JPS63303571A - Optical reader - Google Patents

Abstract

PURPOSE:To clearly read a picture on an original, the background color of which is not white by correcting data, obtained by a white level check it a reference member having a constant reflection factor, on the basis of the data, obtained by a white level check at the surface of the original. CONSTITUTION:A CPU 7 sends light quantity data to a D/A converter 4, and an output signal from the D/A converter 4 is outputted to drive control circuits C1-Cn through a multiplexer 1, and the drive control circuits C1-Cn light respective LEDs L1-Ln. Their light illuminate points D1-Dn to be read on the surface of the original through corresponding light emitting side optical fibers T1-Tn. The reflected light is received by the end parts of the original side of corresponding light receiving side optical fibers R1-Rn, and the fibers R1-Rn transmit the light to a photoelectric conversion element 2, connected to them. The output from the photoelectric conversion element 2 is compared with a reference value by a comparator 3, and when it reaches the reference value, the data, being inputted in the D/A converter 4, is stored in a RAM 5 separately by the light receiving side optical fibers R1-Rn.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical image reading device used in facsimile machines, copying machines, etc., for reading images written on manuscripts, etc.

[Prior Art] This type of optical reading device includes a light emitting element (hereinafter referred to as an LED) and a first light emitting element that irradiates a document with light from the light emitting element.
an optical component (for example, a light-emitting fiber), a second optical component (for example, a light-receiving fiber) that receives and transmits the reflected light from the document, and the light is transmitted via the light-receiving fiber. A plurality of optical systems each including a light receiving element (hereinafter referred to as SPD) that receives light, a detection means that detects the output of the light receiving element in the optical system, and a constant reflectance at the position of the original with respect to the optical system. A member is arranged relative to the optical system, the LED emits light and the detection means detects the output of the SPD, and the LE is set so that the output of the detection means in each optical system becomes a predetermined value.
and control means for adjusting the light amount of D or the output of the SPD.

In an optical image input device, in order to accurately read an image on a document, it is necessary to adjust the brightness of each LED so that the output signal from the SPD is at a constant level. Conventionally, a so-called white level check method has been used as this subsurface method.

The light emitted from the LED is irradiated onto a white reference material (white member) via the light-emitting fiber, the SPD receives the light via the light-receiving fiber, and the SPD outputs a signal according to the amount of light. In this method, the brightness of the LED is determined so that the signal inputted to the detection means is constant when the detection means is used.

[Problems to be Solved by the Invention] Conventionally, this type of white level check is performed by reading the white level of a white reference material placed in the reading unit before starting reading the document. This optical reading device then reads the original after correcting the reading level. However, if the color of the document is not white, such as a yellowish newspaper, the background color of the document will not be determined as white.
The optical reader could not accurately read the image on this document.

[Object of the Invention] The present invention has been made in order to eliminate the drawbacks of the above-mentioned prior art.After checking the white level with a reference member having a certain reflectance, the original is placed in the reading section. By checking the white level on the original surface and correcting the data from the white level check on a reference member with a certain reflectance based on the data from the white level check on the original surface, it is possible to detect the original surface where the background color is not white. It is an object of the present invention to provide an optical reading device that can clearly read the above image.

[Means for Solving the Problems] In order to achieve this object, the optical reading device of the present invention includes a light emitting element and a first optical component that irradiates the reading unit with light emitted from the light emitting element. a plurality of optical systems including a light receiving element and a second optical component that transmits the reflected light from the reading section to the light receiving element; a detection means for detecting the output of the light receiving element; A first arrangement means for arranging a member having a constant reflectance at the position of the reading section relative to the optical system, and after the arrangement by the first arrangement means is completed, the light emitting element is caused to emit light, and the detection means adjusting means for detecting the output of the light-receiving element and adjusting the light amount of the light-emitting element or the output of the light-receiving element so that the input of the detection means in each optical system becomes a predetermined value; In an optical reading device comprising a first storage means for storing the light amount of the light emitting element or the output of the light receiving element, after the control operation by the control means is completed, the white color of the original is stored at the position of the reading section with respect to the optical system. a second arranging means for arranging the parts; and a second storage means for executing the adjustment by the adjusting means after the arrangement of the second arranging means and storing the light amount of the light emitting element or the output of the light receiving element in that case. and a correction means for correcting the data stored in the first storage means based on the data stored in the second storage means.

[Example] Hereinafter, an example embodying the present invention will be described with reference to the drawings.

FIG. 1 shows a block diagram of this embodiment.

In response to instructions sent according to a program stored in the ROM 6, the CPU 7 adjusts the light amount of each of the plurality of light sources L1 to ln based on the light amount data input from the ROM 6.

That is, the CPU 7 sends light amount data to the D/A converter 4, and the output signal from the D/A converter 4 is sent to the drive control circuit C via the multiplexer 1, which is in charge of time division control.
1 to Cn, and the drive control circuits C1 to Cn are output to each LE.
Turn on DLz~ln. The light illuminates points D1 to Dn on the document surface to be read through corresponding light emitting optical fibers T1 to Tn. The reflected light is received at the end of the corresponding light-receiving side optical fiber R1 to Rn on the document side, and the fiber R1 to Rn transmits it to the photoelectric conversion element 2 connected thereto.

The output from this photoelectric conversion element 2 is compared with a reference value by a comparator 3, and when the reference value is reached, the data input to the D/A converter 4 is transferred to the RAM 5 separately from the plural light-receiving side optical fibers R1 to Rn. The CPU 7 stores the information.

FIG. 2 shows a flowchart showing the white level checking operation as the adjusting means in this embodiment.

First, in step 1, 1 is input into the N and M registers for counting, and then in step 2, the reading device is moved to a white reference value having a constant reflectance. In step 3, the n-th drive control circuit is designated based on the contents of the N register, and the m-th test data is read out from the ROM 6 and output based on the contents of the M register (step 4).

In step 5, the output of the comparator is set to the reference fa (SG=1
>If the result is above, in step 6, the test data at that time is stored in the RAM 5 as appropriate light amount data.

If the register N is not 16 in step 7, this operation is repeated until N=16 as shown in step 8. At this time, as shown in step 8, the M register is reset to "1''. Also, in step 7, N=
16, the start-on switch can be input (step 9). By the way, if the output of the comparator to which the m-th test data is input does not exceed the reference value in step 5, as shown in step 10, m=13.
Step 12 so that the light amount of the light emitting element increases until
．． Step 4. Repeat step 5. m
If it does not match the reference value when =13, step 11
At this point, a failure is displayed on the display device 8 and the process ends.

The operation of this embodiment will be explained according to the flowchart shown in FIG.

Since the white level check is performed for each LED L1 to Ln, in step 1, first, a register for counting the number of LEDs is specified, and "1" indicating that it is the first LED is input into it. Next, in step 2, a white level check shown in FIG. 2 is performed immediately before reading the document. In step 3, the CPU 7 performs a white level check and stores the obtained appropriate data x 1 in the RAM 5. This kind of white level check is performed on all LEDs (in this case, the LED
(The number P is 104) (Step 4)
If there is no abnormality, the white portion of the document is read (step 5). P for LED count in step 6
Reset the register and input "1pa" again. In step 7, check the white level shown in FIG. 2 on the white part of the document, and use the appropriate light amount data X2 obtained from the white level check in the same way as before. RAM5
to be memorized. This is performed for each LEDL+ to 1-n (step 8). Next, reset the P register for LED counting again in step 10, input "1", and as shown in step 11, calculate the difference X+2 between the appropriate light amount data X obtained by checking the white level twice and X2. is determined, and it is determined whether this difference is within the allowable range (Ch < 8 (step '13). This mode is executed for all LEDLn (step '13).
1 to step 15). In step 16, the difference X12
Calculate the average 1 shift tn. In steps 17 to 20, the average value tn is added to the appropriate light amount data XI2 to correct it to the appropriate preset data Zi for that document. Then, in step 21, document reading is started.

Note that the present invention is not limited to the above-mentioned embodiments,
A reflecting mirror may be used instead of the plurality of light-emitting fibers, a lens may be used instead of the plurality of light-receiving fibers, and a light-receiving element (AMP) may be used instead of adjusting the light amount of the light-emitting element to check the white level. (including) may be controlled.

Furthermore, an A/D converter may be used instead of the comparator 3 as the detection means. Furthermore, a display device 8 constituting the detection means
may be a buzzer that outputs sound or may be an LED lamp.

[Effects of the Invention] As explained above, according to the optical reading device of the present invention, since the reading level is adjusted to the original, clear reading is possible even when the background color is not white.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment embodying the present invention, FIG. 2 is a flowchart showing the white level check of this embodiment, and FIG. 3 is a flowchart showing the operation of this embodiment. In the figure, 1 is a multiplexer, 2 is a photoelectric conversion element, 3 is a voltage comparator, 4 is a D/A converter, and 5
(Yo RAM, 6 is ROM, 7 is CPU, 8 is display device,
D1 to Dn are reading points, C+ to cn are drive control circuits,
Lt to Lrl are LEDs, T1 to TnG are light emitting side optical fibers, and R1 to Rn are light receiving side optical fibers.

Claims (1)

[Scope of Claims] A light emitting element, a first optical component that irradiates a reading unit with light emitted from the light emitting element, a light receiving element, and a second optical component that transmits reflected light from the reading unit to the light receiving element. a plurality of optical systems comprising: a detection means for detecting an output of the light receiving element; and a member having a constant reflectance at a position of the reading section relative to the optical system, which is arranged relative to the optical system. and a first arrangement means for causing the light emitting element to emit light and detecting the output of the light receiving element by the detection means after the arrangement of the first arrangement means is completed, so that the input of the detection means in each optical system becomes a predetermined value. an adjusting means for adjusting the light quantity of the light emitting element or the output of the light receiving element; and a first apparatus for storing the light quantity of the light emitting element or the output of the light receiving element adjusted by the adjusting means.
an optical reading device comprising: a second arranging means for arranging a white portion of a document at a position of the reading section with respect to the optical system after the control operation by the control means is completed; After the arrangement is completed, a second storage means executes the adjustment by the adjustment means and stores the light amount of the light emitting element or the output of the light receiving element in that case; and the second storage means stores the data stored in the first storage means. What is claimed is: 1. An optical reading device comprising: a correction means for correcting data based on data stored in a storage means.