JPH0757006B2 - Automatic setting method of gradation conversion table - Google Patents

Description

The present invention relates to an image which is subjected to color correction processing of an image signal of an original (original image) read by an input unit, gradation conversion is performed using a gradation conversion table, and then exposure output to a film or the like. The present invention relates to a method of automatically setting a gradation conversion table in a scanning recording device.

For example, a density histogram (or a cumulative density histogram) is obtained in advance for a plurality of standard prints by an offline document classifier, the density histogram is patterned to form some standard patterns, and a color scanner corresponding to these patterns is formed. There is a method of setting a tone curve setting value and visually determining which standard pattern the density histogram pattern of the original is close to and setting the tone curve (for example, JP-A-58-5744). However, in this conventional tone curve setting method, there is a preparatory work such as dividing each standard pattern into some standard patterns in advance, and how to set the shape of the standard pattern, and associating each pattern with the tone curve setting value. However, there are drawbacks in that the user's burden is heavy and that the printed matter having a satisfactory image quality cannot be obtained unless the preparation work is properly performed. This means that the user has to determine the shape of the standard pattern and determine which standard pattern the pattern of the density histogram of each document is similar to. This is because it requires considerable know-how and skill. Further, since the machine is offline, it is necessary to set the tone curve knob of the scanner to a predetermined value for each document after selecting the tone curve. In many cases, a part of the original is trimmed and reproduced, but there is a drawback that it is not possible to obtain a density histogram of only a necessary part of the original.

Therefore, an object of the present invention is to eliminate such a conventional drawback, and to set a gradation conversion table for obtaining a high-quality output (hard copy or halftone for printing) with an extremely simple input operation. It is to provide an online setting method for automatically performing.

The present invention will be described below.

The present invention is an automatic gradation conversion table for an image scanning recording apparatus that performs color correction processing on an image signal of a document read by an input unit, performs gradation conversion using a gradation conversion table, and then exposes and outputs to a film or the like. Regarding the setting method, after correcting a plurality of standard tone curve data so as to pass the color separation signal values related to the highlight point and the shadow point of the document to be introduced, the corrected plurality of tone curve data are used. A plurality of output signals calculated for the color separation signals of the portion to be inspected of the document to be introduced, respectively, the sum of the deviation from the desired output signal of the portion to be inspected to be introduced is calculated, One of the corrected tone curve data that minimizes the sum is set as the gradation conversion table.

That is, according to the present invention, as shown in FIG. 1, a plurality of standard tone curve data g ₁ (X) to g _n (X) are prepared in the memory, and all of these standard tone curve data are designated high level. Modify so that it passes through Light Point HP and Shadow Point SP. This correction operation will be described with reference to FIG. 2. For example, standard tone curve data g _i (X)
Assuming that Xho and Xso are highlight points of, the corrected tone curve data g _i ′ (X) = g _i (aX + b) must satisfy the following expression (1).

From this equation (1) Therefore, if we solve for the coefficients a and b, Becomes In this way, the tone curve data g _i ′ (X) = g _i (a · X + b) modified so as to pass through the specified highlight point HP and shadow point SP can be obtained.

As described above, the tone curve data g _i ′ corrected so as to pass through the specified highlight point HP and shadow point SP from the standard tone curve data g _i (X)
When (X) is calculated, this tone curve data is next
Output signal Yj = g _i corresponding to Xyj when g _i ′ (X) is used
The sum Δi of the deviation between (a · Xyj + b) and the desired output signal Yyjd is obtained. That is, Is calculated from i = 1 to k, and tone curve data g _i ′ (X) = g _i (a · X + b) (5) when the sum of deviations Δ _i is minimum is obtained, and this tone is calculated. The curve data g _i ′ (X) is stored as a gradation conversion table.

The state of the above-described arithmetic processing is shown in detail in the flowchart of FIG. 3. Next, an example of an apparatus that realizes this processing method will be described.

In the image recording apparatus shown in FIG. 4, the original 2 is set on the input drum 1, and the color separation signals Xyh, Xys at highlight points and shadow points of the original 2 and the color separation signals of several portions to be inspected (for example, high Xyj is read by the input optical system at the light portion, shadow portion, and intermediate portion), converted into a digital signal by the AD converter 3, and input to the arithmetic unit 4. At the same time, a desired output signal (Yyjd) 5 corresponding to the portion to be inspected is input to the arithmetic unit 4, and the arithmetic unit 4 outputs color separation signals of highlight points and shadow points,
From the set of color separation signals of the portion to be inspected and the corresponding set of desired output signals, the correction process g _i ′ as described above is performed.
Calculating the most appropriate tone curve data g _i '(X) calculated by the summation delta _i of (X) and deviations, set and stored in the gradation conversion table 6 in the signal processing unit. After this,
The image signal of the original 2 mounted on the input drum 1 is read by the optical system, converted into a digital amount by the AD converter 3, and then input to the color correction processing unit 7 for color correction, and the corrected image signal Is input to the gradation conversion table 6, the gradation is converted according to the gradation conversion table 6 which has already been set as described above, and the exposure is output by the exposure unit 8.

Further, in the image recording apparatus shown in FIG. 5, the original 2 is scanned in advance at a rough sampling pitch (rough scan), the rough scan data 9 is stored in the storage medium in the arithmetic unit 4, and a coordinate input device such as a digitizer. By manuscript 2
The coordinates 10 of the highlight points, shadow points, and several points to be inspected are input to the arithmetic unit 4A, and a desired set of output signals (Xy
jd) Enter 5 as well. Then, the calculation unit 4A calculates color separation signals Xyh, Xys of highlight points and shadow points from the coordinate input 10 and rough scan data 9 and a set Xyj of color separation signals of several portions to be inspected, The most appropriate tone curve data is calculated from the corresponding desired output signal set (Xyjd) 5 and the obtained tone curve data g _i ′ (X) is stored in the gradation conversion table 6 and set. . After that, the original 2 is read by the input optical system, color-corrected by the color correction processing unit 7, gradation-converted by the gradation conversion table 6, and exposed by the exposure unit 8.

On the other hand, in the image recording apparatus shown in FIG. 6, the calculation unit 4B automatically calculates the color separation signals Xyh, Xys of the highlight point and the shadow point and the set Xyj of the color separation signals to be inspected from the rough scan data 9. Then, a set of desired output signals (Xyj
d) The calculation section 4B for the tone curve data so that it is close to 5
The optimum tone curve data g calculated by
_i (X) is stored in the gradation conversion table 6 and set.
Also in this case, the original 2 mounted on the input drum 1 is read by the input optical system, color-corrected by the color correction processing unit 7, gradation-converted by the gradation conversion table 6, and then the exposure unit 8 is used. It is exposed and output.

Here, an example of automatically calculating the color separation signals Xyh and Xys of the highlight point and the shadow point from the rough scan data 9 will be described.

A cumulative histogram of signals is calculated from the rough scan data 9. For example, a signal corresponding to 1% of the histogram is a highlight signal and a signal corresponding to 99% of the histogram is a shadow signal. As a set of color separation signals to be inspected from the rough scan data 9, for example, a set of signals corresponding to 20%, 50%, 80% of the cumulative histogram of signals is used. Then, the set of these signals is considered to be the highlight part, the intermediate part, and the shadow part of the document, and the gradation conversion data may be calculated so that these become a set of predetermined output signals.
Further, for a manuscript mainly composed of a person, a cumulative histogram of a skin color portion may be used.

In the image recording apparatus described above, the desired output signal 5 may be fixed and a constant numerical value may be always input to the arithmetic units 4 and 4A unless otherwise specified. It is also possible to calculate the tone curve data by interpolating from the set of standard tone curve data so that it passes through all points on the XY plane including highlight points and shadow points. Examples of such methods include linear interpolation, Lagrange interpolation, and B-spline interpolation. In the above description, one is selected from the set of standard tone curve data, but the standard tone curve data may be stored as a functional expression.

As described above, according to the setting method of the present invention, it is possible to automatically set the gradation conversion table, and even an unskilled person can easily and quickly set the gradation conversion table. .

[Brief description of drawings]

1 and 2 are views for explaining the operation of the method of the present invention, and FIG. 3 is a flow chart showing a processing example of the method of the present invention.
4 to 6 are block diagrams showing an example of an image recording apparatus to which the method of the present invention can be applied. 1 ... Input drum, 2 ... Original, 3 ... AD converter, 4, 4
A, 4B: arithmetic unit (computer), 5: desired output signal, 6: gradation conversion table, 7: color correction processing unit, 8
…… Exposure area, 9 …… Rough scan data of original, 10 ……
Coordinates of highlight point, shadow point and the part to be inspected.

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Claims (6)

[Claims] 1. An image scanning recording apparatus which performs color correction processing on an image signal of an original read by an input unit, performs gradation conversion using a gradation conversion table, and then exposes and outputs a plurality of standard tone curve data. After correction so that the color separation signal values related to the highlight point and shadow point of the document to be introduced are passed, the colors of the portion to be inspected of the document to be introduced are corrected by using the corrected plurality of tone curve data. Corrected tone curve data such that the sum of the deviations of the plurality of output signals calculated for the decomposed signals from the desired output signal of the introduced portion to be inspected is calculated, and the sum is minimized. One of the above is set as the gradation conversion table, which is an automatic setting method of the gradation conversion table. 2. At least one of a color separation signal relating to the highlight point and the shadow point and a color separation signal of the portion to be inspected is introduced from an image signal of a document read by the input section. An automatic setting method of a gradation conversion table according to claim 1. 3. The coordinate data of the highlight point, the shadow point, and the portion of the document to be inspected, which has been input by a coordinate input device in advance, and a rough scan obtained by optically scanning the document at a coarse sampling pitch. The gradation according to claim 1, wherein at least one of a color separation signal related to the highlight point and the shadow point and a color separation signal of the portion to be inspected is introduced based on the data. Automatic conversion table setting method. 4. A cumulative histogram is created from rough scan data obtained by optically scanning the document at a coarse sampling pitch in advance, and the density signals corresponding to respective arbitrarily defined ratios to the cumulative histogram are highlighted. The gradation conversion table according to claim 1, wherein at least one of the color separation signals related to the point and the shadow point and the color separation signal of the portion to be inspected is introduced. Automatic setting method. 5. The automatic gradation table setting method according to claim 4, wherein when the design of the document is a person, the cumulative histogram is created for the skin color portion. 6. The method according to claim 1, wherein a constant value is always introduced as a desired output signal of the portion to be inspected.
An automatic setting method of the gradation conversion table described in the item.