JP4083823B2 - Image processing device - Google Patents

Description

上記式において、ｎ ：指示点の数
ｙ_i ：ｉ番目の指示点のハイライト濃度修正前のｙの網％データ
ｙ_i0 ：ｉ番目の指示点のＹの目標網％データ
ｗ_i ：ｉ番目の指示点の重み付け係数
ｙ_ia ：ｉ番目の指示点のハイライト濃度修正後のｙの網％データ
ｒ_iy ：ｉ番目の指示点のハイライト濃度修正前のｙの指標
ｒ_iya ：ｉ番目の指示点のハイライト濃度修正後のｙの指標
【００３９】
なお、上記式において、重み付け係数ｗは、オペレータによって設定された支持点の色相が異なる場合に、その偏差を修正するためのものであり、この偏差を無くすように自動設定される。
【００４０】
次いで、上記式（２）および（３）で得られた評価関数ｆｙおよびｆ５ｙａを比較し、網％の評価を行う。
ここで、ｆｙ＞ｆｙａであれば、指示点のＹの網％データが目標網％データに近付いているので、ハイライト濃度の修正が正当であると判定し、このセットアップパラメータを新たにパラメータ記憶部３８に記憶してＳ３〜Ｓ５の操作を行い、逆に、ｆｙ＜ｆｙａであれば、指示点のＹの網％データが目標網％データから離れてしまっているので、ハイライト濃度の修正が大きすぎたと判定し、修正量を、例えば１／２に変更してＳ３〜Ｓ５の操作を行う。
【００４１】
同様にして、ＭおよびＣについても、前記評価関数ｆ_y およびｆ_yaと同様の方法を用い、ハイライト濃度の判定および修正を行う。
このようなＳ３からＳ５に至るハイライト濃度の修正操作を繰り返し行い、Ｃ、ＭおよびＹがすべて目標網％データとなった時点で、ハイライト濃度に対するセットアップパラメータの設定を終了する。
【００４２】
他方、Ｂモードが選択された場合には、指示点の画像情報のみを用い、例えば、以下のようにして画像処理条件を決定する。
まず、設定された指示点のうち、最小濃度を有するものを検出し、この点の濃度を指示点濃度ａ₂とする。
この方法においては、指示点濃度ａ₂を初期ハイライト濃度として『ハイライトを美しく』に対応する理想の網％バランス（Ｃ、ＭおよびＹ空間の一点）、および理想の網％データをグラデーションLUT記憶回路４０から読み出し、指定点のうち最も濃度の低い部分は前記理想の網％バランスとし、これ以外の指定点は、理想の網％データを目標として、指定点がこの理想の網％データとなるように、前述のように画像処理条件を決定する。
【００４３】
このような本発明の画像処理装置を用いることにより、オペレータの技量や画像に応じて、ハイライト仕上り情報の指示方法を選択してハイライトを美しくする画像処理条件を設定することができ、経験の浅いオペレータであってもハイライトの美しい高画質な画像を得ることが可能であり、また、経験の豊富な高い技量を有するオペレータであれば、よりハイライトの美しい高画質な画像を得ることができる。
すなわち、指示点を設定しないモードを選択することにより、ハイライトを正確に検出できない、全く経験のないオペレータが操作を行う場合であっても、装置がハイライト領域を検出して、画像処理条件を設定するので、ハイライトの美しい高画質な画像を得ることができ、さらに、指定点を設定する必要がないので、作業も極めて単純かつ容易である。また、Ａモードを選択することにより、経験の浅いオペレータやハイライトの検出が困難な際に、オペレータがハイライトを間違えて設定しても、プレスキャンの画像情報によってこれを補償して画像条件を設定することができるので、ハイライトの美しい高画質な画像を得ることができる。
さらに、ハイライトの設定を正確に行うことができる熟練したオペレータや、ハイライトが明らかな画像の場合には、Ｂモードを選択することにより、原稿にゴミが付着したり、画像が素抜けを有する場合であっても、これによる悪影響を一切排除して画像処理条件を設定できるので、よりハイライトの美しい高画質な画像を得ることができる。
なお、本発明の画像処理装置においては、仕上がり指示は複数を選択可能であるのは前述のとおりであり、その場合には、他の仕上がり指示に対応する理想の網％データも加味して画像処理条件が設定される。
【００４４】
このようにして画像処理条件（セットアップパラメータ）を設定した後、図２に示されるように本スキャンを行い、図３に示される様に、設定された画像処理条件に応じてグラデーション処理やカラーコレクション処理等を行うことにより、仕上り情報の指示に応じた高画質な出力画像、特に、ハイライトの美しい画像を安定して形成することができる。
【００４５】
以上、本発明の画像処理装置について詳細に説明したが、本発明は上記実施例に限定はされず、本発明の要旨を逸脱しない範囲において、各種の改良および変更を行ってもよいのはもちろんである。
【００４６】
【発明の効果】
以上、詳細に説明したように、本発明の画像処理装置によれば、画像またはオペレータの技量に応じて選択されるＡモードおよびＢモードのいずれかを選択する手段を有し、画像やオペレータの技量等に応じてハイライトに関する仕上り情報の指示を選択することができ、容易にハイライトの美しい画像を安定して作成することができ、また、熟練したオペレータであれば、モード選択によってＢモードを選択し、プレスキャンで得られた画像情報の悪影響を一切排除して、極めてハイライトの美しい高画質な画像を得ることができる。
【図面の簡単な説明】
【図１】本発明の画像処理装置を利用する画像読取再生システムの構成ブロック図である。
【図２】図１に示される画像読取再生システムの作用を説明するためのフローチャートである。
【図３】図１に示される画像読取再生システムにおける画像情報処理を説明するためのフローチャートである。
【図４】図１に示される画像読取再生システムにおけるディスプレイ表示の一例を示す概念図である。
【図５】仕上り指示『ハイライトを美しく』、『グレイに揃える』、『シャドーを美しく』に対応する理想の網％データの一例を示すグラフである。
【符号の説明】
１０ （画像読取再生）システム
１２ 反射原稿スキャナ
１４ 透過原稿スキャナ
１６ ワークステーション
１８ 記録装置
２０ ＣＰＵ
２２ 画像読取部
２６ 前処理回路
２８ 画像処理回路
３０ バス
３２ 画像バッファ
３４ 色変換 LUT記憶部
３６ 画像処理条件修正回路
３８ パラメータ記憶部
４０ グラデーションLUT 記憶回路
４２ ビデオバッファ
４４ 制御部
４６ ディスプレイ
４８ キーボード
５０ マウス[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image processing apparatus for processing photoelectrically read image information to obtain a desired output image. Specifically, the present invention relates to an image processing apparatus that can output an image with a beautiful highlight.
[0002]
[Prior art]
For example, in the field of printing and plate making, for the purpose of rationalizing work processes and improving image quality, the original image is read photoelectrically, the read image information is processed electrically, and the film is processed according to the processed image information. 2. Description of the Related Art Image reading and reproducing systems that make a film plate by scanning and exposing a photosensitive material are widely used.
[0003]
Such an image reading / reproducing system basically includes a reading device that photoelectrically reads a document image, an image processing device that processes image information, and a recording device that outputs an image.
Among these, in the image processing apparatus, pre-scanning is performed to read a document image before reading for image recording, and reading conditions such as a magnification and a trimming range are set. Output image finish information according to the output image, for example, output image finish information such as “Beautiful highlights”, “Beautiful skin”, “Beautiful sky”, “Beautiful green”, etc., and set image processing conditions Thereafter, reading for obtaining an output image, that is, main scanning is performed (refer to Japanese Patent Laid-Open Nos. 4-111575 and 6-291998).
[0004]
That is, in the image reading / reproducing system, first, pre-scanning is performed, image processing conditions are set from the image information (image characteristic value) obtained by the pre-scanning and the finish information instruction, and then the main scanning is performed. The image information obtained in the main scan is processed in accordance with the image processing conditions set in the above, and the film photosensitive material is exposed in accordance with the processed image information to obtain an output image.
[0005]
[Problems to be solved by the invention]
By the way, highlight (the brightest part) can be cited as one of factors that greatly affect the image quality of the output image regardless of the pattern. In particular, in the case of printed materials, highlights are often very important for obtaining high-quality images.
As described above, the image processing apparatus has means for instructing the finish information of the output image, and usually includes highlight finish information for beautifully finishing the highlight.
[0006]
In the conventional image processing apparatus, when highlight finish information is instructed (other instructions are usually the same), two operation methods can be selected as the processing method.
[0007]
One is a method in which the operator designates a highlight location in an image, that is, sets a designated point. In a normal image reading / reproducing system, when pre-scanning is performed, the read image is displayed on a display such as a CRT. The operator looks at this image, selects which part of the image is highlighted, and designates it with the mouse or the like. In this case, the image processing condition is set using the image information of the designated point and the density distribution data obtained by the prescan.
The other is a method in which a designated point is not set. In this case, the apparatus discriminates the highlight area from the image information obtained by the pre-scan, and the image information of the discriminated highlight area is obtained by the pre-scan. Image processing conditions relating to highlighting are set using the obtained density distribution data.
In other words, the method that does not set the designated point is a method that makes it possible to obtain a good image even by an inexperienced operator who cannot accurately determine where to highlight, and on the other hand, the designated point. Is a method that allows an operator with some experience to make adjustments to obtain a higher quality image.
[0008]
Here, in the method of setting the designated point, the image processing condition is set by referring not only to the image information of the designated point but also to image information obtained by pre-scanning, more specifically, a density distribution (density histogram). Thus, even when the operator mistakenly designates the highlight, the image processing condition can be set satisfactorily.
However, the density histogram obtained by the pre-scan includes image information such as dust attached to the document and image defects such as white spots in the document. Therefore, in the conventional apparatus, when the operator correctly designates highlights, the image information obtained by the pre-scan may adversely affect the image processing conditions.
[0009]
An object of the present invention is to solve the above-mentioned problems of the prior art, and it is possible to select an instruction of finishing information related to highlights according to the image, operator skill, etc., and to stabilize a beautiful image of highlights. It is an object of the present invention to provide an image processing apparatus that can be created.
[0010]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention performs output processing on image information obtained by photoelectrically reading a document image according to image processing conditions set in accordance with an instruction of finishing information. An image processing apparatus for obtaining an image reading unit that photoelectrically reads an original image by pre-scanning or main scanning, display means for displaying the original image, and highlight finish of an output image obtained from the image information And an instruction to set the highlight reference area as an instruction point in the pre-scan image of the original document image displayed on the display means when the finish content of the highlight is determined Point setting means, means for selecting necessity / unnecessity of indication point setting by the indication point setting means when determining the finish content of the highlight, and the finger When the set point, and means for selecting one of A and B modes, the A mode,Of the indicated pointImage density obtained from image informationAnd an image density which is a highlight density obtained using image density obtained from image information other than the image information of the indicated point,Adjust according to the finish of the highlightdo itcan getIt was adjustedAn image processing mode in which highlight density is set and image processing conditions are set, and the B mode is a mode in which highlight density is determined only from image information at an indicated point and image processing conditions are set. A device is provided.
[0011]
[Effects of the Invention]
  The image processing apparatus of the present invention automatically sets processing conditions for image information (auto-setup) based on image information (image characteristic values) obtained by pre-scanning and finish information instructions in accordance with a target output image. In addition to the configuration in which the method for setting the indication point and the method for not setting the selection of the highlight finish information can be selected as in the prior art, in the case of setting the indication point,A mode in which highlight density is determined using image information other than the designated point and image processing conditions are set, and a B mode in which highlight density is determined only from image information at the designated point and image processing conditions are set. Or according to operator skillIt has a selectable configuration.
[0012]
  Therefore, according to the image processing apparatus of the present invention, it is possible to set image processing conditions using optimal image information according to the skill of the operator and the image (for example, when the highlight is clear),By selecting the A mode, even if the operator sets the wrong highlight, the image condition can be set by compensating for this by image information other than the designated point.Inexperienced operatorAnd highlights are difficult to detectEven so, it is possible to obtain high-quality images,By selecting B mode,Experienced and highly skilled operatorsAnd images with clear highlightsIf,Even if dust adheres to the original or the image has a burrow,It is possible to obtain high-quality images with more beautiful highlights.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the image processing apparatus of the present invention will be described in detail based on preferred embodiments shown in the accompanying drawings.
FIG. 1 is a block diagram showing the configuration of an image reading / reproducing system using the image processing apparatus of the present invention.
This image reading / reproducing system 10 (hereinafter, referred to as system 10) photoelectrically divides an image carried on a transparent original or a reflective original into three primary colors R (red), G (green), and B (blue). Then, the obtained electrical signal is processed as an image signal, and this is subjected to image processing, and the film photosensitive material is exposed according to the obtained image information to obtain C (cyan) plate, M (magenta) plate, Y (yellow). A plate or three or four black (K) plates are formed and output.
[0014]
The system 10 basically includes a reflective original scanner 12 that photoelectrically reads an image of a reflective original such as a printed matter or a photograph, and an image of a transparent original such as a reversal film, and also controls the reflective original scanner 12. In addition, the obtained electrical signal is used as an image signal, and the transparent original scanner 14 that outputs the processed image by performing predetermined image processing, the transparent original scanner 14, and the like, and the image (pre-scan image) read by the transparent original scanner 14 are operated. ) And a recording device 18 that scans and exposes a film photosensitive material and outputs a film plate in accordance with image information output from the transparent original scanner 14.
[0015]
The reflection document scanner 12 is a known image reading device that photoelectrically reads an image of a reflection document, and includes, for example, a light source extending in one direction, a slit extending in the same direction, and a reflection document. By scanning relatively in a direction orthogonal to the direction in which the slits extend, reflected light that carries the image of the document is obtained, and this is formed on a line sensor such as a CCD sensor corresponding to each of R, G, and B. Are read photoelectrically and output to the transparent original scanner 14.
[0016]
The transparent original scanner 14 includes an image reading unit 22, a preprocessing circuit 26, and an image processing circuit 28. These and the reflection original scanner 12 are connected to each other by a bus 30.
[0017]
The image reading unit 22 is a known image reading device that photoelectrically reads an image of a transparent original by slit scanning or surface exposure. For example, the image reading unit 22 supports an image of a transparent original by slit scanning similar to the reflection original scanner 12 described above. Transmitted light is obtained, imaged on a line sensor such as a CCD sensor corresponding to each of R, G, and B, read, and output.
[0018]
The preprocessing circuit 26 performs preprocessing before image processing is performed on the image information output from the reflective original scanner 12 or the image reading unit 22.
The preprocessing circuit 26 is connected to an image buffer 32 for temporarily recording image information and a color conversion LUT storage unit 34 for performing predetermined color conversion.
[0019]
  The image processing circuit 28 performs predetermined image processing according to preset image processing conditions, and outputs the processed image information to the recording device 18 as output image information.
  The image processing circuit 28 is connected to an image processing condition correction circuit 36 for correcting the image processing conditions (image processing condition setting = auto setup). Further, the image processing condition correction circuit 36 includes the image processing conditions and the image processing conditions. A parameter storage unit 38 for storing setup parameters, and a gradation LUT storage for storing a gradation curve (tone curve) as a reference for gradation processing, ideal half-net data corresponding to an instruction of finishing information, and the like as a lookup tablecircuit40 is connected.
[0020]
A workstation 16 is further connected to the bus 30 described above.
The workstation 16 includes a CPU 20 that performs overall control, a video buffer 42, and a control unit 44. The control unit 44 controls output to a display 46 connected to the workstation 16, and also includes a keyboard 48 and a mouse. Process 50 input data.
In this workstation 16, finish information is instructed, magnification and trimming range are set, and the like.
[0021]
The recording device 18 is a printer that uses light beam scanning exposure. For example, the recording device 18 scans and exposes a film photosensitive material with a light beam modulated in accordance with image information from the image processing circuit 28, performs development processing, and outputs. As an image, C, M and Y, or even K film plates are output.
[0022]
The system 10 basically has the above-described configuration, and FIG. 2 shows a flow of film plate creation by the system 10.
First, when an original is set at a predetermined position of the image reading unit 22 (reflective original scanner 12), a pre-scan is performed to read an image of the original roughly. The image information of the document read by the prescan is subjected to a predetermined process such as logarithmic conversion by the preprocessing circuit 26, stored in the image buffer 32, and sent to the workstation 16, and the image is displayed on the display 46. Is displayed.
The operator looks at the display 46 and uses the keyboard 48 and mouse 50 to set necessary reading (output) conditions such as a magnification and a trimming range, and to give finishing information. When these operations are completed, the image processing condition correction circuit 36 sets image processing conditions in accordance with the image information and finish information instructions obtained by the pre-scan. The finish information instruction and the image processing condition setting will be described in detail later.
[0023]
When the image processing conditions are set, image reading (main scan) for forming a film plate is performed, and image processing according to the image processing conditions previously set in the obtained image information is performed by the image processing circuit 28. And an image (film version) is output by the recording device 18.
[0024]
The flow from this scan to image output is shown in FIG.
When the start of the main scan is instructed, the image reading unit 22 (reflective document scanner 12) performs slit scanning of the document, and transmitted light (or reflected light) carrying the document image is R, G, and B primary colors. And is read by a CCD sensor or the like, photoelectrically converted and output as image information, and sent to the preprocessing circuit 26.
In the preprocessing circuit 26, under the action of the CPU 20, predetermined processing such as A / D conversion and logarithmic conversion is performed to perform density conversion, and image information of C, M, and Y density is generated. Accumulated in the image buffer 32. Next, in the preprocessing circuit 26, predetermined C, M, and Y image information is stored in the color conversion LUT storage unit 34 based on a color conversion lookup table set in accordance with the color density of the image. Color conversion processing is performed to obtain C, M, and Y density image information.
[0025]
This image information is then sent to the image processing circuit 28.
In the image processing circuit 28, reference values in which the highlight density and shadow density of the C, M, and Y image information are set in advance in accordance with the image processing conditions previously set from the prescan and the finish information instruction. The picture adjustment process is adjusted, and gradation processing, color correction processing, UCR (Under Color Removal), sharpness enhancement, and other processing are performed to make the image information of halftone data before recording. It is output to the device 18.
[0026]
The recording device 18 performs a so-called halftone process in which a light beam is modulated in accordance with the image information of the halftone data output from the image processing circuit 28, and the film photosensitive material is scanned and exposed to form a halftone image. Then, development processing is performed, and a film plate on which a halftone image is formed is output.
[0027]
Next, the finish information instruction and the setting of the image processing conditions, which were mentioned in the description of the film plate creation using the flowchart of FIG. 2, will be described.
As described above, the image processing conditions are set based on an instruction of image information and finishing information of a document image obtained by prescanning. The image information of the original image obtained by the prescan is processed in the preprocessing circuit 26 in substantially the same manner as the image information of the main scan, stored in the image buffer 32, the image characteristic value is calculated, and the image is It is displayed on the display 46.
As the image characteristic value, the number of pixels at an arbitrary density in the density histogram obtained by the pre-scan, the average density or the maximum density and the minimum density for each area divided by the whole or the screen (for example, 1/2, 1/4, etc.), The average density and the maximum density for each of C, M and Y (or R, G and B) are exemplified, and one or more are used.
[0028]
In parallel with the calculation of the image characteristic value, in order to create a film plate according to the purpose (that is, to obtain a predetermined printed matter), the operator gives instructions for finishing information. Image processing conditions are set from the finish information instruction), and the above-described gradation processing, color correction processing, UCR, sharpness enhancement, and the like are performed according to the image processing conditions.
Note that the finish information instruction is not necessarily performed, and in this case, the image processing condition is set only from the image characteristic value.
[0029]
When pre-scanning is performed, as shown in FIG. 4, finishing information is displayed on the display 46 together with the document image.
For example, the finish information is divided into a brightness instruction and a finish instruction. In the illustrated apparatus, the brightness instruction is “bright”, “slightly bright”, “dark”, “slightly dark”, and “same as original”. ”Is displayed, and any one of them can be instructed. On the other hand, in the finishing instruction,“ A: Skin / Gray ”,“ B: Highlight ”,“ C: Shadow ”,“ D ” : "Empty" and "E: Green" are displayed, and one or more can be designated, and the operator designates this with the mouse 50 or the keyboard 48 according to the pattern.
Furthermore, if necessary, select “pointing point setting” and set one or a plurality of pointing points with the mouse 50 or the like to make which position (area) be beautiful (where the finishing instruction is Can be instructed.
[0030]
  In the system 10 of the illustrated example, the color balance of C, M, and Y for realizing each color (skin, gray, sky, green, highlight, shadow) at various densities corresponding to each finishing instruction. Corresponding ideal mesh% data (C, M and Y space curves) and highlight and shadow ideal mesh% balance (one point in C, M and Y space) are stored in gradation LUTcircuit40, and the halftone data of the film plate to be output is an ideal halftone data in which C, M, and Y are aligned with a predetermined color balance and highlight / shadow balance with respect to the specified finish information. Image processing conditions are set so as to be data.
  Here, in the system 10 using the image processing apparatus of the present invention, the finish instruction and the image processing conditions in “A: Skin / Gray”, “C: Shadow”, “D: Sky”, and “E: Green” are set. The setting is the same as in the prior art, and is performed by known methods disclosed in the above-mentioned Japanese Patent Laid-Open Nos. 4-111575 and 6-291998.
  On the other hand, the finish instruction of “B: Highlight” and the setting of the image processing conditions are performed as follows.
[0031]
In the system 10 using the image processing apparatus of the present invention, when “B: Highlight” is selected as the finishing instruction, first, the presence or absence of setting of the indicated point is selected by the mouse 50 or the like (this point is different from the other). When the designated point is set, the A mode or the B mode is further selected as shown in FIG.
Here, the A mode is a mode in which image processing conditions are set from the image information of the designated point and the image information obtained by the pre-scan, and the B mode is set from only the image information of the designated point. It is a mode to do.
[0032]
First, when the indication point is not set, a highlight area is detected from pre-scan image information, and the highlight density is determined from the density of this area and the pre-scan image information, and image processing conditions are set. Image processing conditions are set in a similar manner.
More specifically, first, a low density region (for example, a density of 0.4 or less, etc.) in the image is searched from the prescan image information. To detect. Further, a portion where the density is too low or less than a predetermined value in the detected area is likely to be a missing image (base density), and is therefore deleted as a highlight area. The highlight area detection method is not limited to this method, and various known methods can be used.
In this way, the highlight area is detected, and the highlight density is determined using the density. As an example of the highlight density determination method, a method of calculating by the following formula using the density of the highlight area as c and the minimum density of the pre-scan image information (minimum data of density histogram) as b is exemplified.
c × Wa + b × Wb = highlight density
In the above equation, Wa is the probability that there is a highlight, and Wb is the probability that there is no highlight, and “Wa + Wb = 1”.
In this way, the highlight density is determined.
Note that the above-described image characteristic value is a parameter for calculating an initial value of image processing condition setting. This point will be described in detail in JP-A-6-291998.
[0033]
On the other hand, when “pointing point setting” is selected and one or a plurality of pointing points to be highlighted are set with the mouse 50 or the like, the A mode or the B mode is selected as described above.
When the A mode is selected, the image processing conditions are set by a method similar to the conventional method in which the highlight density is determined from the image information of the designated point and the pre-scan image information to set the image processing conditions. The following method is illustrated as an example.
First, the average value of the image density of the designated point is calculated, and this is calculated as the designated point density a.₁And
This indicated point concentration a₁Then, the initial highlight density is calculated by the following equation using the minimum density b of the prescan image information described above.
a₁× Wa + b × Wb = initial highlight density
In this way, the initial highlight density is determined.
Using the initial highlight density thus determined as an initial setup parameter, each halftone dot data is calculated from the density data of C, M, and Y at the designated point (S1).
[0034]
  On the other hand, the image processing condition correction circuit 36 stores the ideal halftone data corresponding to the designated “beautiful highlight” in the gradation LUT.circuitThe point on the ideal network% data closest to the network% data at the indicated point, that is, the target network% data is calculated (S2).
  Here, the network% data that corresponds in common to “Beautiful highlights”, “Align in gray”, and “Beautiful shadows” is the point h in FIG.₁ Is defined as data on the curve β connecting ~ h.
  That is, the halftone data corresponding to the C, M, and Y densities of the i-th indicating point is c_i, M_iAnd y_iThe point on the ideal network% data closest to this is (c_j, M_j, Y_j), The index r shown by the following formula (1)_iIs the target network% data, so that c_j, M_jAnd y_jBecomes the target net% data.
  r_i ²= (C_i-C_j)²+ (M_i-M_j)²+ (Y_i-Y_j)²...... (1)
      c_i, M_i, Y_i: Net% data of i-th indication point
      c_j, M_j, Y_j: Ideal network% data
[0035]
Such an operation (S1 to S2) is performed on each indication point, and the net% data and the target net% data of the obtained indication point are averaged and averaged for each of C, M, and Y. Find the dot% data and the target dot% data.
Next, the size of both halftone data is compared. For example, if the average value of Y halftone data at the indicated point is smaller than the average value of the target halftone data, the Y highlight density is decreased by a certain amount, In the opposite case, the correction is increased. That is, the setup parameter is corrected.
The same operation is performed for C and M, and the corrected setup parameter is stored in the parameter storage unit 38 (S3).
[0036]
Next, using the corrected set-up parameter, the dot percentage data is calculated again in the same manner as in S1 (S4).
[0037]
Subsequently, the image processing condition correction circuit 36 evaluates the halftone data obtained using the corrected setup parameter (S5).
That is, for example, if Y, the evaluation function indicating how far the Y dot% data at the designated point before the highlight density is changed from the target dot% data as a whole is f._yAnd the same evaluation function after changing the highlight density is f_yaThen, each evaluation function is represented by the following formulas (2) and (3).
[0038]
[Expression 1]

In the above formula, n: number of indicating points
y_i  : Y dot% data before correction of highlight density at i-th indication point
y_i0  : Y target net% data of i-th indication point
w_i  : Weighting coefficient of i-th indication point
y_ia  : Y dot% data after correcting the highlight density at the i-th indication point
r_iy  : Index of y before correction of highlight density at i-th indication point
r_iya: Index of y after correction of highlight density at i-th indication point
[0039]
In the above equation, the weighting coefficient w is for correcting the deviation when the hue of the support point set by the operator is different, and is automatically set so as to eliminate this deviation.
[0040]
Next, the evaluation functions fy and f5ya obtained by the above formulas (2) and (3) are compared, and the net% is evaluated.Do.
Here, if fy> fya, the Y dot% data at the indicated point is close to the target dot% data, so it is determined that the correction of the highlight density is valid, and this setup parameter is newly stored as a parameter. The data is stored in the unit 38, and the operations of S3 to S5 are performed. On the contrary, if fy <fya, the Y dot% data at the indicated point is away from the target dot% data, so that the highlight density is corrected. Is determined to be too large, the correction amount is changed to, for example, 1/2, and the operations of S3 to S5 are performed.
[0041]
Similarly, for M and C, the evaluation function f_yAnd f_yaUsing the same method as above, the highlight density is determined and corrected.
The highlight density correction operation from S3 to S5 is repeated, and when C, M, and Y all become target halftone data, the setup parameter setting for the highlight density is completed.
[0042]
  On the other hand, when the B mode is selected, only the image information of the designated point is used, and for example, the image processing conditions are determined as follows.
  First, of the set indication points, the one having the minimum density is detected, and the density at this point is designated as the indication point concentration a.₂And
  In this method, the indicated point density a₂The ideal net% balance (one point in C, M, and Y space) corresponding to “Highlights beautifully” with the initial highlight density, and gradation LUT storage of ideal net% datacircuit40, the lowest density portion of the designated point is the ideal halftone balance, and other designated points are set to the ideal halftone data, and the designated point is the ideal halftone data. In addition, the image processing conditions are determined as described above.
[0043]
  By using such an image processing apparatus of the present invention, it is possible to set an image processing condition for making a highlight beautiful by selecting an instruction method for highlight finish information according to the skill and image of an operator. Even a shallow operator can obtain a high-quality image with beautiful highlights, and an experienced operator with high skill can obtain a high-quality image with more highlights. Can do.
  In other words, by selecting a mode that does not set the indication point, even if an operator who has no experience at all cannot perform highlight detection accurately, the device detects the highlight area, and image processing conditions Therefore, it is possible to obtain a high-quality image with beautiful highlights, and further, since it is not necessary to set a designated point, the operation is extremely simple and easy. In addition, by selecting the A mode, when it is difficult to detect an inexperienced operator or highlight, even if the operator makes a mistake in setting the highlight, this is compensated by the pre-scan image information and the image condition is set. Therefore, it is possible to obtain a high-quality image with beautiful highlights.
  In addition, for an experienced operator who can accurately set highlights, or for images with clear highlights, selecting the B mode can cause dust to adhere to the document orElementaryEven in the case of omissions, the image processing conditions can be set without any adverse effects caused by this, so that high-quality images with more beautiful highlights can be obtained.
  In the image processing apparatus of the present invention, as described above, a plurality of finish instructions can be selected. In this case, the image is also taken into account with the ideal halftone data corresponding to other finish instructions. Processing conditions are set.
[0044]
After setting the image processing conditions (setup parameters) in this way, a main scan is performed as shown in FIG. 2, and gradation processing and color correction are performed according to the set image processing conditions as shown in FIG. By performing processing or the like, it is possible to stably form a high-quality output image according to the finish information instruction, in particular, an image with a beautiful highlight.
[0045]
The image processing apparatus according to the present invention has been described in detail above. However, the present invention is not limited to the above-described embodiments, and various improvements and modifications may be made without departing from the scope of the present invention. It is.
[0046]
【The invention's effect】
  As described above in detail, according to the image processing apparatus of the present invention,Means for selecting either the A mode or the B mode selected according to the image or the skill of the operator;It is possible to select finish information instructions regarding highlights according to the image and operator's skill, etc., and to easily create beautiful images with highlights stably. By choiceSelect B mode,It is possible to eliminate the adverse effects of image information obtained by pre-scanning and obtain a high-quality image with extremely beautiful highlights.
[Brief description of the drawings]
FIG. 1 is a configuration block diagram of an image reading / reproducing system using an image processing apparatus of the present invention.
FIG. 2 is a flowchart for explaining the operation of the image reading / reproducing system shown in FIG. 1;
FIG. 3 is a flowchart for explaining image information processing in the image reading and reproducing system shown in FIG. 1;
FIG. 4 is a conceptual diagram showing an example of display on the image reading / reproducing system shown in FIG.
FIG. 5 is a graph showing an example of ideal net% data corresponding to finishing instructions “beautiful highlight”, “align with gray”, and “beautiful shadow”;
[Explanation of symbols]
10 (Image reading / playback) system
12 Reflective document scanner
14 Transparent document scanner
16 workstation
18 Recording device
20 CPU
22 Image reading unit
26 Pre-processing circuit
28 Image processing circuit
30 bus
32 Image buffer
34 color conversion LUT storage
36 Image processing condition correction circuit
38 Parameter storage
40 gradation LUT memory circuit
42 Video buffer
44 Control unit
46 display
48 keyboard
50 mice

Claims (1)

An image processing apparatus that obtains output data by performing image processing according to image processing conditions set in accordance with an instruction of finishing information on image information obtained by photoelectrically reading a document image,
An image reading unit that photoelectrically reads an original image by pre-scanning or main scanning;
Display means for displaying the original image;
Instruction means for determining the finished content of the highlight of the output image obtained from the image information;
In the pre-scan image of the original document image displayed on the display unit when the finish content of the highlight is determined, an instruction point setting unit that sets an area serving as a reference for the highlight as an instruction point;
Means for selecting necessity / unnecessity of the indication point setting by the indication point setting means when determining the finish content of the highlight;
Means for selecting one of the A mode and the B mode when the indicated point is set;
The A mode is set image density is the highlight density obtained by using the image density obtained from the image information other than image information of the designated point and the image density obtained from the image information of the designated point, the high defining a highlight density adjusted obtained by adjusting in accordance with the finish of a lighting a mode for setting the image processing conditions,
The B mode is an image processing apparatus in which a highlight density is determined only from image information of an indicated point and an image processing condition is set.

Images