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JPH08181863A - Gradation conversion curve generation device - Google Patents

Gradation conversion curve generation device

Info

Publication number
JPH08181863A
JPH08181863A JP6320585A JP32058594A JPH08181863A JP H08181863 A JPH08181863 A JP H08181863A JP 6320585 A JP6320585 A JP 6320585A JP 32058594 A JP32058594 A JP 32058594A JP H08181863 A JPH08181863 A JP H08181863A
Authority
JP
Japan
Prior art keywords
gradation
curve
correction
conversion
corrected
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
JP6320585A
Other languages
Japanese (ja)
Other versions
JP3518913B2 (en
Inventor
Koji Hayashi
浩司 林
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Ricoh Co Ltd
Original Assignee
Ricoh Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Ricoh Co Ltd filed Critical Ricoh Co Ltd
Priority to JP32058594A priority Critical patent/JP3518913B2/en
Publication of JPH08181863A publication Critical patent/JPH08181863A/en
Application granted granted Critical
Publication of JP3518913B2 publication Critical patent/JP3518913B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

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  • Image Processing (AREA)
  • Facsimile Image Signal Circuits (AREA)
  • Color Image Communication Systems (AREA)

Abstract

PURPOSE: To provide a correction gradation curve generation device which can obtain a gradation conversion curve correcting the fluctuation in aged gradation characteristics of an image forming device and the variation of characteristics in respective devices by simple calculation by the use of the storage means of limited capacity and which can arbitrarily correct the gradation conversion characteristic of a desired gradation area. CONSTITUTION: The gradation component <j> bi } of the correction gradation curve<j> B corresponding to the numeric value of a gradation adjustment key in the color balance adjustment part of a copying machine is read from ROM 416. Then, γ conversion circuit 410 calculates ci =(w1 .<1> bi +w2 .<2> bi )/-(w1 +w2 ) (w1 and w2 are weight coefficients). The gradation conversion curve D changing the gradation conversion characteristic of a reference gradation conversion curve A is calculated by di =cfi :fi=ai by using the gradation component<j> ci } of the calculated correction gradation curve C. Then, the gradation of recording data on a printer 412 is converted by the gradation conversion curve D changing the gradation conversion characteristic.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明はデジタル方式の複写機、
プリンター、FAXなどの画像形成装置の画像処理装置
に好適に使用され、原稿読取装置により読み取った画像
データの階調変換のための基準階調曲線の階調変換特性
を補正する補正階調曲線を生成する補正階調曲線生成装
置に関する。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital type copying machine,
A correction gradation curve that is suitably used for an image processing apparatus of an image forming apparatus such as a printer or a FAX and that corrects the gradation conversion characteristic of a reference gradation curve for gradation conversion of image data read by a document reading apparatus is provided. The present invention relates to a corrected gradation curve generating device.

【0002】[0002]

【従来の技術】デジタル方式のカラー複写機やカラース
キャナーなどには階調性を有する原稿画像を読み取って
得られる画像データに基づいてプリンターから出力され
る転写紙の記録画像の濃度階調との整合性を取るため
に、画像データの階調変換を行う階調変換装置が設けら
れている。しかしながら、一般に、原稿の濃度分布の特
徴を的確に捉えて、階調変換を行う際の適正な階調変換
曲線を設定する事は容易ではなく、従来は階調変換曲線
の設定はオペレーターの経験に頼るところが多かった。
原画の濃度分布の特徴を簡単なパラメーターで表現し、
そのパラメーターに応じて経験則に合致した階調変換曲
線を自動設定する技術の開発が望まれている。そこで、
例えば、特開平2−12245号公報には、原画の濃度
域を指示するデータを入力し、原画の濃度域に応じてそ
の湾曲状態が決定されたモデル曲線を発生するモデル曲
線発生手段と、階調変換座標面上において、所定のハイ
ライト(低濃度域)点とシャドウ(高濃度域)点を通る
ように前記モデル曲線を修正する修正手段とを具え、前
記モデル曲線の湾曲状態は少なくとも上に凸の状態と下
に凸の状態とを含んだ状態群の中から、原画の濃度域に
応じて、経験則に合致したものが自動的に選択されるよ
うにした階調変換曲線発生装置が開示されている。ま
た、特開平2−291773号公報には、色分解された
入力画像信号に対して等価中性濃度の画像信号に変換す
る手段と、等価中性濃度に変換された信号を記録信号に
変換する手段と、記録信号に対してコントラスト調整を
行う手段を具えた画像処理装置において、コントラスト
調整は折れ線で構成された階調変換表により行い、中間
調における変換特性の傾きを変えるようにした発明が開
示されている。
2. Description of the Related Art In digital color copiers, color scanners, etc., the density gradation of a recorded image on a transfer paper output from a printer based on image data obtained by reading an original image having gradation. A gradation conversion device that performs gradation conversion of image data is provided for consistency. However, in general, it is not easy to accurately grasp the characteristics of the original document's density distribution and set an appropriate gradation conversion curve when performing gradation conversion. Conventionally, the gradation conversion curve was set by the operator. There were many places to rely on.
Express the characteristics of the concentration distribution of the original image with simple parameters,
It is desired to develop a technique for automatically setting a gradation conversion curve that matches the empirical rule according to the parameter. Therefore,
For example, in Japanese Patent Laid-Open No. 2-12245, model curve generating means for inputting data designating a density range of an original image and generating a model curve whose curved state is determined according to the density range of the original image, A correction means for correcting the model curve so as to pass a predetermined highlight (low density area) point and shadow (high density area) point on the tonal conversion coordinate plane, and the curved state of the model curve is at least upward. A tone conversion curve generating device adapted to automatically select one that conforms to the empirical rule from a group of states including a convex state and a downward convex state according to the density range of the original image. Is disclosed. Further, in Japanese Patent Laid-Open No. 2-291773, a means for converting the color-separated input image signal into an image signal of equivalent neutral density and a signal converted into the equivalent neutral density into a recording signal. In the image processing apparatus including the means and the means for performing contrast adjustment with respect to the recording signal, the invention in which the contrast adjustment is performed by the gradation conversion table configured by polygonal lines and the inclination of the conversion characteristic in the halftone is changed is provided. It is disclosed.

【0003】[0003]

【発明が解決しようとする課題】しかしながら、上述の
従来技術にに開示されている階調変換曲線発生装置は複
雑な計算を必要とするために、複写機などの画像形成装
置内で用いるためには計算に時間がかかるため、変換処
理の際に使用者を待たせたり、または、階調変換曲線を
記憶するために、かなり多くのROM容量が必要である
ことから、装置のコストが上がるなどの欠点が有った。
さらに、装置の初期設定時等に階調変換曲線の修正の際
に用いられるモデル曲線の湾曲状態は上に凸の状態と下
に凸の状態とを含んだ状態群の中から選択されるので、
修正後の階調変換曲線の湾曲形状は制約を受け、所定の
階調領域について細かな修正を施すことが難しかった。
また、折れ線で構成された階調変換表を用いて記録信号
に対してコントラスト調整を行う画像処理装置において
は、階調変換表作成の自由度は高いものの、滑らかな階
調補正曲線を生成したり、ハイライト部やシャドウ部の
階調性の微妙な調整を行うには折れ線の接続点の数が膨
大になり、やはり、大容量のROMが必要になるため、
コストの上昇が避けられなかった。本発明は従来技術に
おける上述の問題点に鑑み成されたものであり、限られ
た容量の記憶手段を用いて、簡単な計算によって画像形
成装置の経時濃度特性変動や個々の装置における特性の
バラつきを補正する階調変換曲線を得ることができると
共に、所望の濃度領域の階調変換特性を任意に修正可能
な補正階調曲線生成装置を提供することを目的とする。
However, since the gradation conversion curve generator disclosed in the above-mentioned prior art requires complicated calculation, it is used in an image forming apparatus such as a copying machine. Takes a long time to calculate, so that the user has to wait during the conversion process, or a considerably large amount of ROM capacity is required to store the gradation conversion curve, which increases the cost of the device. Had its drawbacks.
Further, the curved state of the model curve used when modifying the gradation conversion curve at the time of initial setting of the apparatus is selected from the state group including the upward convex state and the downward convex state. ,
The curved shape of the corrected gradation conversion curve is restricted, and it is difficult to make a fine correction in a predetermined gradation region.
Further, in an image processing device that performs contrast adjustment on a recording signal using a gradation conversion table composed of polygonal lines, although a gradation conversion table has a high degree of freedom, a smooth gradation correction curve is generated. Or, the number of connection points of the polygonal line becomes enormous in order to finely adjust the gradation of the highlight part and the shadow part, and again, since a large capacity ROM is required,
The rise in costs was inevitable. The present invention has been made in view of the above-mentioned problems in the prior art, and uses a storage device having a limited capacity to perform a simple calculation to change the density characteristics of an image forming apparatus over time and variations in characteristics of individual apparatuses. It is an object of the present invention to provide a corrected gradation curve generation device capable of obtaining a gradation conversion curve for correcting the above, and capable of arbitrarily correcting the gradation conversion characteristic of a desired density region.

【0004】[0004]

【課題を解決するための手段】本発明は上記課題を解決
するために、γ変換における基準となる基準階調変換曲
線Aと該基準階調変換曲線Aを補正する際に用いられる
複数の補正階調曲線 jB(j=1,…,n)の階調成分{a
i },{ ji }を入力階調iに対応付けて記憶する階
調曲線記憶手段と、該階調曲線記憶手段から読み出した
複数の補正階調曲線 jBの階調成分{ ji }に所定の
重み付き平均処理を施す補正演算をする補正階調曲線演
算手段あるいは入力データに等しい出力データを与える
恒等変換を表す恒等変換曲線E上の座標点と該座標点を
通る垂線と補正階調曲線 jCおよび補正階調曲線-jCと
の交点をそれぞれ結ぶ線分が等しくなるように、少なく
とも1つの補正階調曲線 jBの階調成分{ ji }に基
づいて補正階調曲線 jCの階調成分{ ji }を演算す
る補正階調曲線演算手段を有し、補正階調曲線演算手段
が演算した補正階調曲線 jCに基づいて前記基準階調変
換曲線Aを補正して新たな階調変換曲線Dを生成し、該
階調変換曲線Dに基づいて入力データに対して所望の出
力データを与えるγ変換を行わせるようにしたものであ
る。
In order to solve the above-mentioned problems, the present invention solves the above-mentioned problems by using a reference gradation conversion curve A as a reference in γ conversion and a plurality of corrections used when correcting the reference gradation conversion curve A. The gradation component {a of the gradation curve j B (j = 1, ..., N)
i }, { jb i } stored in association with the input gradation i, and gradation components { j b of the plurality of corrected gradation curves j B read from the gradation curve storage means. i } through a coordinate point on the identity transformation curve E representing the identity transformation which gives the output data equal to the input data, or the correction gradation curve computing means for performing the correction computation for applying a predetermined weighted averaging process to the coordinate point. Based on the gradation component { jb i } of at least one correction gradation curve j B so that the line segments connecting the perpendicular line and the intersections of the correction gradation curve j C and the correction gradation curve -j C are equal. a correction gradation curve calculating means for calculating a gradation component {j c i} of the correction gradation curve j C Te, the correction gradation curve calculating means and said standard floor based on the corrected gradation curve j C which is calculated The gradation conversion curve A is corrected to generate a new gradation conversion curve D, and based on the gradation conversion curve D, It is obtained so as to perform γ conversion to provide the desired output data to the input data Te.

【0005】[0005]

【作用】階調曲線記憶手段はγ変換における基準となる
基準階調変換曲線Aと該基準階調変換曲線Aを補正する
際に用いられる複数の補正階調曲線 jBの階調成分{a
i },{ ji }を入力階調iに対応付けて記憶する。
補正階調曲線演算手段は階調曲線記憶手段から読み出し
た複数の補正階調曲線 jBの階調成分{ ji }に所定
の重み付き平均処理を施し、あるいは、入力データに等
しい出力データを与える恒等変換を表す恒等変換曲線E
上の座標点と該座標点を通る垂線と補正階調曲線 jCお
よび補正階調曲線-jCとの交点をそれぞれ結ぶ線分が等
しくなるように、少なくとも1つの補正階調曲線 jBの
階調成分{ ji }に基づいて補正階調曲線 jCの階調
成分{ ji }を演算する。補正階調曲線演算手段が演
算した補正階調曲線 jCに基づいて基準階調変換曲線A
に補正が施されることにより、新たな階調変換曲線Dが
得られ、γ変換においては新しい階調変換曲線Dに基づ
いて入力データに対して所望の出力データが与えられ
る。
[Function] The gradation curve storage means serves as a reference in γ conversion.
Correct the standard gradation conversion curve A and the standard gradation conversion curve A
Multiple correction gradation curves used whenjB gradation component {a
i}, {jbi} Is stored in association with the input gradation i.
The corrected gradation curve calculation means reads out from the gradation curve storage means.
Multiple correction gradation curvesjB gradation component {jbi} Prescribed
Weighted averaging, or input data
Identical transformation curve E that gives new output data
The upper coordinate point, the perpendicular line passing through the coordinate point, and the corrected gradation curvejC
And correction gradation curve-jThe line segment connecting each intersection with C is equal
At least one correction gradation curve so thatjB's
Gradation component {jbi} Based on the corrected gradation curvejC gradation
component{jci} Is calculated. Corrected gradation curve calculation means
Corrected gradation curve calculatedjReference gradation conversion curve A based on C
The new gradation conversion curve D is
Which is obtained based on the new gradation conversion curve D in γ conversion.
The desired output data for the input data
It

【0006】[0006]

【実施例】以下、本発明を画像形成装置である電子写真
複写機(以下、単に複写機と言う)に適用した実施例に
ついて説明する。まず、図2に示す機構図によって実施
例の複写機本体101の機構の概略を説明する。図2に
おいて、複写機本体101のほぼ中央部に配置された像
担持体としての120 mmφの有機感光体(OPC)ドラ
ム102の周囲には、該感光体ドラム102の表面を帯
電する帯電チャージャー103、一様帯電された感光体
ドラム102の表面上に半導体レーザーから射出された
レーザー光を照射して静電潜像を形成するレーザー光学
系104、静電潜像に各色トナーを供給して現像し、各
色毎にトナー像を得る黒現像装置105及びイエロー
Y、マゼンダM、シアンCの3つのカラー現像装置10
6、107、108、感光体ドラム102上に形成され
た各色毎のトナー像を順次転写する中間転写ベルト10
9、上記中間転写ベルト109に転写電圧を印加するバ
イアスローラー110、転写後の感光体ドラム102の
表面に残留するトナーを除去するクリーニング装置11
1、転写後の感光体ドラム102の表面に残留する電荷
を除去する除電部112などが順次配列されている。上
記中間転写ベルト109の周囲には、転写されたトナー
像を転写材に転写する電圧を印加するための転写バイア
スローラー113及び転写材に転写後に残留したトナー
像を除去するためのベルトクリーニング装置114が配
設されている。また、中間転写ベルト109から剥離さ
れた転写材を搬送する搬送ベルト115の下流側端部に
は転写材上のトナーを加熱及び加圧して定着させる定着
装置116が配置されている。この定着装置116の出
口部には、定着された転写材を排出するための排紙トレ
イ117が取り付けられている。複写機本体101のレ
ーザー光学系104の上部には、原稿載置台としてのコ
ンタクトガラス118、このコンタクトガラス118上
に載置された原稿に走査光を照射する露光ランプ11
9、原稿からの反射光を結像レンズ122に導く反射ミ
ラー121、および結像レンズ122によって結像され
入光した反射光を光電変する光電変換素子としてのCC
D(Charge Coupled Device )から成るイメージセンサ
ーアレイ123が配置されている。イメージセンサーア
レイ123で原稿の画像情報が電気信号に変換された画
像信号は、後述する画像処理装置を経てレーザー光学系
104に送られて、その中の半導体レーザーのレーザー
発振を制御する。
Embodiments Embodiments in which the present invention is applied to an electrophotographic copying machine (hereinafter simply referred to as a copying machine) which is an image forming apparatus will be described. First, the outline of the mechanism of the copying machine main body 101 of the embodiment will be described with reference to the mechanism diagram shown in FIG. In FIG. 2, a 120 mmφ organic photoconductor (OPC) drum 102, which serves as an image carrier, is arranged in the central portion of the copying machine main body 101, and is surrounded by a charging charger 103 for charging the surface of the photoconductor drum 102. A laser optical system 104 that irradiates a laser beam emitted from a semiconductor laser on the surface of the uniformly charged photosensitive drum 102 to form an electrostatic latent image; and supplies toner of each color to the electrostatic latent image for development. Then, a black developing device 105 for obtaining a toner image for each color and three color developing devices 10 for yellow Y, magenta M, and cyan C
6, 107, 108, the intermediate transfer belt 10 for sequentially transferring the toner images of the respective colors formed on the photosensitive drum 102.
9, a bias roller 110 that applies a transfer voltage to the intermediate transfer belt 109, and a cleaning device 11 that removes toner remaining on the surface of the photosensitive drum 102 after transfer.
1. A charge removing unit 112 for removing charges remaining on the surface of the photosensitive drum 102 after transfer is sequentially arranged. Around the intermediate transfer belt 109, a transfer bias roller 113 for applying a voltage for transferring the transferred toner image to the transfer material and a belt cleaning device 114 for removing the toner image remaining after being transferred to the transfer material. Is provided. Further, a fixing device 116 that heats and pressurizes the toner on the transfer material to fix the toner on the transfer material is arranged at the downstream end of the conveyor belt 115 that conveys the transfer material separated from the intermediate transfer belt 109. A discharge tray 117 for discharging the fixed transfer material is attached to the outlet of the fixing device 116. Above the laser optical system 104 of the copying machine main body 101, a contact glass 118 as a document placing table, and an exposure lamp 11 for irradiating a document placed on the contact glass 118 with scanning light.
9, a reflection mirror 121 that guides the reflected light from the document to the imaging lens 122, and a CC as a photoelectric conversion element that photoelectrically converts the reflected light that is imaged and entered by the imaging lens 122.
An image sensor array 123 including a D (Charge Coupled Device) is arranged. The image signal obtained by converting the image information of the original document into an electric signal by the image sensor array 123 is sent to the laser optical system 104 through an image processing device described later to control the laser oscillation of the semiconductor laser therein.

【0007】次に、複写機の電装部の概略を示す図3を
用いて複写機の電装部について説明する。図3に示すよ
うに、複写機は全体を制御するメイン制御部(CPU)
130を備えていて、このメイン制御部130に対して
所定の制御情報を記憶するROM131及びRAM13
2が付設されている。さらに、メイン制御部130には
インターフェースI/O133を介してレーザー光学系
制御部134、電源回路135、光学センサー136、
トナー濃度センサー137、環境センサー138、電位
センサー139、トナー補給回路140および中間転写
ベルト駆動部141がそれぞれ接続されている。レーザ
ー光学系制御部134はレーザー光学系104のレーザ
ー出力を調整する。また、電源回路135は帯電チャー
ジャー103に対して所定の帯電用放電電圧を与えると
共に、各色の現像装置105〜108に対して所定の現
像バイアス電圧を与え、かつ、バイアスローラー110
および転写バイアスローラー113に対して所定の転写
電圧を与える。光学センサー136は発光ダイオードな
どの発光素子とフォトセンサーなどの受光素子とから成
り、感光体ドラム102の転写位置後方に近接配置さ
れ、感光体ドラム102上に形成される検知パターン潜
像のトナー像におけるトナー付着量及び地肌部における
トナー付着量を各色毎にそれぞれ検知すると共に、感光
体ドラム102の除電後の電位、所謂、残留電位を検知
するようになっている。この光電センサー136からの
検知出力信号は図示を省略した光電センサー制御部に印
加されている。光電センサー制御部は検知パターントナ
ー像に於けるトナー付着量と地肌部におけるトナー付着
量との比率を求め、その比率値を基準値と比較して画像
濃度の変動を検知し、トナー濃度センサー137の制御
値の補正を行なっている。
Next, the electrical components of the copying machine will be described with reference to FIG. 3 which shows the outline of the electrical components of the copying machine. As shown in FIG. 3, the copying machine has a main control unit (CPU) that controls the entire copying machine.
A ROM 131 and a RAM 13 that are provided with a main control unit 130 and store predetermined control information.
2 is attached. Further, the main control unit 130 has a laser optical system control unit 134, a power supply circuit 135, an optical sensor 136, and an interface I / O 133.
A toner concentration sensor 137, an environment sensor 138, a potential sensor 139, a toner replenishing circuit 140, and an intermediate transfer belt driving unit 141 are connected to each other. The laser optical system controller 134 adjusts the laser output of the laser optical system 104. Further, the power supply circuit 135 supplies a predetermined charging discharge voltage to the charging charger 103, a predetermined developing bias voltage to the developing devices 105 to 108 for the respective colors, and the bias roller 110.
And a predetermined transfer voltage is applied to the transfer bias roller 113. The optical sensor 136 includes a light emitting element such as a light emitting diode and a light receiving element such as a photo sensor. The optical sensor 136 is disposed in the vicinity of the transfer position of the photoconductor drum 102 in the vicinity thereof and is a toner image of a detection pattern latent image formed on the photoconductor drum 102. In addition to detecting the amount of toner adhering to the toner and the amount of toner adhering to the background portion for each color, the potential of the photoconductor drum 102 after static elimination, that is, the so-called residual potential is detected. The detection output signal from the photoelectric sensor 136 is applied to a photoelectric sensor control unit (not shown). The photoelectric sensor control unit obtains a ratio between the toner adhesion amount in the detection pattern toner image and the toner adhesion amount in the background portion, compares the ratio value with a reference value to detect a change in image density, and detects the toner density sensor 137. The control value of is corrected.

【0008】また、トナー濃度センサー137は現像装
置105〜108内において現像装置105〜108内
に存在する現像剤の透磁率変化に基づいてトナー濃度を
検知する。トナー濃度センサー137は検知されたトナ
ー濃度値と基準値とを比較し、トナー濃度が一定値を下
回ってトナー不足状態になった場合に、その不足分に対
応した大きさのトナー補給信号をトナー補給回路140
に出力する機能を有している。電位センサー139は像
担持体である感光体102の表面電位を検知し、中間転
写ベルト駆動部141は中間転写ベルト109の駆動を
制御する。M現像器107内にはMトナーと搬送材を含
む現像剤が収容されていて、剤撹拌部材204Mの回転
によって撹拌される。現像剤規制部材は現像スリーブ2
01M上に汲み上げられる現像剤量を調節する。現像ス
リーブ201M上に供給された現像剤は磁気的に現像ス
リーブ201Mに担持されつつ、磁気ブラシとして現像
スリーブ201Mの回転方向に移動する。なお、図3に
は示していないが、他の色の現像器においても全く同様
の構成と動作を有している。
Further, the toner concentration sensor 137 detects the toner concentration in the developing devices 105 to 108 based on the change in magnetic permeability of the developer existing in the developing devices 105 to 108. The toner concentration sensor 137 compares the detected toner concentration value with a reference value, and when the toner concentration falls below a certain value and a toner shortage occurs, a toner replenishment signal of a magnitude corresponding to the shortage is supplied to the toner concentration sensor 137. Supply circuit 140
It has a function to output to. The potential sensor 139 detects the surface potential of the photoconductor 102, which is an image carrier, and the intermediate transfer belt drive unit 141 controls driving of the intermediate transfer belt 109. A developer containing M toner and a transport material is accommodated in the M developing device 107, and is agitated by the rotation of the agent agitating member 204M. The developer regulating member is the developing sleeve 2
Adjust the amount of developer pumped over 01M. The developer supplied onto the developing sleeve 201M is magnetically carried by the developing sleeve 201M and moves as a magnetic brush in the rotating direction of the developing sleeve 201M. Although not shown in FIG. 3, developing devices of other colors have exactly the same configuration and operation.

【0009】図1は画像処理ユニットを含む画像処理装
置のブロック図である。以下、画像処理装置の構成につ
いて説明する。同図において、401はスキャナー、4
02はシェーディング補正回路、403はRGBγ補正
回路、404は画像分離回路、405はMTF補正回
路、406は色変換−UCR処理回路、407は変倍回
路、408は画像加工(クリエイト)回路、409はM
TFフィルター、410はγ変換回路、411は階調処
理回路、412はプリンターである。なお、画像処理ユ
ニットは図1に示す画像処理装置のスキャナー401お
よびプリンター412を除いた部分である。コンタクト
ガラス118上に載置された原稿の画像はスキャナー4
01によってR,G,Bの3色に分解されて読み取られ
る。シェーディング補正回路402では、イメージセン
サーアレイ123の撮像素子のムラ、露光ランプ119
光源の照明ムラなどが補正される。RGBγ補正回路4
03ではスキャナー401で読み取られた画像信号が反
射率データから明度データに変換される。画像分離回路
404では文字部と写真部の判定および有彩色、無彩色
の判定が行われる。MTF補正回路405では特に、画
像信号の高周波領域でのMTF特性の劣化が補正され
る。色変換−UCR処理回路406は入力したR,G,
B系の色分解特性と出力されるY,M,C系の色データ
の分光特性の違いを補正し、忠実な色再現に必要な色デ
ータY,M,Cの値を計算する色補正処理部と、補色の
Y,M,Cの3色が重なる成分をBk(ブラック)に置
き換えるためのUCR処理部とからなる。色補正処理部
での色補正処理は図12の演算式に示すマトリックス演
算を実行することにより実現できる。同図において、
はR,G,Bの3色の補数を表す。マトリッ
クス係数aij の値は入力系色データ(R,G,B)と出
力系色データ(Y,M,C)の分光特性によって決ま
る。なお、本実施例では一次マスキング方程式に因った
が、 2 BGのような2次項、あるいはさらに高次の
項を用いることにより、より精度良く色補正することが
できる。また、色相によって演算式を変えたり、ノイゲ
バウアー方程式を用いるようにしても良い。何れの方法
にしても、補色の3成分Y,M,Cは色の3補数成分の
(または、色の3成分B,G,Rでも良い)
の値から求めることができる。一方、UCR処理は次式
を用いて演算することにより行うことができる。 Y’=Y−α・min (Y,M,C) M’=M−α・min (Y,M,C) C’=C−α・min (Y,M,C) Bk = α・min (Y,M,C) 上式において、αはUCRの量を決める係数であり、α
=1の時100%UCR処理となる。例えば、高濃度部
ではα≒1、ハイライト部ではα≒0にすることによ
り、ハイライト部での画像を滑らかにすることができ
る。なお、αは一定値でも良い。
FIG. 1 is a block diagram of an image processing apparatus including an image processing unit. The configuration of the image processing apparatus will be described below. In the figure, 401 is a scanner, 4
Reference numeral 02 is a shading correction circuit, 403 is an RGBγ correction circuit, 404 is an image separation circuit, 405 is an MTF correction circuit, 406 is a color conversion-UCR processing circuit, 407 is a scaling circuit, 408 is an image processing (create) circuit, and 409 is 409. M
A TF filter, 410 is a γ conversion circuit, 411 is a gradation processing circuit, and 412 is a printer. The image processing unit is a part of the image processing apparatus shown in FIG. 1 excluding the scanner 401 and the printer 412. The image of the document placed on the contact glass 118 is the scanner 4
01 is separated into three colors of R, G, and B and read. In the shading correction circuit 402, the unevenness of the image sensor of the image sensor array 123, the exposure lamp 119
Illumination unevenness of the light source is corrected. RGBγ correction circuit 4
In 03, the image signal read by the scanner 401 is converted from reflectance data to brightness data. The image separation circuit 404 determines the character portion and the photograph portion and determines the chromatic color and the achromatic color. In particular, the MTF correction circuit 405 corrects the deterioration of the MTF characteristic in the high frequency region of the image signal. The color conversion-UCR processing circuit 406 inputs the R, G,
Color correction processing that corrects the difference between the spectral characteristics of the B color separation characteristics and the output Y, M, C color data, and calculates the values of the color data Y, M, C necessary for faithful color reproduction. And a UCR processing unit for replacing a component in which three complementary colors Y, M, and C overlap with Bk (black). The color correction processing in the color correction processing unit can be realized by executing the matrix calculation shown in the calculation formula of FIG. In the figure,
R , G and B represent the three color complements of R, G and B. The value of the matrix coefficient aij is determined by the spectral characteristics of the input system color data (R, G, B) and the output system color data (Y, M, C). In this embodiment, although it was due to the first-order masking equation, color correction can be performed more accurately by using a quadratic term such as B 2 or BG , or a higher-order term. Further, the arithmetic expression may be changed depending on the hue, or the Neugebauer equation may be used. Whichever method is used, the three complementary color components Y, M, and C are the three complementary color components.
B , G , R (or three color components B, G, R)
It can be obtained from the value of. On the other hand, the UCR process can be performed by calculating using the following equation. Y ′ = Y−α · min (Y, M, C) M ′ = M−α · min (Y, M, C) C ′ = C−α · min (Y, M, C) Bk = α · min (Y, M, C) In the above equation, α is a coefficient that determines the amount of UCR, and α
When = 1, 100% UCR processing is performed. For example, by setting α≈1 in the high density portion and α≈0 in the highlight portion, the image in the highlight portion can be smoothed. Note that α may be a constant value.

【0010】変倍回路407では縦横変倍が行われ、画
像加工(クリエイト)回路408ではリピート処理など
が行われる。また、MTFフィルター409ではシャー
プな画像やソフトな画像など、使用者の好みに応じてエ
ッジ強調や平滑化等、画像信号の周波数特性を変更する
処理が行われる。γ変換回路410ではプリンター41
2の特性に応じて、画像信号の補正が行われる。また、
地肌汚れ除去等の処理も同時に行うことができる。階調
処理回路411ではディザ処理またはパターン処理が行
われる。インターフェース(I/F)413,414は
スキャナー401で読み込んだ画像データを外部の画像
処理装置等で処理したり、外部の画像処理装置からの画
像データをプリンター412で出力するために備えられ
ている。上述の画像処理回路を制御する画像処理CPU
415及びROM416、RAM417はバス418で
接続されている。画像処理CPU415はシリアルI/
Fを通じて、システムコントローラー419および必要
に応じて外部のホストコンピューター420と接続され
ており、図示しない操作部などからのコマンド信号をも
受信する。図4はプリンター412のレーザー変調回路
のブロック図である。ルックアップテーブル(LUT)
451では8ビットの画像データにγ変換を施すことが
できる。パルス幅変調回路(PWM)452に入力した
8ビットの画像信号は、その上位2ビットの信号に基づ
いて4値のパルス幅データに変換され、強度変調回路
(PM)453で下位6ビットの信号に基づいて64値
の強度変調が施される。レーザーダイオード(LD)4
54は変調された駆動信号に従って発光する。レーザー
光学系制御部134はフォトディテクター(PD)45
5が検出した検出結果に基づいて、1ドット毎にLD4
54の発光強度の光量補正を行う。なお、レーザー光の
強度の最大値は、画像信号とは独立に8ビット(256
段階)に可変できる。また、LD454の書き込み周波
数は18.6MHz 、1画素の走査時間は53.8nsecである。
The scaling circuit 407 performs vertical and horizontal scaling, and the image processing (create) circuit 408 performs repeat processing. Further, the MTF filter 409 performs processing for changing the frequency characteristic of the image signal, such as edge enhancement and smoothing according to the user's preference such as a sharp image or a soft image. In the γ conversion circuit 410, the printer 41
The image signal is corrected according to the characteristics of 2. Also,
It is also possible to simultaneously perform processing such as background stain removal. The gradation processing circuit 411 performs dither processing or pattern processing. Interfaces (I / F) 413 and 414 are provided for processing image data read by the scanner 401 by an external image processing device or the like, and outputting image data from the external image processing device by the printer 412. . Image processing CPU for controlling the above-mentioned image processing circuit
The bus 418 connects the ROM 416, the ROM 416, and the RAM 417. The image processing CPU 415 is a serial I /
Through F, it is connected to the system controller 419 and an external host computer 420 as necessary, and receives command signals from an operation unit (not shown). FIG. 4 is a block diagram of the laser modulation circuit of the printer 412. Look-up table (LUT)
In 451 it is possible to perform γ conversion on 8-bit image data. The 8-bit image signal input to the pulse width modulation circuit (PWM) 452 is converted into 4-valued pulse width data based on the higher 2-bit signal, and the intensity modulation circuit (PM) 453 lower-order 6-bit signal. A 64-value intensity modulation is performed based on Laser diode (LD) 4
54 emits light according to the modulated drive signal. The laser optical system control unit 134 is a photo detector (PD) 45.
LD4 for each dot based on the detection result detected by
The light intensity of the light emission intensity of 54 is corrected. The maximum value of the laser light intensity is 8 bits (256
It can be changed in steps). The write frequency of the LD454 is 18.6MH z, 1 pixel of the scan time is 53.8Nsec.

【0011】図5はPM453から出力される隣接する
2つのラインL1 ,L2 の記録信号のタイミング図と、
それらに対応する記録画像を示す説明図である。画像信
号はディザ処理が施された後、PWM452およびPM
453によってパルス幅変調されてLD454に出力さ
れるが、その時のタイミングは図5に示すように、隣接
する2つの画素のハイとなる位置が互いに隣合うように
なっている。これにより、記録画像の画素パターンは副
走査方向に連続したものになり、画素パターンの幅は1
番目の画素の濃度と2番目の画素の濃度の和にほぼ比例
する。図6は主走査方向の隣接する2つの画素の異なる
光束径(静止時の光束の光強度が最大値から1/e2
減衰するまでの幅)のLD454の記録信号の和と光電
センサー136の検知出力を示す特性図である。記録信
号の出力タイミングを上述のように制御することによ
り、記録信号の出力値と光電センサー136で検知した
トナー像の濃度値の優れた線型性を得ることができる。
なお、図6に示すように、LD454の主走査方向の光
束径が小さくなる程、記録信号の出力値とトナー像の濃
度値の線型性が向上する。この線型性は光束径にも依存
する。光束径は1画素の主走査方向の幅の90%以下、
望ましくは80%以下とするのが良い。画素密度が40
0DPI 、主走査方向の画素幅が63.5μm の時は、望
ましい光束径は50μm 以下である。
FIG. 5 is a timing chart of recording signals of two adjacent lines L 1 and L 2 output from the PM 453,
It is explanatory drawing which shows the recording image corresponding to them. After the image signal is dithered, PWM 452 and PM
The pulse width is modulated by 453 and output to the LD 454. At that time, as shown in FIG. 5, the high positions of two adjacent pixels are adjacent to each other. As a result, the pixel pattern of the recorded image becomes continuous in the sub-scanning direction, and the width of the pixel pattern is 1
It is almost proportional to the sum of the density of the second pixel and the density of the second pixel. FIG. 6 shows the photoelectric sensor 136 and the sum of the recording signals of the LD 454 of different light beam diameters (widths until the light intensity of the light beam at rest is attenuated from the maximum value to 1 / e 2 ) of two adjacent pixels in the main scanning direction. It is a characteristic view showing the detection output of. By controlling the output timing of the recording signal as described above, excellent linearity of the output value of the recording signal and the density value of the toner image detected by the photoelectric sensor 136 can be obtained.
As shown in FIG. 6, the linearity of the output value of the recording signal and the density value of the toner image improves as the light beam diameter of the LD 454 in the main scanning direction decreases. This linearity also depends on the beam diameter. The luminous flux diameter is 90% or less of the width of one pixel in the main scanning direction,
It is preferably 80% or less. Pixel density is 40
When the pixel width in the main scanning direction is 0DPI and 63.5 μm, the desired luminous flux diameter is 50 μm or less.

【0012】図7は複写機の操作表示板のカラーバラン
ス調整部に表示された調整画面を示す平面図である。本
実施例では同図に示すように、YMCBk の濃度を濃度
調整キー20の操作により、無調整を0、濃度を濃くす
る側を+、濃度を薄くする側を−として左右に±4段
階、即ち、全部で9段階にカラーバランス調整できるよ
うになっている。以下に、カラーバランス調整を行った
時のγ変換回路410で行われる階調変換処理の階調変
換特性を変える階調変換曲線の補正処理について述べ
る。図8はカラーバランス調整を行った時の複写動作の
流れ図である。同図を参照して上記動作の処理を説明す
る。まず、操作者によるカラーバランス調整部の濃度キ
ー20の選択操作を待って、その値を参照する(S
1)。そして、操作者によるコピー開始釦の押下を待っ
て、コピー開始信号を受信する(S2)。なお、これら
の信号は操作表示板上の操作により得られるものの外
に、オンライン接続された外部制御装置から入力された
ものであっても良い。CPU415は濃度調整キー20
からの濃度選択信号を受信すると、基準階調変換曲線A
の階調成分{ai }と必要な補正階調曲線Bi の階調成
分{bi }をROM416から読み出してγ変換回路4
10に転送し、選択された濃度選択信号に対応する階調
変換曲線Dを得るための補正階調曲線Cの階調成分{c
i }を演算させる(S3)。階調成分ci は一般に不連
続な値となるので、比例近似補間処理を行う(S4)。
さらに、補正階調曲線Cを滑らかにするために、表図9
にフィルター係数を示す1×5の大きさの平滑化デジタ
ルフィルターを用いて平滑化処理を行う(S5)。こう
して平滑化された補正階調曲線Cを用いてカラーバラン
ス調整による階調変換曲線Dを得る。そして、通常の複
写動作ルーチンに従ってコピー動作を実行する(S
6)。このカラーバランス調整複写処理はYMCBK の
各色毎、また、写真モードや文字モード等の各モード毎
に行われる。次に、手順S3で行われる、選択された濃
度選択信号に対応する階調変換曲線Dを得るための補正
階調曲線Cの階調成分{ci }の演算処理について詳述
する。基準となる基準階調変換曲線A(階調成分ai
に対し、階調変換特性を変えるための複数の補正階調曲
線を補正階調曲線 jB(j=1,…,n)とし、これらの曲
線を与える入力IN−出力OUTの変換データをROM
416に予め格納しておく。そして、階調変換曲線の補
正処理を行う時に上記入力IN−出力OUTの変換デー
タを読み出して、任意の2つの補正階調曲線 jBを選択
する。選択された2つの補正階調曲線 1B, 2Bの諧調
成分を 1i 2i 、階調成分 1i 2i に対す
る重みをw1 ,w2 (w1 ,w2 は自然数)、新たな補
正階調曲線をC(階調成分ci )とすると、新たな補正
階調曲線Cの階調成分ci は補正階調曲線 1B, 2
の階調成分 1i 2i の重み付き平均値を求めるこ
とにより、下記のように表すことができる。 ci =(w1 1i +w2 2i )/(w1 +w2 )(i=1,…,256)(1) 補正階調曲線Cを用いて基準階調変換曲線Aの階調変換
特性を変える変換式は di =cfi :fi =ai … (2) と表すことができる。fi は基準階調変換曲線Aの入力
IN=iに対する出力OUT、cfiは補正階調曲線Cの
入力IN=fi に対する出力OUTを表す。
FIG. 7 is a plan view showing an adjustment screen displayed on the color balance adjusting section of the operation display plate of the copying machine. In the present embodiment, as shown in the figure, the density of YMCBk is adjusted by operating the density adjusting key 20 to 0 for no adjustment, + for increasing the density and − for decreasing the density. That is, the color balance can be adjusted in 9 steps in total. Hereinafter, the correction processing of the gradation conversion curve that changes the gradation conversion characteristic of the gradation conversion processing performed by the γ conversion circuit 410 when the color balance adjustment is performed will be described. FIG. 8 is a flow chart of the copying operation when the color balance adjustment is performed. The processing of the above operation will be described with reference to FIG. First, after waiting for the operator to select the density key 20 of the color balance adjusting section, the value is referred to (S).
1). Then, after the operator depresses the copy start button, the copy start signal is received (S2). In addition to these signals obtained by the operation on the operation display board, these signals may be input from an external control device connected online. The CPU 415 is the density adjustment key 20.
When receiving the density selection signal from the reference gradation conversion curve A
Gradation component {a i } and the necessary correction gradation curve B i gradation component {b i } are read from the ROM 416 and the γ conversion circuit 4 is read.
10 and the gradation component {c of the corrected gradation curve C for obtaining the gradation conversion curve D corresponding to the selected density selection signal.
i } is calculated (S3). Since the gradation component c i generally has discontinuous values, proportional approximation interpolation processing is performed (S4).
Furthermore, in order to smooth the correction gradation curve C, the table shown in FIG.
Then, smoothing processing is performed using a smoothing digital filter having a size of 1 × 5 indicating the filter coefficient (S5). A gradation conversion curve D by color balance adjustment is obtained using the corrected gradation curve C thus smoothed. Then, the copy operation is executed according to the normal copy operation routine (S
6). The color balance adjustment copying process is performed for each color of YMCBK, and for each mode such as the photo mode and the character mode. Next, the calculation process of the gradation component {c i } of the corrected gradation curve C for obtaining the gradation conversion curve D corresponding to the selected density selection signal, which is performed in step S3, will be described in detail. Reference gradation conversion curve A (gradation component a i ) serving as a reference
On the other hand, a plurality of correction gradation curves for changing the gradation conversion characteristics are set as correction gradation curves j B (j = 1, ..., N), and the conversion data of the input IN-output OUT that gives these curves is stored in the ROM.
It is stored in 416 in advance. Then, when the correction processing of the gradation conversion curve is performed, the conversion data of the input IN-output OUT is read and two arbitrary corrected gradation curves j B are selected. The tone components of the two selected correction tone curves 1 B and 2 B are 1 b i and 2 b i , and the weights for the tone components 1 b i and 2 b i are w 1 and w 2 (w 1 and w 2 is a natural number), a new correction gradation curve When C (tone component c i), tone component c i of a new correction gradation curve C is corrected gradation curve 1 B, 2 B
The following can be expressed by obtaining the weighted average value of the gradation components 1 b i and 2 b i . c i = (w 1 · 1 b i + w 2 · 2 b i ) / (w 1 + w 2 ) (i = 1, ..., 256) (1) Using the corrected gradation curve C, the reference gradation conversion curve A A conversion equation for changing the gradation conversion characteristic of can be expressed as: d i = c fi : fi = a i (2) fi represents an output OUT for the input IN = i of the reference gradation conversion curve A, and c fi represents an output OUT for the input IN = fi of the corrected gradation curve C.

【0013】補正階調曲線Cが単純平均により求められ
る場合は(1) 式はw1 =w2 として ci =( 1i 2i )/2 ;(i =1,…,256) …(1) ′ となる。図10は補正階調曲線Cを補正階調曲線 1B,
2Bの階調成分 1i 2i の単純平均により求めた
一例を示したものである。なお、Eは恒等変換を表す。
操作表示板のカラーバランス調整部の濃度調整キー20
の数値と補正階調曲線 jBが表図11のように対応付け
られるとすると、図7に示すカラーバランス調整部に目
盛られた濃度キー20の数値の中間の濃度キーに対応す
る補正階調曲線Cは表図12のようになる。カラーバラ
ンス調整部の濃度調整キー20の数値をjとすると、表
図11,12に表された濃度調整キー20の数値jに対
応する補正階調曲線 jCの階調成分 ji を与える演算
式は一般的な重み付き平均を取るとすると、 ji =〔w1 [(4+j)/2]i +w2 ([(4+j)/2] +1)i 〕 /(w1 +w2 ) ;(j;奇数) ji [(4+j)/2]i ;(j;偶数) … (3) (〔x〕はxを越えない最大整数(Gauss の括弧)、-4
≦j≦4 )と表すことができる。なお、上述の単純平均
を取る場合はw1 =w2 となる。このように、本実施例
では偶数の濃度調整キー20の数値2mに対応する補正
階調曲線2mBを与えるだけで奇数の濃度調整キー20の
数値(2m+1)を含む全ての濃度調整キー20に対応
する補正階調曲線 jCの階調成分 ji を得ることがで
きる。従って、全ての濃度調整キー20に対応する補正
階調曲線 jBの変換データをROM416に記憶させた
場合に較べて記憶容量を約半分に削減することができ
る。上述の例では2つの補正階調曲線 1B, 2Bを用い
て、その中間的な補正階調特性を有する新たな補正階調
曲線Cを演算するようにしたが、3つ以上の補正階調曲
jBを用い、重みwi を適当に選択することにより、
様々な補正階調特性を有する補正階調曲線Cを得ること
ができる。なお、濃度調整キー20の数値jを上記範囲
に限ったのは単に操作表示板のカラーバランス調整部の
濃度調整キー20のプラス側の数に対応させたためであ
り、理論的には任意の整数であって良い。
[0013] When the correction gradation curve C is obtained by simply averaging the equation (1) w 1 = a w 2 c i = (1 b i + 2 b i) / 2; (i = 1, ..., 256 )… (1) ′. Figure 10 is corrected gradation curve 1 B correction gradation curve C,
It shows an example obtained by a simple average of 2 B gradation components 1 b i and 2 b i . In addition, E represents an identity transformation.
Density adjustment key 20 in the color balance adjustment section of the operation display board
Assuming that the numerical value and the correction gradation curve j B are associated as shown in FIG. 11, the correction gradation corresponding to the density key in the middle of the numerical values of the density key 20 on the color balance adjusting unit shown in FIG. The curve C is as shown in Table 12. When the numerical value of the color balance adjustment of density adjustment key 20 and j, gives the tone component j c i of the correction gradation curve j C corresponding to Numerical j density adjustment key 20 represented in Table Figure 11 Assuming that a general weighted average is taken as the arithmetic expression, j c i = [w 1 · [(4 + j) / 2] b i + w 2 · ([(4 + j) / 2] +1) b i ] / (w 1 + w 2 ); (j; odd number) j c i = [(4 + j) / 2] b i ; (j; even number) (3) ([x] is the maximum that does not exceed x Integer (Gauss brackets), -4
≦ j ≦ 4) When the above-mentioned simple average is taken, w 1 = w 2 . As described above, in the present embodiment, all the density adjustment keys 20 including the numerical value (2m + 1) of the odd-numbered density adjustment keys 20 can be provided only by giving the correction gradation curve 2m B corresponding to the numerical value 2m of the even-numbered density adjustment keys 20. It is possible to obtain the corresponding gradation component j c i of the corrected gradation curve j C. Therefore, the storage capacity can be reduced to about half as compared with the case where the conversion data of the corrected gradation curve j B corresponding to all the density adjustment keys 20 is stored in the ROM 416. In the above example, two correction gradation curves 1 B and 2 B are used to calculate a new correction gradation curve C having an intermediate correction gradation characteristic, but three or more correction gradation curves are used. By using the curve j B and selecting the weight w i appropriately,
The corrected gradation curve C having various corrected gradation characteristics can be obtained. The reason that the numerical value j of the density adjustment key 20 is limited to the above range is simply to correspond to the number of the density adjustment keys 20 on the plus side of the color balance adjustment section of the operation display plate, and theoretically any integer. May be

【0014】次に、カラーバランス調整部の両端の最大
と最小の濃度調整キー20と無補正の濃度調整キー20
の補正階調曲線 2B, 0B, 1Bのみが与えられた時に
全ての濃度調整キー20に対応する補正階調曲線 jCを
比例平均法により得る方法を説明する。図13および図
14はそれぞれカラーバランス調整部の両端の最大、最
小と無補正の濃度調整キー20と補正階調曲線 0B〜 2
Bを対応付ける表図およびこれら以外の濃度調整キー2
0に対応する補正階調曲線 jCを与える演算式を示す表
図である。図14に示す補正階調曲線 jCの階調成分 j
i を与える演算式は、 ji =θ(-j)・〔−j・ 0i +(4+j)・ 1i 〕/4 +θ( j)・〔(4−j)・ 1i +j・ 2i 〕/4 … (4) (θ( x)=0 for x<0:θ( x)=1 for x≧
0、-4≦j≦4 )と表すことができる。なお、θ( x)
は単位ステップ関数と呼ばれる。図17は演算式(4) に
従って演算された階調成分 ji の補正階調曲線 jCを
16進法で示した入出力特性図である。さらに、カラー
バランス調整部の両端の最大と最小の濃度調整キー20
の補正階調曲線 0B, 1Bのみが与えられた時に全ての
濃度調整キー20に対応する補正階調曲線 jCを比例平
均法により得る方法を説明する。図15および図16は
それぞれカラーバランス調整部の両端の最大と最小の濃
度調整キー20の数値とそれらに対応する補正階調曲線
0B, 1Bおよびこれら以外の濃度調整キー20に対応
する補正階調曲線 jCを与える演算式を示す表図であ
る。一般に、最大と最小の濃度数値の間を(p0
1 )分割した濃度数値に対応する階調成分 ji を与
える演算式は、 ji =〔(p0 −j)・ 0i +(p1 +j)・ 1i 〕 /(p0 +p1 ) …(5) (p0 ,p1 は負でない整数、-4≦j≦4 )となるが、
本実施例では最大と最小の濃度数値の間を8分割してい
るので、p0=p1 =4である。図19は演算式(5) に
従って演算された階調成分 ji の補正階調曲線 jCを
16進法で示した入出力特性図である。なお、演算式
(5) において、最大と最小の濃度数値の間を(p0 +p
1 )分割した濃度数値に対応する階調成分 ji を求め
る時に濃度数値に対して重み係数w1 ,w2 を掛けて低
濃度側または高濃度側の階調成分 ji を相対的に強調
することができる。この場合の演算式は、 ji =〔w1 (p0 −j)・ 0i +w2 (p1 +j)・ 1i 〕 /〔w1 (p0 −j)+w2 (p1 +j)〕 …(5) ′ (w1 ,w2 は正の整数)となる。
Next, the maximum and minimum density adjustment keys 20 and the uncorrected density adjustment keys 20 at both ends of the color balance adjusting section.
A method for obtaining the corrected gradation curves j C corresponding to all the density adjustment keys 20 by the proportional average method when only the corrected gradation curves 2 B, 0 B and 1 B are given will be described. 13 and 14 a density adjustment key 20 of the largest at both ends of the color balance adjustment section respectively, the minimum and uncorrected corrected gradation curve 0 B to 2
A table diagram in which B is associated and density adjustment keys 2 other than these
6 is a table showing an arithmetic expression that gives a corrected gradation curve j C corresponding to 0. FIG. The gradation component j of the corrected gradation curve j C shown in FIG.
The arithmetic expression giving c i is j c i = θ (−j) · [−j · 0 b i + (4 + j) · 1 b i ] / 4 + θ (j) · [(4-j) · 1 b i + j · 2 b i] / 4 ... (4) (θ (x) = 0 for x <0: θ (x) = 1 for x ≧
0, -4 ≤ j ≤ 4). Note that θ (x)
Is called the unit step function. FIG. 17 is an input / output characteristic diagram showing the corrected gradation curve j C of the gradation component j c i calculated according to the calculation formula (4) in hexadecimal notation. Further, the maximum and minimum density adjustment keys 20 at both ends of the color balance adjustment unit
A method of obtaining the corrected gradation curves j C corresponding to all the density adjustment keys 20 by the proportional averaging method when only the corrected gradation curves 0 B and 1 B are given will be described. 15 and 16 respectively show numerical values of the maximum and minimum density adjustment keys 20 at both ends of the color balance adjusting section and the corresponding correction gradation curves.
9 is a table showing an arithmetic expression that gives a corrected gradation curve j C corresponding to 0 B, 1 B and density adjustment keys 20 other than these. In general, between the maximum and minimum density values (p 0 +
p 1 ) The arithmetic expression that gives the gradation component j c i corresponding to the divided density value is j c i = [(p 0 −j) · 0 b i + (p 1 + j) · 1 b i ] / ( p 0 + p 1 ) (5) (p 0 and p 1 are non-negative integers, -4 ≦ j ≦ 4)
In this embodiment, since the maximum and minimum density values are divided into eight, p 0 = p 1 = 4. FIG. 19 is an input / output characteristic diagram showing the corrected gradation curve j C of the gradation component j c i calculated according to the calculation formula (5) in hexadecimal notation. The calculation formula
In (5), the value between the maximum and minimum concentration values is (p 0 + p
1 ) When obtaining the gradation component j c i corresponding to the divided density value, the density value is multiplied by the weighting factors w 1 and w 2 to relatively determine the gradation component j c i on the low density side or the high density side. Can be emphasized. The equation at this case, j c i = [w 1 (p 0 -j) · 0 b i + w 2 (p 1 + j) · 1 b i ) / (w 1 (p 0 -j) + w 2 (p 1 + j)] (5) '(w 1 and w 2 are positive integers).

【0015】補正階調曲線 jCを用いて基準階調変換曲
線Aの階調変換特性を変えた階調変換曲線Dを得る階調
変換曲線補正処理を図18の流れ図を参照して説明す
る。本実施例では補正階調曲線 1Bは予めROM416
に記憶させずに、補正階調曲線0Bの恒等変換階調曲線
Eに対して対称な補正階調曲線として求める(S1
1)。離散的な階調成分 1i の間の階調成分を補うた
めに比例近似補間処理を行う(S12)。補正階調曲線
1Bを滑らかにするために、表図9に示す平滑化デジタ
ルフィルターを用いて平滑化処理を行う(S13)。そ
して、操作者によるカラーバランス調整部の濃度調整キ
ー20の選択操作を待って、その値を参照する(S1
4)。次に、選択された濃度調整キー20に対応する補
正階調曲線 jCの階調成分 ji を演算式(5) に従って
求める(S15)。こうして得られた補正階調曲線 j
を用いて基準階調変換曲線Aの階調変換特性を変えた階
調変換曲線Dを求める(S16)。図20は図19に示
す補正階調曲線 jCを用いて図21に示す基準階調変換
曲線Aの階調変換特性を変えた階調変換曲線D(階調成
ji )を示したものである。同図に示すように、こ
の例では、濃度調整キー20の数値jを変更しても高濃
度の領域hにおける濃淡比をさ程変化させずにほぼ一定
の割合で濃度を変化させることができる。
The gradation conversion curve correction processing for obtaining the gradation conversion curve D by changing the gradation conversion characteristic of the reference gradation conversion curve A using the corrected gradation curve j C will be described with reference to the flowchart of FIG. . Correction gradation curve 1 B in this embodiment is previously ROM416
Without stored, determined as symmetrical correction gradation curve with respect to the identity transformation gradation curve E of the correction gradation curve 0 B (S1
1). Performing proportional approximate interpolation processing to compensate for the tone component between discrete tone components 1 b i (S12). Corrected gradation curve
In order to smooth 1B, smoothing processing is performed using the smoothing digital filter shown in Table 9 (S13). Then, after waiting for the operator to select the density adjustment key 20 of the color balance adjustment unit, the value is referred to (S1).
4). Next, determine the tone component j c i of the correction gradation curve j C corresponding to the density adjustment key 20 selected according to the calculation equation (5) (S15). The corrected gradation curve j C thus obtained
Is used to obtain the gradation conversion curve D in which the gradation conversion characteristic of the reference gradation conversion curve A is changed (S16). FIG. 20 shows a gradation conversion curve D (gradation component jd i ) obtained by changing the gradation conversion characteristics of the reference gradation conversion curve A shown in FIG. 21 using the corrected gradation curve j C shown in FIG. It is a thing. As shown in the figure, in this example, even if the numerical value j of the density adjustment key 20 is changed, the density can be changed at a substantially constant ratio without changing the density ratio in the high density area h. .

【0016】ところで、基準階調変換曲線Aの階調変換
特性を変える補正階調曲線 jCを基準となる補正階調曲
0Bから恒等変換階調曲線Eに至る距離の比が常に一
定ななものとすることもできる。即ち、図24に示すよ
うに、恒等変換階調曲線E上の座標点PE (ei
i )に立てた垂線が補正階調曲線 0Bと交わる座標点
をP0 (i, 0i )、求める補正階調曲線 jCと交わ
る座標点をPC (ki , jki)とし、補正階調曲線 j
C上の座標点PC から座標点PE (ei ,ei )までの
距離と座標点P0 から座標点PE までの距離の比が常に
等しくなるような補正階調曲線 jCを求めるには、ei
−i=li とすると、ΔP0 E Rは直角二等辺三角形
であるから、 ei =( 0i +i)/2 li =( 0i −i)/2 ki =−m・j・li /4+ei となり、補正階調曲線 jCの階調成分 ji を求める演
算式は、 jki=m・j・li /4+ei ;(mは定数、-4≦j≦4 ) …(6) となる。上述のように、変数ki は離散的な値となるの
で、図18の流れ図に示す手順S12と同様に比例近似
補間処理を行うことにより、その間の必要な入出力デー
タを補う。図22および図23はそれぞれ演算式(6) に
従って演算された補正階調曲線 jCを16進法で示した
入出力特性図および図22に示す補正階調曲線 jCを用
いて図21に示す基準階調変換曲線Aの階調変換特性を
変えた階調変換曲線Dを示した入出力特性図である。図
23に示すように、この場合には濃度調整キー20の数
値jを増大させるに連れて、高濃度の領域h′における
低濃度側の濃淡比を徐々に増大させるような階調変換曲
線となる。上述の記述では濃度調整キー20の数値jに
対して線型に変化する補正階調曲線 jCを求める場合に
ついて説明したが、一般的にはαj をjの任意の関数と
して、補正階調曲線 jCの階調成分 ji を求める演算
式は、 ki =−αj ・li +ei jki= αj ・li +ei ;(αj はjの任意の関数) …(6) ′ となる。例えば、標準濃度を与えるj=0近傍の濃度変
化が小さくなるような関数αj として図25に示す変換
特性のものを用いれば、j=−4〜4に対応する補正階
調曲線 jCの特性曲線は図26のようになる。また、図
26に示す補正階調曲線 jCを用いて図21に示す基準
階調変換曲線Aの階調変換特性を変えた階調変換曲線 j
Dは図27のようになる。
By the way, the ratio of the distance from the corrected gradation curve 0 B, which is the reference to the corrected gradation curve j C for changing the gradation conversion characteristic of the reference gradation conversion curve A, to the identity conversion gradation curve E is always constant. It can also be anything. That is, as shown in FIG. 24, coordinate points P E (e i ,
e 0 ) is the coordinate point where the perpendicular line intersecting the corrected gradation curve 0 B intersects with P 0 (i, 0 b i ), and the coordinate point where the corrected gradation curve j C intersects with P C (ki, j c ki ). And the corrected gradation curve j
The correction gradation curve j C is such that the ratio of the distance from the coordinate point P C on C to the coordinate point P E (e i , e i ) and the distance from the coordinate point P 0 to the coordinate point P E is always equal. To find, e i
When -i = li, because the [Delta] P 0 P E R is an isosceles right triangle, e i = (0 b i + i) / 2 l i = (0 b i -i) / 2 ki = -m · j L i / 4 + e i , and the calculation formula for the gradation component j c i of the corrected gradation curve j C is j c ki = m · j · l i / 4 + e i ; (m is a constant, -4 ≦ j ≤ 4) It becomes (6). As described above, since the variable ki has a discrete value, the proportional approximate interpolation processing is performed as in step S12 shown in the flowchart of FIG. 18 to supplement the necessary input / output data during that period. 22 and 23 show the corrected gradation curve j C calculated according to the arithmetic expression (6) in hexadecimal notation, and FIG. 21 shows the corrected gradation curve j C shown in FIG. 9 is an input / output characteristic diagram showing a gradation conversion curve D in which the gradation conversion characteristics of the reference gradation conversion curve A shown in FIG. As shown in FIG. 23, in this case, as the numerical value j of the density adjustment key 20 is increased, a gradation conversion curve that gradually increases the density ratio on the low density side in the high density area h ′ is obtained. Become. In the above description, a case has been described in which the correction gradation curve j C that changes linearly with respect to the numerical value j of the density adjustment key 20 is obtained, but in general, α j is an arbitrary function of j and the correction gradation curve j C is set. The arithmetic expression for obtaining the gradation component j c i of j C is ki = −α j · l i + e i j c ki = α j · l i + e i ; (α j is an arbitrary function of j) (6 ) ′. For example, if a function α j having a conversion characteristic shown in FIG. 25 is used as the function α j that reduces the density change near j = 0, which gives the standard density, the corrected gradation curve j C corresponding to j = −4 to 4 is obtained. The characteristic curve is as shown in FIG. Further, a gradation conversion curve j obtained by changing the gradation conversion characteristics of the reference gradation conversion curve A shown in FIG. 21 by using the corrected gradation curve j C shown in FIG.
D becomes like FIG.

【0017】[0017]

【発明の効果】以上説明したように請求項1記載の発明
によれば、階調曲線記憶手段から読み出した複数の補正
階調曲線 jBの階調成分{ ji }に所定の重み付き平
均処理を施す補正演算をする補正階調曲線演算手段を有
したので、限られた容量の記憶手段を用いて、簡単な計
算によって画像形成装置の経時濃度特性変動や個々の装
置における特性バラつきを補正する階調変換曲線を得る
ことができると共に、所望の濃度領域の階調変換特性を
任意に修正することができる。請求項2記載の発明によ
れば、2つの補正階調曲線 jB,j'Bの階調成分{ j
i },{j'i }に単純平均処理を施す補正演算により
補正階調曲線 jCの階調成分{ ji }を得るようにし
たので、2つの補正階調曲線 jB,j'Bが表す階調特性
の中間または敷衍した階調特性を有する補正階調曲線 j
Cを容易に得ることができる。
As described above, according to the first aspect of the present invention, the gradation components { jb i } of the plurality of corrected gradation curves j B read from the gradation curve storage means are given a predetermined weight. Since the correction gradation curve calculation means for performing the correction calculation for performing the averaging process is included, the storage capacity of the limited capacity is used to perform the simple calculation to change the density characteristics of the image forming apparatus over time and the characteristic variations in individual apparatuses. It is possible to obtain a gradation conversion curve to be corrected, and it is possible to arbitrarily modify the gradation conversion characteristic of a desired density region. According to the second aspect of the invention, the gradation components { j b of the two corrected gradation curves j B, j'B
Since the gradation component { j c i } of the corrected gradation curve j C is obtained by the correction calculation for performing the simple averaging process on i }, { j ′ b i }, the two corrected gradation curves j B, j ' Corrected gradation curve j having a gradation characteristic intermediate or extended between the gradation characteristics represented by B
C can be easily obtained.

【0018】請求項3記載の発明によれば、2つの補正
階調曲線 jB,j'Bの中の1つは入力データに等しい出
力データを与える恒等変換を表す恒等変換曲線Eとした
ので、新たな階調変換曲線 jDの指数jの変化に連れて
出力階調データの濃淡比が徐々に変化する階調変換曲線
jDを得ることができる。請求項4記載の発明によれ
ば、恒等変換曲線E上の座標点と該座標点を通る垂線と
補正階調曲線 jCおよび補正階調曲線 jBとの交点をそ
れぞれ結ぶ線分の比が常に等しくなるように、少なくと
も1つの補正階調曲線 jBの階調成分{ ji }に基づ
いて補正階調曲線 jCの階調成分{ ji }を演算する
ようにしたので、補正階調曲線 jBと類似した階調特性
を有し、それぞれ補正の程度が異なる階調補正階調曲線
jCを容易に得ることができる。請求項5記載の発明に
よれば、補正演算により得られた2つの補正階調曲線 j
C, kCの階調成分{ ji },{ ki }に単純平均
処理を施す補正演算をするようにしたので、新たな階調
変換曲線 jDの指数jの変化に連れて出力階調データの
濃淡比が少なくとも或る階調領域で変化しない階調変換
曲線 jDを得ることができる。請求項6記載の発明によ
れば、補正演算によって得られた補正階調曲線の階調成
分に対してデジタルフィルターを用いた平滑化処理を施
すようにしたので、滑らかな補正階調曲線 jCを容易に
得ることができる。
According to the third aspect of the present invention, two correction gradation curve j B, one of j 'B is a identity transformation curve E representing the identity transformation that gives equal output data to the input data Therefore, the gradation conversion curve in which the gradation ratio of the output gradation data gradually changes as the index j of the new gradation conversion curve j D changes
j D can be obtained. According to the invention of claim 4, the ratio of the line segments connecting the coordinate points on the identity transformation curve E, the perpendiculars passing through the coordinate points, and the intersections of the corrected gradation curve j C and the corrected gradation curve j B, respectively. as but always equal. Thus computing the tone component of the correction gradation curve j C based on the grayscale component {j b i} of at least one correction gradation curve j B {j c i} , A gradation correction gradation curve having similar gradation characteristics to the correction gradation curve j B and different correction levels
j C can be easily obtained. According to the invention of claim 5, the two corrected gradation curves j obtained by the correction calculation
Since the correction calculation for performing the simple averaging process on the gradation components { j c i }, { k c i } of C and k C is performed, as the exponent j of the new gradation conversion curve j D changes. It is possible to obtain the gradation conversion curve j D in which the gradation ratio of the output gradation data does not change at least in a certain gradation area. According to the sixth aspect of the invention, since the gradation component of the corrected gradation curve obtained by the correction calculation is subjected to the smoothing process using the digital filter, the smoothed corrected gradation curve j C Can be easily obtained.

【図面の簡単な説明】[Brief description of drawings]

【図1】本発明の実施例に係るデジタル複写機の画像処
理装置のブロック図
FIG. 1 is a block diagram of an image processing apparatus of a digital copying machine according to an embodiment of the present invention.

【図2】実施例に係るデジタル複写機の機構の概略を示
す機構図
FIG. 2 is a mechanism diagram showing an outline of a mechanism of a digital copying machine according to an embodiment.

【図3】複写機の電装部の概略を示す模式図FIG. 3 is a schematic view showing an outline of an electric component section of a copying machine.

【図4】プリンターのレーザー変調回路のブロック図FIG. 4 is a block diagram of a laser modulation circuit of a printer.

【図5】PMから出力される隣接する2つのラインの記
録信号のタイミング図
FIG. 5 is a timing diagram of recording signals of two adjacent lines output from PM.

【図6】主走査方向の隣接する2つの画素の異なる光束
径のLDの記録信号の和と光電センサーの検知出力を示
す特性図
FIG. 6 is a characteristic diagram showing a sum of recording signals of LDs having different luminous flux diameters of two adjacent pixels in the main scanning direction and a detection output of a photoelectric sensor.

【図7】操作表示板のカラーバランス調整部に表示され
た調整画面を示す平面図
FIG. 7 is a plan view showing an adjustment screen displayed on a color balance adjustment section of the operation display plate.

【図8】カラーバランス調整を行った時の複写動作の流
れ図
FIG. 8 is a flow chart of a copying operation when color balance adjustment is performed.

【図9】1×5の大きさの平滑化デジタルフィルターの
フィルター係数を示す表図
FIG. 9 is a table showing filter coefficients of a 1 × 5 smoothing digital filter.

【図10】補正階調曲線 1B, 2Bの階調成分の単純平
均により補正階調曲線Cを求めた一例を示す入出力特性
[10] Correction gradation curve 1 B, 2 input-output characteristic diagram showing an example of obtaining the correction gradation curve C by a simple average of the gradation components of B

【図11】カラーバランス調整部の濃度調整キーの数値
と補正階調曲線 jBを対応付ける表図
FIG. 11 is a table diagram in which the numerical values of the density adjustment key of the color balance adjustment unit and the correction gradation curve j B are associated with each other.

【図12】カラーバランス調整部の濃度調整キーの目盛
の中間の数値の濃度キーに対応する補正階調曲線Cを与
える演算式を示す表図
FIG. 12 is a table showing an arithmetic expression that gives a correction gradation curve C corresponding to a density key having a numerical value in the middle of the scale of the density adjustment key of the color balance adjustment unit.

【図13】カラーバランス調整部の両端の最大、最小と
無補正の濃度調整キーと補正階調曲線 0B〜 2Bを対応
付ける表図
FIG. 13 is a table in which the maximum and minimum density adjustment keys at both ends of the color balance adjustment unit and the correction gradation curves 0 B to 2 B are associated with each other.

【図14】補正階調曲線 0B〜 2B以外の濃度調整キー
に対応する補正階調曲線 jCを与える演算式を示す表図
FIG. 14 is a table showing an arithmetic expression that gives a correction gradation curve j C corresponding to a density adjustment key other than the correction gradation curves 0 B to 2 B.

【図15】カラーバランス調整部の両端の最大と最小の
濃度調整キーの数値とそれらに対応する補正階調曲線 0
B, 1Bを示す表図
FIG. 15: Numerical values of the maximum and minimum density adjustment keys at both ends of the color balance adjustment unit and the corresponding correction gradation curve 0
Chart showing B, 1 B

【図16】補正階調曲線 0B, 1B以外の濃度調整キー
に対応する補正階調曲線 jCを与える演算式を示す表図
FIG. 16 is a table showing an arithmetic expression that gives a correction gradation curve j C corresponding to a density adjustment key other than the correction gradation curves 0 B and 1 B.

【図17】比例平均法により補正階調曲線 0B〜 2Bを
基に演算された補正階調曲線 jCを入出力特性図
FIG. 17 is an input / output characteristic diagram showing a corrected gradation curve j C calculated based on the corrected gradation curves 0 B to 2 B by the proportional averaging method.

【図18】階調変換曲線補正処理を示す流れ図FIG. 18 is a flowchart showing gradation conversion curve correction processing.

【図19】比例平均法により補正階調曲線 0B, 1Bを
基に演算された補正階調曲線 jCを示した入出力特性図
FIG. 19 is an input / output characteristic diagram showing a corrected gradation curve j C calculated based on the corrected gradation curves 0 B and 1 B by the proportional averaging method.

【図20】図19に示す補正階調曲線 jCを用いて補正
演算された階調変換曲線Dを示した入出力特性図
20 is an input / output characteristic diagram showing a gradation conversion curve D corrected and calculated using the corrected gradation curve j C shown in FIG.

【図21】基準階調変換曲線Aの階調変換特性を示す入
出力特性図
21 is an input / output characteristic diagram showing the gradation conversion characteristics of the reference gradation conversion curve A. FIG.

【図22】補正階調曲線 0Bを基に演算された恒等変換
階調曲線Eに対して対称な補正階調曲線 jCを示した入
出力特性図
FIG. 22 is an input / output characteristic diagram showing a corrected gradation curve j C symmetrical to the identity conversion gradation curve E calculated based on the corrected gradation curve 0 B.

【図23】図22に示す補正階調曲線 jCを用いて補正
演算された階調変換曲線Dを示した入出力特性図
23 is an input / output characteristic diagram showing a gradation conversion curve D corrected and calculated using the corrected gradation curve j C shown in FIG.

【図24】恒等変換階調曲線Eに対して対称な補正階調
曲線 jCを演算する演算方法を説明する説明図
24 is an explanatory diagram illustrating a calculation method for calculating a corrected gradation curve j C that is symmetrical with respect to the identity conversion gradation curve E. FIG.

【図25】濃度調整キーの数値jに対して非線型の補正
階調曲線 jCの階調成分 ji を与える関数αj の特性
曲線図
FIG. 25 is a characteristic curve diagram of a function α j that gives a gradation component j c i of a non-linear correction gradation curve j C to the numerical value j of the density adjustment key.

【図26】関数αj によって与えられる補正階調曲線 j
Cを示した入出力特性図
[Figure 26] is given by the function alpha j correction gradation curve j
Input / output characteristic diagram showing C

【図27】図26に示す補正階調曲線 jCを用いて補正
演算された階調変換曲線 jDを示した入出力特性図
27 is an input / output characteristic diagram showing a gradation conversion curve j D corrected and calculated using the corrected gradation curve j C shown in FIG.

【符号の説明】[Explanation of symbols]

20 濃度調整キー 101 複写機本体 102 感光体ドラム 104 レーザー光学系 106,107,108 Y,M,Cカラー現像装置 109 中間転写ベルト 118 コンタクトガラス 123 イメージセンサーアレイ 130 メイン制御部 131 ROM 134 レーザー光学系制御部 137 トナー濃度センサー 401 スキャナー 409 MTF補正回路 410 γ変換回路 412 プリンター 415 画像処理CPU 451 ルックアップテーブル(LUT) 452 パルス幅変調回路(PWM) 453 強度変調回路(PM) 454レーザーダイオード(LD) 20 Density Adjustment Key 101 Copier Main Body 102 Photosensitive Drum 104 Laser Optical System 106, 107, 108 Y, M, C Color Developing Device 109 Intermediate Transfer Belt 118 Contact Glass 123 Image Sensor Array 130 Main Control Unit 131 ROM 134 Laser Optical System Control unit 137 Toner density sensor 401 Scanner 409 MTF correction circuit 410 γ conversion circuit 412 Printer 415 Image processing CPU 451 Look-up table (LUT) 452 Pulse width modulation circuit (PWM) 453 Intensity modulation circuit (PM) 454 Laser diode (LD)

───────────────────────────────────────────────────── フロントページの続き (51)Int.Cl.6 識別記号 庁内整理番号 FI 技術表示箇所 H04N 1/52 H04N 1/40 B 1/46 B ─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. 6 Identification code Internal reference number FI Technical indication H04N 1/52 H04N 1/40 B 1/46 B

Claims (6)

【特許請求の範囲】[Claims] 【請求項1】 記録データに基づいて変調された照射光
により静電写真プロセスに従って形成された記録画像の
濃度階調と前記記録データとの対応を取るために、入力
データに対して所望の出力データを与える階調変換特性
に従って入出力データの変換を行うγ変換における基準
となる基準階調変換曲線Aと該基準階調変換曲線Aを補
正する際に用いられる複数の補正階調曲線 jB(j=1,
…,n)の階調成分{ai },{ ji }を入力階調iに
対応付けて記憶する階調曲線記憶手段と、該階調曲線記
憶手段から読み出した補正階調曲線 jBの階調成分{ j
i }に演算を施して補正階調曲線 jBと異なる階調変
換特性を有する補正階調曲線 jCを得る補正階調曲線演
算手段を具え、該補正階調曲線演算手段が演算した補正
階調曲線 jCに基づいて前記基準階調変換曲線Aを補正
して新たな階調変換曲線Dを生成するようにした階調変
換曲線生成装置において、前記補正階調曲線演算手段は
複数の補正階調曲線 jBの階調成分{ ji }に所定の
重み付き平均処理を施す補正演算をするものであること
を特徴とする階調変換曲線生成装置。
1. A desired output for input data in order to establish correspondence between density gradation of a recorded image formed by an electrophotographic process by irradiation light modulated based on the recorded data and the recorded data. A reference gradation conversion curve A that serves as a reference in γ conversion that converts input / output data according to a gradation conversion characteristic that gives data, and a plurality of corrected gradation curves j B used when correcting the reference gradation conversion curve A (J = 1,
, N) the gradation components {a i }, { j b i } are stored in association with the input gradation i, and the corrected gradation curve j read from the gradation curve storage means. B gradation component { j
b i }, and a correction gradation curve calculation means for obtaining a correction gradation curve j C having a gradation conversion characteristic different from that of the correction gradation curve j B, and the correction calculated by the correction gradation curve calculation means. In the gradation conversion curve generating device that corrects the reference gradation conversion curve A based on the gradation curve j C to generate a new gradation conversion curve D, the corrected gradation curve calculation means is a plurality of A gradation conversion curve generation device, which performs a correction calculation for performing a predetermined weighted averaging process on the gradation component { j b i } of the corrected gradation curve j B.
【請求項2】 補正階調曲線演算手段は2つの補正階調
曲線 jB,j'Bの階調成分{ ji },{j'i }に単
純平均処理を施す補正演算をするものであることを特徴
とする請求項1記載の階調変換曲線生成装置。
2. The correction gradation curve calculation means performs a correction calculation for performing a simple averaging process on the gradation components { jb i }, { j ′ b i } of the two correction gradation curves j B, j ′ B. The gradation conversion curve generation device according to claim 1, wherein
【請求項3】 2つの補正階調曲線 jB,j'Bの中の1
つは入力データに等しい出力データを与える恒等変換を
表す恒等変換曲線Eであることを特徴とする請求項2記
載の階調変換曲線生成装置。
3. One of the two corrected gradation curves j B, j'B
3. The gradation conversion curve generating device according to claim 2, wherein one is an identity conversion curve E representing an identity conversion that gives output data equal to input data.
【請求項4】 記録データに基づいて変調された照射光
により静電写真プロセスに従って形成された記録画像の
濃度階調と前記記録データとの対応を取るために、入力
データに対して所望の出力データを与える階調変換特性
に従って入出力データの変換を行うγ変換における基準
となる基準階調変換曲線Aと該基準階調変換曲線Aを補
正する際に用いられる複数の補正階調曲線 jB(j=1,
…,n)の階調成分{ai },{ ji }を入力階調iに
対応付けて記憶する階調曲線記憶手段と、該階調曲線記
憶手段から読み出した補正階調曲線 jBの階調成分{ j
i }に演算を施して補正階調曲線 jBと異なる階調変
換特性を有する補正階調曲線 jCを得る補正階調曲線演
算手段を具え、該補正階調曲線演算手段が演算した補正
階調曲線 jCに基づいて前記基準階調変換曲線Aを補正
して新たな階調変換曲線Dを生成するようにした階調変
換曲線生成装置において、前記補正階調曲線演算手段は
入力データに等しい出力データを与える恒等変換を表す
恒等変換曲線E上の座標点と該座標点を通る垂線と補正
階調曲線 jCおよび補正階調曲線 jBとの交点をそれぞ
れ結ぶ線分の比が常に等しくなるように、少なくとも1
つの補正階調曲線 jBの階調成分{ ji }に基づいて
補正階調曲線 jCの階調成分{ ji }を演算するもの
であることを特徴とする階調変換曲線生成装置。
4. A desired output for input data in order to make correspondence between the density gradation of a recorded image formed according to an electrostatographic process by irradiation light modulated based on the recorded data and the recorded data. A reference gradation conversion curve A that serves as a reference in γ conversion that converts input / output data according to a gradation conversion characteristic that gives data, and a plurality of corrected gradation curves j B used when correcting the reference gradation conversion curve A (J = 1,
, N) the gradation components {a i }, { j b i } are stored in association with the input gradation i, and the corrected gradation curve j read from the gradation curve storage means. B gradation component { j
b i }, and a correction gradation curve calculation means for obtaining a correction gradation curve j C having a gradation conversion characteristic different from that of the correction gradation curve j B, and the correction calculated by the correction gradation curve calculation means. In the gradation conversion curve generating device in which the reference gradation conversion curve A is corrected based on the gradation curve j C to generate a new gradation conversion curve D, the corrected gradation curve calculation means has Line segments connecting the coordinate points on the identity transformation curve E representing the identity transformation giving the output data equal to, the perpendicular line passing through the coordinate points, and the intersections of the corrected gradation curve j C and the corrected gradation curve j B, respectively. At least 1 so that the ratios are always equal
Gradation conversion curve generation, characterized in that the gradation component { j c i } of the corrected gradation curve j C is calculated based on the gradation component { j b i } of one corrected gradation curve j B apparatus.
【請求項5】 補正階調曲線演算手段は補正演算により
得られた2つの補正階調曲線 jC, kCの階調成分{ j
i },{ ki }に単純平均処理を施す補正演算をす
るものであることを特徴とする請求項4記載の階調変換
曲線生成装置。
5. The correction gradation curve calculation means is a gradation component { j of the two correction gradation curves j C, k C obtained by the correction calculation.
5. The gradation conversion curve generation device according to claim 4, wherein a correction calculation for performing a simple averaging process on c i }, { k c i } is performed.
【請求項6】 補正階調曲線演算手段は補正演算によっ
て得られた補正階調曲線の階調成分に対してデジタルフ
ィルターを用いた平滑化処理を施すものであることを特
徴とする請求項1ないし請求項5記載の階調変換曲線生
成装置。
6. The correction gradation curve calculation means performs smoothing processing using a digital filter on the gradation component of the correction gradation curve obtained by the correction calculation. The gradation conversion curve generation device according to claim 5.
JP32058594A 1994-12-22 1994-12-22 Tone conversion curve generator Expired - Fee Related JP3518913B2 (en)

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Application Number Priority Date Filing Date Title
JP32058594A JP3518913B2 (en) 1994-12-22 1994-12-22 Tone conversion curve generator

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Application Number Priority Date Filing Date Title
JP32058594A JP3518913B2 (en) 1994-12-22 1994-12-22 Tone conversion curve generator

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Publication Number Publication Date
JPH08181863A true JPH08181863A (en) 1996-07-12
JP3518913B2 JP3518913B2 (en) 2004-04-12

Family

ID=18123067

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6400469B1 (en) 1998-01-09 2002-06-04 Nec Corporation Printing apparatus for color electronic photograph
JP2004205554A (en) * 2002-12-20 2004-07-22 Konica Minolta Holdings Inc Image processing device, image processing method and program
JP2008228140A (en) * 2007-03-15 2008-09-25 Noritsu Koki Co Ltd Image processor and image processing method
US7480075B2 (en) 2003-07-15 2009-01-20 Konica Minolta Business Technologies, Inc. Image processing apparatus, image processing method, and image processing program
US7783126B2 (en) 2003-09-11 2010-08-24 Panasonic Corporation Visual processing device, visual processing method, visual processing program, and semiconductor device
US7860339B2 (en) 2003-09-11 2010-12-28 Panasonic Corporation Visual processing device, visual processing method, visual processing program, intergrated circuit, display device, image-capturing device, and portable information terminal

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JPH03139976A (en) * 1989-10-25 1991-06-14 Dainippon Screen Mfg Co Ltd Method for setting up tone curve
JPH0614193A (en) * 1991-11-25 1994-01-21 Eastman Kodak Co Automatic gradation-scale forming method in digital radiation image
JPH0662252A (en) * 1992-05-19 1994-03-04 Minolta Camera Co Ltd Digital image generating device

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH03139976A (en) * 1989-10-25 1991-06-14 Dainippon Screen Mfg Co Ltd Method for setting up tone curve
JPH0614193A (en) * 1991-11-25 1994-01-21 Eastman Kodak Co Automatic gradation-scale forming method in digital radiation image
JPH0662252A (en) * 1992-05-19 1994-03-04 Minolta Camera Co Ltd Digital image generating device

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6400469B1 (en) 1998-01-09 2002-06-04 Nec Corporation Printing apparatus for color electronic photograph
JP2004205554A (en) * 2002-12-20 2004-07-22 Konica Minolta Holdings Inc Image processing device, image processing method and program
US7480075B2 (en) 2003-07-15 2009-01-20 Konica Minolta Business Technologies, Inc. Image processing apparatus, image processing method, and image processing program
US7783126B2 (en) 2003-09-11 2010-08-24 Panasonic Corporation Visual processing device, visual processing method, visual processing program, and semiconductor device
US7860339B2 (en) 2003-09-11 2010-12-28 Panasonic Corporation Visual processing device, visual processing method, visual processing program, intergrated circuit, display device, image-capturing device, and portable information terminal
US7945115B2 (en) 2003-09-11 2011-05-17 Panasonic Corporation Visual processing device, visual processing method, visual processing program, and semiconductor device
US8165417B2 (en) 2003-09-11 2012-04-24 Panasonic Corporation Visual processing device, visual processing method, visual processing program, integrated circuit, display device, image-capturing device, and portable information terminal
JP2008228140A (en) * 2007-03-15 2008-09-25 Noritsu Koki Co Ltd Image processor and image processing method

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