JP3400807B2 - Image forming device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming apparatus for optically reading a manuscript and recording it on a recording medium, and in particular, a forgery preventing function of paper sheets for which copying of banknotes, securities or various kinds of cash vouchers is prohibited. The present invention relates to an image forming apparatus that can be used in a copier or the like equipped with the.

[0002]

2. Description of the Related Art In the hard copy of a copying machine or the like, technical development has been advanced for the purpose of forming an image faithful to an original, and as a result, in recent years, a reproduced image which is indistinguishable from the original image is formed. Color copiers that can do this are also commercially available. If a reproduced image very close to the original image is obtained in this way, it may be misused for counterfeiting banknotes or securities.

Conventionally, in order to prevent such forgery,
It is determined by feature extraction whether the input image signal is an image signal of banknotes or securities for which copying is prohibited. If it is determined that the image signal is prohibited copying, reduction processing or mirror image inversion is performed. A method has been devised to prevent forgery by reproducing an image after conversion processing (for example, Japanese Patent Laid-Open No. 1-316783).

[0004]

However, in the above-mentioned method, if the judgment as to whether or not copying is prohibited is made to some extent, normal image reproduction cannot be performed normally or copying cannot be performed normally. However, there is a problem in that a normal reproduced image can be obtained despite the prohibition.

In view of the above problems, the present invention can make clear that a copy image is a copy image by adding information that is not in the original to the copy image by utilizing the difference in density, and in particular, copying is prohibited. To provide an image forming apparatus capable of adding a signal pattern for identification to all copy images without significantly affecting copy images without requiring identification of bills, securities, etc. With the goal.

[0006]

In order to solve the above-mentioned problems, an image forming apparatus of the present invention combines a symbol pattern generating means for generating a symbol pattern with the density of the symbol pattern.
Image signal highlighting against the density of the destination image signal
The density of the symbol pattern is small in the
C) Modulate so that the density of the symbol pattern becomes large.
Modulation means and a symbol pattern modulated by the modulation means
And the image signal are combined and output to the output means.
The image forming means is provided with information by a symbol pattern.

Further, the synthesizing means detects saturation of the synthesized output.
And the symbol pattern and the image signal have a predetermined density difference.
The control is performed so that when the information based on the symbol pattern is added to the copy image, the image is saturated and the symbol pattern cannot be identified. Well
In order to solve the above problems, the image forming apparatus of the present invention
Is the image signal related to the image and a note to identify the image.
No.
A symbol pattern generating step for generating a signal pattern, and
The density of the No. pattern to the density of the image signal to be combined,
The density of the symbol pattern is low in the highlight part of the image signal
The density of the symbol pattern is high in the shadow part of the image signal.
The modulation process that modulates the
The adjusted symbol pattern and the image signal are combined and output.
And a synthesizing process that requires force.
It

[0008]

With the above structure, the intensity of the symbol pattern is modulated in accordance with the intensity of the image signal, and the intensity of the symbol pattern is reduced in the highlight portion, which is sensitive to the human density difference.
Since the insensitive shadow portion can be made large, the symbol pattern can be reliably read in any density range, and the symbol pattern can be made inconspicuous.

Further, the saturation of the composite output is detected, and
So that the signal pattern and the image signal have a predetermined density difference.
The control can prevent the image from being saturated and the symbol pattern becoming unrecognizable when the information based on the symbol pattern is added to the image.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of an image forming apparatus according to an embodiment of the present invention. In FIG. 1, 1 is an input means for converting an image into an electric signal and outputting it as an image signal, 2 is a processing means for image-processing the image signal input from the input means 1 and then outputting it, and 3 is a symbol for generating a symbol pattern. The pattern generating means 4 is a modulating means for modulating the intensity of the symbol pattern generated by the symbol pattern generating means 3 according to the intensity of the image signal processed by the processing means 2, and 5 is a symbol pattern modulated by the modulating means 4. The synthesizing means for synthesizing the image signals processed by the processing means 2 is an output means for recording the image signals synthesized by the synthesizing means 5 as an image on a recording medium.

Next, the operation of the above configuration will be described. The input unit 1 outputs an image as an image signal 101 composed of three types of signals of R, G, and B for each pixel, each of which is proportional to the reflectance of 8 bits. The processing means 2 applies color conversion processing, enlargement / reduction, trimming, and other processing to the input image signal 101, and then an image composed of four types of signals of C, M, Y, and K, each of which is proportional to the 8-bit density. Output as signal 102. On the other hand, the symbol pattern generating means 3 is a hexadecimal oo or ff symbol pattern 103 to be synthesized on the copy image.
Is output at the output timing of the processed image signal 102.

The modulation means 4 modulates the intensity of the signal pattern 103 according to the intensity of the processed image signal 102,
The processed image signal 102 is D _IN and the symbol pattern 103 is D
_{If P} and the modulated symbol pattern 104 are D _POUT , the process of D _POUT = kD _IN D _P (1) is performed. However, k is an appropriate coefficient smaller than 1.

The synthesizing means 5 synthesizes the modulated symbol pattern 104 outputted from the modulating means 4 and the processed image signal 102 outputted from the processing means 2 and outputs a synthesized image signal 105. When the processed image signal 102 is D _IN , the modulated symbol pattern 104 is D _POUT , and the combined image signal 105 is D _OUT , the process of D _OUT = D _IN + D _POUT (2) is performed. Next, the output means 6 records the combined image signal 105 on the recording medium to obtain a copied image. This copy image becomes an image to which a symbol pattern is added, and it is possible to identify that it is a copy image.

Here, a human sense of the difference in density will be described. Table 1 shows Munsell V and reflectance Y by standard light
3 is a table showing the relationship between c and Munsell V, and the relationship between concentration and concentration difference.

[0015]

[Table 1]

In Table 1, Munsell V (lightness value Valu
The relationship between e) and the reflectance Yc of standard light is based on JIS Z8721.
It was created at equal Value intervals of 0.5. The relationship between Munsell V and the concentration and the difference in concentration is obtained by using concentration = −log (Yc / 100) from this value of Yc and concentration difference = concentration (x + 0.5) −concentration (x) from this concentration. It was created. Here, the density (x) is the density at a certain value of Munsell V.

From Table 1, the density difference corresponding to the difference between Munsell V of 1 and 1.5 is as large as 0.22. On the other hand, Munsell V is 9
The density difference corresponding to the difference of 9.5 is as small as 0.06. Therefore, the difference in concentration that humans perceive as equal Value intervals is
Depending on the e value, it is high value in the low value part.
A large density difference is required compared to the low density area, that is, a high density area is required to be larger than a low density area. FIG. 4 is a graph showing Table 1, showing a large density difference in the high density portion and a small density difference in the low density portion.

As described above, the human sense of the difference in density is not uniform with respect to the density, and becomes more sensitive as the density becomes lower. Therefore, if the intensity of the symbol pattern added to the image signal for distinguishing the original from the copied image is constant, the symbol pattern becomes too conspicuous in the highlight portion and the original image cannot be read, and in the shadow portion. The problem occurs that the symbol pattern cannot be read.

However, in this embodiment, as shown in the equation (1), the image signal in which the modulated symbol pattern 104 is processed is processed.
By making it proportional to 102, the intensity of the modulated symbol pattern 103 can be reduced in the highlight part where the sensation to the human density difference is sensitive, and can be increased in the insensitive shadow part. The symbol pattern 103 can be read reliably in any density range, and the symbol pattern 103 can be made inconspicuous.

In the present embodiment, the equation (1) is used as the symbol pattern modulation method. However, the modulation method can reduce the intensity of the modulated symbol pattern 103 in the highlight portion and increase it in the shadow portion. Any method is possible.

As described above, by modulating the symbol pattern 103 according to the intensity of the processed image signal 102,
The symbol pattern 103 is not conspicuous even in the highlight part, and it is not buried in the processed image signal in the shadow part.Therefore, it is not necessary to identify whether the original is a banknote or securities for which copying is prohibited. It is possible to add a symbol pattern for identifying a document to all copied images without significantly affecting the copied images.

FIG. 2 is a block diagram showing a specific example for explaining the operation of the modulation means 4. In FIG. 2, the multiplication circuit
41 outputs an image signal 401 obtained by multiplying the processed image signal 102 by a coefficient k smaller than 1. According to the symbol pattern 103 input to the selection terminal S, the selection circuit 42 is a symbol obtained by modulating the multiplied image signal 401 input to the data terminal A or the 0 signal input to the data terminal B from the output terminal Y. Output as pattern 104.

Specifically, each of the processed image signal 102, the multiplied image signal 401 and the modulated symbol pattern 104 is an 8-bit signal, the symbol pattern 103 is a 1-bit signal, and the coefficient k is 0.5. , Processed image signal 102
If the value of is 255, the multiplied image signal 401 is 127
Becomes At this time, if the value of the 1-bit symbol pattern 103 is 1, the value 127 of the multiplied image signal 401 is output to the modulated symbol pattern 104. When the value of the 1-bit symbol pattern 103 is 0, 0 is output to the modulated symbol pattern 104. Therefore, if the processed image signal 102 is D _IN , the symbol pattern 103 is D _P , and the modulated symbol pattern 104 is D _POUT , then ifD _P = 1 then D _POUT = kD _IN (k <1) ifD _P = 0 It can be expressed as then D _POUT = 0.

When the symbol pattern 103 is an 8-bit multivalued signal and two hexadecimal signals oo or ff, the selecting circuit 42 is an AND circuit and the AND operation is performed for each bit. , A modulated image signal can be obtained as well.

FIG. 3 is a block diagram showing a specific example for explaining the operation of the synthesizing means 51. In FIG. 3, an adder circuit
51 is the processed image signal 102 and the modulated symbol pattern
The sum of 104 is output as the added image signal 502. At this time, if the addition result does not exceed the maximum value of the adder circuit 51, 0 is output to the carry signal 501, and if it exceeds the maximum value, 1 is output to the carry signal 501. The subtraction circuit 52 outputs the difference between the processed image signal 102 and the modulated symbol pattern 104 as a subtracted image signal 503. According to the carry signal 501 input to the selection terminal S, the selection circuit 53 forms an image in which the added image signal 502 input to the data terminal A or the subtracted image signal 503 input to the data terminal B is combined. Output as signal 105.

Specifically, each of the processed image signal 102, the modulated symbol pattern 104, the added image signal 502, the subtracted image signal 503 and the synthesized image signal 105 is an 8-bit signal, The carry signal 501 is a 1-bit signal, the value of the processed image signal 102 is 255, the value of the modulated symbol pattern 104 is 127, and the addition circuit
If the maximum value of 51 is 255, then the sum of the processed image signal 102 and the modulated symbol pattern 104 is 382 and the difference is
The sum becomes 128, and the sum exceeds the maximum value 255 of the adder circuit 51, so that 1 is output to the carry signal 501. At this time, since the carry signal 501 is 1 in the selection circuit 53, the value 128 of the image signal 503 subtracted as the value of the combined image signal 105 is 128.
Is output.

The value of the processed image signal 102 is 127.
, The modulated symbol pattern 104 has a value of 63, the processed image signal 102 and the modulated symbol pattern
Since the sum of 104 is 190 and 0 is output as the carry signal 501, the selection circuit 53 outputs the value 190 of the image signal 502 added as the value of the combined image signal 105.

Further, when the value of the modulated symbol pattern 104 is 0, the sum of the processed image signal 102 and the modulated symbol pattern 104 does not exceed the maximum value 255 of the adder circuit. 0 is output to 501, and the value of the added image signal 502 is output to the combined image signal 105.

Therefore, the processed image signal 102 is D
_{If IN} , the modulated symbol pattern 104 is D _POUT , and the combined image signal 105 is D _OUT , then if D _IN + D _{POUT ≤255} then D _OUT = D _IN + D _POUT if D _IN + D _POUT > 255 then D _OUT = It can be expressed as D _IN -D _POUT . Thus, according to the result of the carry signal 501 composed of D _IN + D _POUT , the D of the synthesized image signal 105 is
Choosing a value for _OUT prevents D _OUT from saturating and making the symbol pattern indistinguishable.

Further, the symbol pattern 103 of the symbol pattern generating means 3 is 1-bit data per pixel, that is,
When Dp = 1 or 0 is set as described above, the recording area of the symbol pattern 103 can be made small. that's all
As described above, according to this embodiment, the copied image contains information that is not in the original document.
Information is added to the copied image without significantly affecting it,
It is possible to clarify that it is a copied image and add it.
If you use the symbol unique to the copying machine as the information
It is used for copying when bills and securities are copied.
The copier that has
It is possible to prevent counterfeiting of value securities.

[0031]

As described above, according to the present invention, which concentration
The symbol pattern can be reliably read even in the frequency range.
Sign patterns can also be made inconspicuous.

[Brief description of drawings]

FIG. 1 is a block diagram of an image forming apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a specific example of a modulator in an image forming apparatus according to an embodiment of the present invention.

FIG. 3 is a block diagram showing a specific example of a combining device in the image forming apparatus according to the embodiment of the present invention.

FIG. 4 is a graph showing changes in the density difference of Munsell V at equal Value intervals.

[Explanation of symbols]

1 Input means 2 processing means 3 Symbol pattern generation means 4 Modulation means 5 Synthetic means 6 Output means 101 Input image signal 102 Processed image signal 103 symbol pattern 104 modulated symbol pattern 105 Composite image signal 41 Multiplier circuit 42 Selection circuit 51 Adder circuit 52 Subtraction circuit 53 Selection circuit 501 carry signal

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor ▲ Kuwa ▼ Yasuhiro Hara               1006 Kadoma, Kadoma-shi, Osaka Matsushitaden               Instrument industry Co., Ltd. (72) Inventor Tomoko Suetake               1006 Kadoma, Kadoma-shi, Osaka Matsushitaden               Instrument industry Co., Ltd. (72) Inventor Kai               1006 Kadoma, Kadoma-shi, Osaka Matsushitaden               Instrument industry Co., Ltd. (72) Inventor Tsutomu Mikami               1006 Kadoma, Kadoma-shi, Osaka Matsushitaden               Instrument industry Co., Ltd. (72) Inventor Akio Kojima               1006 Kadoma, Kadoma-shi, Osaka Matsushitaden               Instrument industry Co., Ltd.                (56) References JP-A-61-285578 (JP, A)                 JP-A-61-53873 (JP, A)                 JP-A-1-316782 (JP, A)                 JP-A-5-219354 (JP, A)

Claims (8)

(57) [Claims] 1. The strength of a symbol pattern signal is defined as the density of an input image.
In an image forming apparatus and a combining means for combining said input image signal and the modulation means the modulated symbol pattern signal for modulating, said modulating means, said input image signal and the density conversion, the image density depending on the, entering sense is sensitive to the concentration difference between the people
The strength of the symbol pattern is small at the
The strength of the symbol pattern in the shadow area, which is insensitive to
The image forming apparatus is characterized in that the symbol pattern signal is modulated for each pixel so as to be large . 2. The image forming apparatus according to claim 1, wherein the modulation means modulates the symbol pattern signal so as to have a predetermined density difference from the input image signal on a pixel-by-pixel basis. 3. The image forming apparatus according to claim 1, wherein the input image signal is a signal obtained for each pixel. 4. When the synthesizing means exceeds a maximum value of an adder circuit for adding the symbol pattern signal and the input image signal, the magnitude of which is obtained after the synthesizing, is modulated. Selecting the output of a subtraction circuit for performing a subtraction process on the modulated symbol pattern signal and the input image signal, and selecting the output of the addition circuit when the maximum value of the addition circuit is not exceeded. The image forming apparatus according to claim 1. 5. The image forming apparatus according to claim 1, wherein the symbol pattern signal is a signal including a symbol unique to the apparatus. 6. The strength of a symbol pattern signal is defined as the density of an input image.
In an image forming method and a synthesis step of combining modulation step and the modulated symbol pattern signal for modulating a and said input image signal, in the modulation step, the input image signal and the density conversion, the image density Sensitivity to differences in concentration depending on
The strength of the symbol pattern is small in the
The symbol pattern is used in the shadow area where the sense of the density difference is insensitive.
The image forming method is characterized in that the symbol pattern signal is modulated for each pixel so that the intensity of the image becomes large . 7. The modulating step further comprises:
7. The image forming method according to claim 6, wherein the symbol pattern signal is modulated so as to have a predetermined density difference from the input image signal. 8. The image forming method according to claim 6, wherein the input image signal is a signal obtained in pixel units.