JPH09141837A - Printing monitoring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to accurately measure a chromatic density without being adversely affected by the variation of a quantity of light emitted by a stroboscope and detect a delicate change in the chromatic density. SOLUTION: In a printing monitoring device for displaying on a monitor television screen 8 a still image of printed matter 20 photographed by a video camera 1 by emitting light to the printed matter 20 with the help of a stroboscope, the reference value of image data obtained by photographing a reference color using a video camera 1 and the control limit value of a color density are previously stored in a control circuit 7. At the same time, the measuring area of part of printed matter 20 and a color sample 6 are photographed simultaneously, then an error is calculated based on a difference between image data on the color sample 6 obtained by photographing the color sample 6 and the reference value, and the acceptability of the chromatic density of the printed matter 20 is determined by collating a correction value obtained by subtracting the error from the image data on the printed matter 20 with the control limit value.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention displays a moving image of a printed matter moving at high speed as a still image on a monitor television,
Related to a printing monitoring device that checks the print quality of printed matter,
In particular, it relates to detection of defective color density among various print quality defects.

[0002]

2. Description of the Related Art In a printing process such as gravure printing, there are several printing stations. After printing one color at each printing station, a continuous printed matter is wound up in a roll. At this time, since the printed matter is moving at a speed of about 200 m per minute, it is not possible to directly observe and monitor defects such as printing deviation and color density. Therefore, a print monitoring device that irradiates a printed matter moving at a high speed with a stroboscope and displays an image of the printed matter taken by a video camera as a still image on a television monitor to check print quality has been used. The video camera is installed so as to face the printed material immediately before being wound into a roll, and is movable in the width direction of the printed material.

[0003]

In gravure printing, ink density does not change suddenly and ink is continuously printed. Therefore, it is important to detect subtle changes in color as early as possible. is there. The measurement of the color density depends on the external light in many cases, and it is difficult to obtain the absolute value of the color density. For printed matter flowing at high speed, a sample can be created as a still image using a stroboscope, but the light intensity of the stroboscope is not always constant and changes every time it emits light, so data reproducibility cannot be obtained. There's a problem. A method of detecting the light emission amount of the stroboscope by a photo sensor or the like and feeding it back can be considered, but the cost is high.

[0004]

SUMMARY OF THE INVENTION The present invention has a control circuit for controlling and computing signal processing, irradiating a moving printed matter with a stroboscope and shooting a video image of the printed matter as a still image. In a print monitoring device for displaying on a monitor TV, the reference value of image data obtained by shooting a reference color with a video camera and the control limit value of color density are stored in the control circuit in advance, and a color sample is shot by the video camera. It is placed in the field of view, a part of the measurement area of the printed matter and the color sample are photographed at the same time, and the color sample image data obtained by photographing the color sample and the printed matter image data obtained by photographing the printed matter are input to the control circuit. Then, the error is calculated from the difference between the color sample image data and the reference value, and the correction value obtained by subtracting this error from the print image data is compared with the control limit value to check whether the color density of the print is acceptable or not. Characterized a configuration in which a constant. The present invention also provides, in a similar printing monitoring apparatus, a color sample in which a sample of an allowable upper limit density and an allowable lower limit density of each color of a plurality of inks used for printing is displayed, respectively, within a photographing field of view of a video camera. A color sample is placed, a part of the measurement area of the printed matter and the color sample are photographed at the same time, and the density of the image data of the printed matter is between the upper limit density and the lower limit density of the image data of the color sample taken simultaneously. It is characterized in that it is determined whether or not there is a pass or fail.

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a block diagram showing an embodiment of the configuration of a print monitoring apparatus of the present invention. Reference numeral 1 denotes a video camera with a stroboscope, and an output signal of the video camera 1 which has photographed the printed matter 20 to be inspected is converted into digital image data by AD conversion after removing a noise component in the image input circuit 2. After that, it is stored in the frame memory 3. The image output circuit 4 DA-converts the image data read from the frame memory 3 and scan-converts the image data in the progressive system to add the data to the monitor television 5.

When the movement direction of the printed matter 20 is the Y axis and the width direction is the X axis, 8 is a motor for reciprocating the video camera 1 in the X axis direction. The motor 8 is controlled by the pulse supplied from the positioning circuit 10 and driven by the drive circuit 9. Color sample 6 fixed to the video camera 1
Is movable in the X-axis direction together with the video camera 1,
It is placed in the field of view of the video camera 1 so as to be always taken with the printed matter 20. Reference numeral 7 denotes a control circuit that reads out and calculates image data from the frame memory 3 and controls the motor 8. The movement amount and speed of the printed matter 20 in the Y-axis direction are detected by the encoder 11, and the detection signal is supplied to the control circuit 7.

Next, the operation of the print monitoring apparatus according to the present invention will be described. First, the video camera 1 photographs the color sample plate of the reference color several times while irradiating the stroboscope, and the average value of this image data is calculated. Then, the average value is stored in the control circuit 7 in advance as a reference value. R
When the GB output video camera 1 is used, the reference values R _REF , G _REF , and B _REF of the respective color components are stored in the control circuit 7. As a standard color, like white,
A color is used in which the output of each color component of the video camera 1 is at a substantially uniform level. As for the data of the range of allowable color density, that is, the control limit value, the control circuit 7 stores in advance the upper limit value and the lower limit value for each color component for the number of printing inks used.

After completing such preparation work, printed matter 20
To start printing. At the same time, the print monitoring device is operated, and the color sample 6 and the printed matter 20 are simultaneously photographed by the video camera 1 while intermittently irradiating the stroboscope at regular intervals.
As the color sample 6, the same white color as the reference color described above is used. FIG. 2 shows an example of an image on the monitor television 5 at this time. On the right side of the screen, P _O and P ₁ of the image of the printed matter 20
The measurement area with the diagonal line is reflected, and the color sample 6 appears on the left side of the screen.
The measurement area with the diagonal lines P ₂ and P ₃ of the image is shown. The average values of the image data of the pixels in the measurement areas P _O , P ₁ and P ₂ , P ₃ are taken and used as the measurement data of the color density of the printed matter 20 and the color sample 6, respectively. Measurement area P _O , P ₁
As for, a single color portion in the design of the printed matter 20 may be selected, but a register mark provided at the end of the printed matter 20 can also be used. The case where the register mark is used will be described below.

The register mark is used to detect the print position deviation of the print ink of each color, and is provided at a predetermined position for each printed matter 20 as shown in FIG. 3, for example. FIG. 3 shows an example of register marks when the printing ink colors are four colors of black, cyan, magenta, and yellow.
B, C, M, and Y are black, cyan, magenta, and yellow register marks, respectively. The register marks B, C, M, and Y are also printed in their respective colors. The printed matter 20 has a long web shape in which a large number of sheets are continuously connected, and moves at a high speed in the arrow direction during printing. The video camera 1 has B and 2 for the first printed matter 20.
The first sheet is C, the third sheet is M, and the fourth sheet is Y, and the measurement areas P _O and P ₁ of the printed matter 20 are sequentially changed while continuously taking images.

Since each image data obtained by photographing each register mark B, C, M, Y and the color sample 6 with the video camera 1 contains an error due to the variation of the light emission amount of the stroboscope, Is corrected as follows. FIG.
FIG. 7 is an explanatory diagram of a color density measuring operation using the RGB output video camera 1. Although the case where the register mark Y is photographed is shown here, other register marks B,
The same applies to C and M. The image data after passing through the color sample 6 and the image input circuit 2 of the register mark Y, which are simultaneously photographed, are separated into R, G, and B color components and stored in the frame memory 3. That is, the image data of the color sample 6 has the register marks Y as W _R , W _G , and W _B.
The image data of Y is stored in the frame memory 3 as Y _R , Y _G , and Y _B , respectively.

First, the errors R _ERR , G _ERR , and B _ERR of each color component due to variations in the amount of light emitted by the stroboscope are obtained.
As described above, the reference values of the reference colors are R _REF , G _REF , B _REF
Since the measured values of the color sample 6 are W _R , W _G , and W _B , R _ERR = W _R −R _REF G _ERR = W _G −G _REF B _ERR = W _B −B _REF . Therefore, the correction value of the measured color density of the register mark Y (corrected for the error) Y _RA , Y _GA , Y
_{The BA looks} like this: Y _RA = Y _R -R _ERR Y _GA = Y _G -G _ERR Y _BA = Y _B -B _ERR The correction value of each register mark calculated in this way is stored in the control circuit 7 for each color component. The pass / fail of the color density is determined by comparing the upper limit value and the lower limit value.

In the above embodiment, a single color is used for the color sample 6, but by using a color sample table composed of a plurality of ink colors used for the printed matter 20 as the color sample 6, the reference value and The work of pre-storing the data of the control limit value in the control circuit 7 can be omitted. Next, a second embodiment of the print monitoring apparatus configured as described above will be described. FIG. 5 shows a display screen of the monitor television 5 when four colors of black, cyan, magenta and yellow are printed.
On the left half of the screen, the color sample table of each color used for printing is displayed, and on the right half, P _O of the image of the printed matter 20,
A measurement area having a diagonal line P ₁ is displayed. The color sample table shows the maximum allowable density Y ₀ of each of the four colors of yellow Y, magenta M, cyan C and black B,
M ₀ , C ₀ , B ₀ and lower limit densities Y ₁ , M ₁ , C ₁ , B
Composed of ₁ color bar. Register marks B, C, M, and Y may be selected for the measurement area of the printed matter 20 as in the previous example.

As shown in FIG. 6, the printed matter 20 is moved in the direction of the arrow to start printing, and the register mark B of the printed matter 20,
The C, M, Y and the color sample 6 are simultaneously photographed by the video camera 1 while intermittently irradiating the stroboscope at regular intervals. At this time, the first sheet of printed matter 20 is B, the second sheet is C,
The third sheet is M, the fourth sheet is Y, and the measurement areas P _O and P ₁ on the printed matter 20 are different register marks B,
Repeated shooting is performed while sequentially changing to C, M, and Y. The fifth sheet returns to B again, and thereafter this operation is repeated. For the first printout 20, whether the density of the image data of the register mark B is within the upper limit density B ₀ and the lower limit density B ₁ of the measurement data of the color sample 6 taken at the same time. The control circuit 7 determines. Printed matter 2 of 20
Similarly for the second and subsequent sheets, the control circuit 7 determines whether the density of the image data of the register mark is between the upper limit density and the lower limit density of the image data of the color sample 6 that is also captured.

That is, the register marks B, C, M,
Image data obtained by shooting Y is D_B, D_C,
D_M, D_YThen, we check whether the following relation holds.
The control circuit 7 calculates and determines whether the print density is acceptable or not. 1st sheet B₀≧ D_B≧ B₁ Second sheet C₀≧ D_C≧ C₁  3rd sheet M₀≧ D_M≧ M₁ 4th sheet ・ ・ ・ Y₀≧ D_Y≧ Y₁ Take a picture of the register marks B, C, M, Y on the printed matter 20
Obtained image data D_B, D_C, D_M, D_YStrobos
The error due to the variation of the luminescence amount of the co-op is included. Only
Image data B of color sample 6 taken at the same time₀,
B₁, C₀, C₁, M₀, M₁, Y₀, Y₁As well as
Since the error is included, it can be canceled and neglected
Become.

[0015]

According to the present invention, it is possible to obtain a print monitoring apparatus capable of accurately measuring a color density without being affected by fluctuations in the amount of light emitted from a stroboscope, and capable of early detecting a slight change in color density. To be

[Brief description of the drawings]

FIG. 1 is a block diagram showing one embodiment of a configuration of a print monitoring device of the present invention.

FIG. 2 is a diagram showing a monitor television screen in the first embodiment of the present invention.

FIG. 3 is an operation explanatory diagram of the embodiment.

FIG. 4 is an operation conceptual diagram of the embodiment.

FIG. 5 is a diagram showing a monitor television screen in the second embodiment of the present invention.

FIG. 6 is an operation explanatory diagram of the embodiment.

[Explanation of symbols]

 1 ... video camera 6 ... color sample 7 ... control circuit 20 ... printed matter B, C, M, Y ... register mark

Claims (3)

[Claims] 1. A print monitoring apparatus having a control circuit for controlling and calculating signal processing, and irradiating a moving printed matter with a stroboscope to display a video of the printed matter taken by a video camera on a monitor television as a still image. In, in the reference value of the image data obtained by shooting the reference color with a video camera,
The control limit value of the color density is stored in advance in the control circuit, the color sample is placed in the shooting field of view of the video camera, and a part of the measurement area of the printed matter and the color sample are simultaneously shot, and the color sample is shot. The color sample image data obtained and the print image data obtained by photographing the printed matter are input to the control circuit, an error is calculated from the difference between the color sample image data and the reference value, and the error is subtracted from the print image data. A print monitoring apparatus, which determines whether or not the color density of a printed matter is acceptable by comparing the obtained correction value with a control limit value. 2. A print monitoring apparatus for irradiating a moving printed matter with a stroboscope and displaying the image of the printed matter taken by a video camera on a monitor television as a still image. Equipped with a color sample displaying the upper limit density and the lower limit density sample respectively, the color sample is placed in the field of view of the video camera, and a partial measurement area of the printed matter and the color sample are photographed at the same time. A print monitoring apparatus, which determines whether or not the density of the image data of the captured image data is between the upper limit density and the lower limit density of the image data of the color sample captured at the same time to determine whether the result is acceptable. 3. The print monitoring apparatus according to claim 1, wherein a part of the measurement area of the printed matter is a register mark provided on the printed matter.