in FIG. 2 is driven to slide the holder 17 in the direction of arrow A to set the red first optical filter 13' on the optical axis 16. At this time, the protruding piece 22' at the base end of the holder 17 presses only the contact 21' of one filter changeover detection switch 20', and the micro switch of the filter changeover detection switch 20' is operated to operate the filter. A switching signal S1 is sent out. This switching signal S1 is transmitted to the clock generator 24 through the lead 23' as shown in FIG.
The changeover switch 27 is inputted to the changeover switch 27, and the changeover switch 27 is connected to the contact 28 side. In this state, from the reference clock circuit 25 to the pulse motor 8 and the charge coupled device 15 via the contact 28, the changeover switch 27, and the respective drive circuits 30 or 31,
A reference clock signal 32 shown in FIG. 4a is input. This reference clock signal 32 causes the pulse motor 8 and the charge coupled device 15 to operate synchronously. That is, the image information paper ₁ is conveyed at a period of t1 shown in FIG. 4a, and the charge coupled device 1
5 is activated.

Next, if the image information paper 1 contains red characters, diagrams, seals, etc., the solenoid 19 is driven to remove the holder 17 as shown in FIG.
slide in the direction of arrow B to set the green second optical filter 13'' on the optical axis 16. At this time, the protruding piece 22'' at the base end of the holder 17
presses only the contact 21'' of the other filter changeover detection switch 20'', and the micro switch of the filter changeover detection switch 20'' operates to send out the filter changeover signal S2.This changeover signal S2
As shown in FIG. 3, is input to the changeover switch 27 of the clock generator 24 through the lead 23'', and the changeover switch 27 is connected to the other contact 29 side.In this state, the frequency dividing circuit 26 to contact 29, selector switch 27, and respective drive circuits 3
A clock signal 33 of a frequency dividing circuit shown in FIG. The pulse motor 8 and the charge-coupled device 15 operate in synchronization with the clock signal 33 of this frequency dividing circuit. Therefore, the fourth
As shown in FIG. b, the image information paper 1 is conveyed at a period t ₂ that is approximately three times as long as t ₁ , that is, at a speed that is approximately one-third, and the charge-coupled device 15 is activated at the period t ₂ described above. do. As a result, even when switching to the green second optical filter 13'', it is possible to obtain the same reading video output as when using the red first optical filter 13', and
The pixel size can also be kept constant.

Furthermore, although the red and green filters have been described in this embodiment, the present invention is not limited thereto, and it goes without saying that it can be applied to cases where other filters with different amounts of transmitted light are used. do not have.

F Effects of the Invention Since the present invention is configured as described above, it is possible to switch the optical filter 13 of the photoelectric conversion unit to multiple types with different transmission wavelengths, and even when this switching is performed, the reading image output and pixel size can be adjusted. can be kept constant. If a green filter is used as the second optical filter 13'', all image information can be read even if the image information paper 1 includes red characters, line drawings, seals, etc.

Furthermore, the clock signals supplied to the charge-coupled device and the pulse motor are from the same clock oscillation source, and the frequency is switched in conjunction with the switching operation of the color filter. It is possible to prevent erroneous operations when varying the storage time of the coupling element and the conveyance speed of the pulse motor.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram showing the mechanical part of the image information reading device according to the present invention, FIG. 2 is a plan view showing the reading part, FIG. 4a and 4b are waveform diagrams showing the reference clock signal and the clock signal of the frequency dividing circuit, respectively. 1... Image information paper, 5... Reading section, 8... Pulse motor, 9, 9'... Drive roller, 10...
Light source, 11...Translucent plate, 12...Reflector, 13...
...Optical filter, 13'...First optical filter,
13″...Second optical filter, 14...Lens,
15...Charge coupled device, 16...Optical axis, 17...
Holder, 18... Filter switching mechanism, 19...
Solenoid, 20', 20''... Filter change detection switch, 24... Clock generator, 25... Reference clock circuit, 26... Frequency dividing circuit, 27... Changeover switch, 32... Reference clock signal, 33...
...Clock signal of the frequency dividing circuit, S1, S2...Switching signal.

Claims (1)

[Claims] 1. It has a paper feeding section that conveys the image information paper by combining a pulse motor and a drive roller, it has a light source section that irradiates the image information paper with reading light, and it has an optical filter, a lens, and a charge coupled device that are the same. In an image information reading device comprising a photoelectric conversion unit that is combined on an axis to photoelectrically convert reflected light from the image information paper, the optical filter is composed of a plurality of types of optical filters having different transmission wavelengths, and , a filter switching mechanism for sequentially switching and arranging each of the optical filters on the optical axis; and a filter switching mechanism for sequentially switching and arranging each of the optical filters on the optical axis; a clock generating section that sends out a clock signal from a common oscillation source; a detection means for detecting the type of optical filter disposed on the optical axis; and based on the detection result of the detection means,
The clock frequency from the clock generating section is used to provide the accumulation time of the charge-coupled device to equalize the difference in the amount of transmitted light for each optical filter, and to provide the conveyance speed of the image information paper so that the pixel size is constant. 1. An image information reading device comprising: clock frequency switching means for switching the frequency.